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|
{-
(c) The GRASP/AQUA Project, Glasgow University, 1992-1998
\section[RnNames]{Extracting imported and top-level names in scope}
-}
{-# LANGUAGE CPP, NondecreasingIndentation #-}
module RnNames (
rnImports, getLocalNonValBinders, newRecordSelector,
rnExports, extendGlobalRdrEnvRn,
gresFromAvails,
calculateAvails,
reportUnusedNames,
checkConName
) where
#include "HsVersions.h"
import DynFlags
import HsSyn
import TcEnv
import RnEnv
import RnHsDoc ( rnHsDoc )
import LoadIface ( loadSrcInterface )
import TcRnMonad
import PrelNames
import Module
import Name
import NameEnv
import NameSet
import Avail
import FieldLabel
import HscTypes
import RdrName
import RdrHsSyn ( setRdrNameSpace )
import Outputable
import Maybes
import SrcLoc
import BasicTypes ( TopLevelFlag(..), StringLiteral(..) )
import ErrUtils
import Util
import FastString
import FastStringEnv
import ListSetOps
import Control.Monad
import Data.Either ( partitionEithers, isRight, rights )
-- import qualified Data.Foldable as Foldable
import Data.Map ( Map )
import qualified Data.Map as Map
import Data.Ord ( comparing )
import Data.List ( partition, (\\), find, sortBy )
-- import qualified Data.Set as Set
import System.FilePath ((</>))
import System.IO
{-
************************************************************************
* *
\subsection{rnImports}
* *
************************************************************************
Note [Tracking Trust Transitively]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
When we import a package as well as checking that the direct imports are safe
according to the rules outlined in the Note [HscMain . Safe Haskell Trust Check]
we must also check that these rules hold transitively for all dependent modules
and packages. Doing this without caching any trust information would be very
slow as we would need to touch all packages and interface files a module depends
on. To avoid this we make use of the property that if a modules Safe Haskell
mode changes, this triggers a recompilation from that module in the dependcy
graph. So we can just worry mostly about direct imports.
There is one trust property that can change for a package though without
recompliation being triggered: package trust. So we must check that all
packages a module tranitively depends on to be trusted are still trusted when
we are compiling this module (as due to recompilation avoidance some modules
below may not be considered trusted any more without recompilation being
triggered).
We handle this by augmenting the existing transitive list of packages a module M
depends on with a bool for each package that says if it must be trusted when the
module M is being checked for trust. This list of trust required packages for a
single import is gathered in the rnImportDecl function and stored in an
ImportAvails data structure. The union of these trust required packages for all
imports is done by the rnImports function using the combine function which calls
the plusImportAvails function that is a union operation for the ImportAvails
type. This gives us in an ImportAvails structure all packages required to be
trusted for the module we are currently compiling. Checking that these packages
are still trusted (and that direct imports are trusted) is done in
HscMain.checkSafeImports.
See the note below, [Trust Own Package] for a corner case in this method and
how its handled.
Note [Trust Own Package]
~~~~~~~~~~~~~~~~~~~~~~~~
There is a corner case of package trust checking that the usual transitive check
doesn't cover. (For how the usual check operates see the Note [Tracking Trust
Transitively] below). The case is when you import a -XSafe module M and M
imports a -XTrustworthy module N. If N resides in a different package than M,
then the usual check works as M will record a package dependency on N's package
and mark it as required to be trusted. If N resides in the same package as M
though, then importing M should require its own package be trusted due to N
(since M is -XSafe so doesn't create this requirement by itself). The usual
check fails as a module doesn't record a package dependency of its own package.
So instead we now have a bool field in a modules interface file that simply
states if the module requires its own package to be trusted. This field avoids
us having to load all interface files that the module depends on to see if one
is trustworthy.
Note [Trust Transitive Property]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
So there is an interesting design question in regards to transitive trust
checking. Say I have a module B compiled with -XSafe. B is dependent on a bunch
of modules and packages, some packages it requires to be trusted as its using
-XTrustworthy modules from them. Now if I have a module A that doesn't use safe
haskell at all and simply imports B, should A inherit all the the trust
requirements from B? Should A now also require that a package p is trusted since
B required it?
We currently say no but saying yes also makes sense. The difference is, if a
module M that doesn't use Safe Haskell imports a module N that does, should all
the trusted package requirements be dropped since M didn't declare that it cares
about Safe Haskell (so -XSafe is more strongly associated with the module doing
the importing) or should it be done still since the author of the module N that
uses Safe Haskell said they cared (so -XSafe is more strongly associated with
the module that was compiled that used it).
Going with yes is a simpler semantics we think and harder for the user to stuff
up but it does mean that Safe Haskell will affect users who don't care about
Safe Haskell as they might grab a package from Cabal which uses safe haskell (say
network) and that packages imports -XTrustworthy modules from another package
(say bytestring), so requires that package is trusted. The user may now get
compilation errors in code that doesn't do anything with Safe Haskell simply
because they are using the network package. They will have to call 'ghc-pkg
trust network' to get everything working. Due to this invasive nature of going
with yes we have gone with no for now.
-}
-- | Process Import Decls. See 'rnImportDecl' for a description of what
-- the return types represent.
-- Note: Do the non SOURCE ones first, so that we get a helpful warning
-- for SOURCE ones that are unnecessary
rnImports :: [LImportDecl RdrName]
-> RnM ([LImportDecl Name], GlobalRdrEnv, ImportAvails, AnyHpcUsage)
rnImports imports = do
this_mod <- getModule
let (source, ordinary) = partition is_source_import imports
is_source_import d = ideclSource (unLoc d)
stuff1 <- mapAndReportM (rnImportDecl this_mod) ordinary
stuff2 <- mapAndReportM (rnImportDecl this_mod) source
-- Safe Haskell: See Note [Tracking Trust Transitively]
let (decls, rdr_env, imp_avails, hpc_usage) = combine (stuff1 ++ stuff2)
return (decls, rdr_env, imp_avails, hpc_usage)
where
combine :: [(LImportDecl Name, GlobalRdrEnv, ImportAvails, AnyHpcUsage)]
-> ([LImportDecl Name], GlobalRdrEnv, ImportAvails, AnyHpcUsage)
combine = foldr plus ([], emptyGlobalRdrEnv, emptyImportAvails, False)
plus (decl, gbl_env1, imp_avails1,hpc_usage1)
(decls, gbl_env2, imp_avails2,hpc_usage2)
= ( decl:decls,
gbl_env1 `plusGlobalRdrEnv` gbl_env2,
imp_avails1 `plusImportAvails` imp_avails2,
hpc_usage1 || hpc_usage2 )
-- | Given a located import declaration @decl@ from @this_mod@,
-- calculate the following pieces of information:
--
-- 1. An updated 'LImportDecl', where all unresolved 'RdrName' in
-- the entity lists have been resolved into 'Name's,
--
-- 2. A 'GlobalRdrEnv' representing the new identifiers that were
-- brought into scope (taking into account module qualification
-- and hiding),
--
-- 3. 'ImportAvails' summarizing the identifiers that were imported
-- by this declaration, and
--
-- 4. A boolean 'AnyHpcUsage' which is true if the imported module
-- used HPC.
rnImportDecl :: Module -> LImportDecl RdrName
-> RnM (LImportDecl Name, GlobalRdrEnv, ImportAvails, AnyHpcUsage)
rnImportDecl this_mod
(L loc decl@(ImportDecl { ideclName = loc_imp_mod_name, ideclPkgQual = mb_pkg
, ideclSource = want_boot, ideclSafe = mod_safe
, ideclQualified = qual_only, ideclImplicit = implicit
, ideclAs = as_mod, ideclHiding = imp_details }))
= setSrcSpan loc $ do
when (isJust mb_pkg) $ do
pkg_imports <- xoptM Opt_PackageImports
when (not pkg_imports) $ addErr packageImportErr
-- If there's an error in loadInterface, (e.g. interface
-- file not found) we get lots of spurious errors from 'filterImports'
let imp_mod_name = unLoc loc_imp_mod_name
doc = ppr imp_mod_name <+> ptext (sLit "is directly imported")
-- Check for self-import, which confuses the typechecker (Trac #9032)
-- ghc --make rejects self-import cycles already, but batch-mode may not
-- at least not until TcIface.tcHiBootIface, which is too late to avoid
-- typechecker crashes. (Indirect self imports are not caught until
-- TcIface, see #10337 tracking how to make this error better.)
--
-- Originally, we also allowed 'import {-# SOURCE #-} M', but this
-- caused bug #10182: in one-shot mode, we should never load an hs-boot
-- file for the module we are compiling into the EPS. In principle,
-- it should be possible to support this mode of use, but we would have to
-- extend Provenance to support a local definition in a qualified location.
-- For now, we don't support it, but see #10336
when (imp_mod_name == moduleName this_mod &&
(case mb_pkg of -- If we have import "<pkg>" M, then we should
-- check that "<pkg>" is "this" (which is magic)
-- or the name of this_mod's package. Yurgh!
-- c.f. GHC.findModule, and Trac #9997
Nothing -> True
Just (StringLiteral _ pkg_fs) -> pkg_fs == fsLit "this" ||
fsToUnitId pkg_fs == moduleUnitId this_mod))
(addErr (ptext (sLit "A module cannot import itself:") <+> ppr imp_mod_name))
-- Check for a missing import list (Opt_WarnMissingImportList also
-- checks for T(..) items but that is done in checkDodgyImport below)
case imp_details of
Just (False, _) -> return () -- Explicit import list
_ | implicit -> return () -- Do not bleat for implicit imports
| qual_only -> return ()
| otherwise -> whenWOptM Opt_WarnMissingImportList $
addWarn (missingImportListWarn imp_mod_name)
iface <- loadSrcInterface doc imp_mod_name want_boot (fmap sl_fs mb_pkg)
-- Compiler sanity check: if the import didn't say
-- {-# SOURCE #-} we should not get a hi-boot file
WARN( not want_boot && mi_boot iface, ppr imp_mod_name ) do
-- Issue a user warning for a redundant {- SOURCE -} import
-- NB that we arrange to read all the ordinary imports before
-- any of the {- SOURCE -} imports.
--
-- in --make and GHCi, the compilation manager checks for this,
-- and indeed we shouldn't do it here because the existence of
-- the non-boot module depends on the compilation order, which
-- is not deterministic. The hs-boot test can show this up.
dflags <- getDynFlags
warnIf (want_boot && not (mi_boot iface) && isOneShot (ghcMode dflags))
(warnRedundantSourceImport imp_mod_name)
when (mod_safe && not (safeImportsOn dflags)) $
addErr (ptext (sLit "safe import can't be used as Safe Haskell isn't on!")
$+$ ptext (sLit $ "please enable Safe Haskell through either "
++ "Safe, Trustworthy or Unsafe"))
let
qual_mod_name = as_mod `orElse` imp_mod_name
imp_spec = ImpDeclSpec { is_mod = imp_mod_name, is_qual = qual_only,
is_dloc = loc, is_as = qual_mod_name }
-- filter the imports according to the import declaration
(new_imp_details, gres) <- filterImports iface imp_spec imp_details
let gbl_env = mkGlobalRdrEnv gres
-- True <=> import M ()
import_all = case imp_details of
Just (is_hiding, L _ ls) -> not is_hiding && null ls
_ -> False
-- should the import be safe?
mod_safe' = mod_safe
|| (not implicit && safeDirectImpsReq dflags)
|| (implicit && safeImplicitImpsReq dflags)
let imports
= (calculateAvails dflags iface mod_safe' want_boot) {
imp_mods = unitModuleEnv (mi_module iface)
[(qual_mod_name, import_all, loc, mod_safe')] }
-- Complain if we import a deprecated module
whenWOptM Opt_WarnWarningsDeprecations (
case (mi_warns iface) of
WarnAll txt -> addWarn $ moduleWarn imp_mod_name txt
_ -> return ()
)
let new_imp_decl = L loc (decl { ideclSafe = mod_safe'
, ideclHiding = new_imp_details })
return (new_imp_decl, gbl_env, imports, mi_hpc iface)
-- | Calculate the 'ImportAvails' induced by an import of a particular
-- interface, but without 'imp_mods'.
calculateAvails :: DynFlags
-> ModIface
-> IsSafeImport
-> IsBootInterface
-> ImportAvails
calculateAvails dflags iface mod_safe' want_boot =
let imp_mod = mi_module iface
orph_iface = mi_orphan iface
has_finsts = mi_finsts iface
deps = mi_deps iface
trust = getSafeMode $ mi_trust iface
trust_pkg = mi_trust_pkg iface
-- If the module exports anything defined in this module, just
-- ignore it. Reason: otherwise it looks as if there are two
-- local definition sites for the thing, and an error gets
-- reported. Easiest thing is just to filter them out up
-- front. This situation only arises if a module imports
-- itself, or another module that imported it. (Necessarily,
-- this invoves a loop.)
--
-- We do this *after* filterImports, so that if you say
-- module A where
-- import B( AType )
-- type AType = ...
--
-- module B( AType ) where
-- import {-# SOURCE #-} A( AType )
--
-- then you won't get a 'B does not export AType' message.
-- Compute new transitive dependencies
orphans | orph_iface = ASSERT( not (imp_mod `elem` dep_orphs deps) )
imp_mod : dep_orphs deps
| otherwise = dep_orphs deps
finsts | has_finsts = ASSERT( not (imp_mod `elem` dep_finsts deps) )
imp_mod : dep_finsts deps
| otherwise = dep_finsts deps
pkg = moduleUnitId (mi_module iface)
-- Does this import mean we now require our own pkg
-- to be trusted? See Note [Trust Own Package]
ptrust = trust == Sf_Trustworthy || trust_pkg
(dependent_mods, dependent_pkgs, pkg_trust_req)
| pkg == thisPackage dflags =
-- Imported module is from the home package
-- Take its dependent modules and add imp_mod itself
-- Take its dependent packages unchanged
--
-- NB: (dep_mods deps) might include a hi-boot file
-- for the module being compiled, CM. Do *not* filter
-- this out (as we used to), because when we've
-- finished dealing with the direct imports we want to
-- know if any of them depended on CM.hi-boot, in
-- which case we should do the hi-boot consistency
-- check. See LoadIface.loadHiBootInterface
((moduleName imp_mod,want_boot):dep_mods deps,dep_pkgs deps,ptrust)
| otherwise =
-- Imported module is from another package
-- Dump the dependent modules
-- Add the package imp_mod comes from to the dependent packages
ASSERT2( not (pkg `elem` (map fst $ dep_pkgs deps))
, ppr pkg <+> ppr (dep_pkgs deps) )
([], (pkg, False) : dep_pkgs deps, False)
in ImportAvails {
imp_mods = emptyModuleEnv, -- this gets filled in later
imp_orphs = orphans,
imp_finsts = finsts,
imp_dep_mods = mkModDeps dependent_mods,
imp_dep_pkgs = map fst $ dependent_pkgs,
-- Add in the imported modules trusted package
-- requirements. ONLY do this though if we import the
-- module as a safe import.
-- See Note [Tracking Trust Transitively]
-- and Note [Trust Transitive Property]
imp_trust_pkgs = if mod_safe'
then map fst $ filter snd dependent_pkgs
else [],
-- Do we require our own pkg to be trusted?
-- See Note [Trust Own Package]
imp_trust_own_pkg = pkg_trust_req
}
warnRedundantSourceImport :: ModuleName -> SDoc
warnRedundantSourceImport mod_name
= ptext (sLit "Unnecessary {-# SOURCE #-} in the import of module")
<+> quotes (ppr mod_name)
{-
************************************************************************
* *
\subsection{importsFromLocalDecls}
* *
************************************************************************
From the top-level declarations of this module produce
* the lexical environment
* the ImportAvails
created by its bindings.
Note [Top-level Names in Template Haskell decl quotes]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
See also: Note [Interactively-bound Ids in GHCi] in HscTypes
Note [Looking up Exact RdrNames] in RnEnv
Consider a Template Haskell declaration quotation like this:
module M where
f x = h [d| f = 3 |]
When renaming the declarations inside [d| ...|], we treat the
top level binders specially in two ways
1. We give them an Internal Name, not (as usual) an External one.
This is done by RnEnv.newTopSrcBinder.
2. We make them *shadow* the outer bindings.
See Note [GlobalRdrEnv shadowing]
3. We find out whether we are inside a [d| ... |] by testing the TH
stage. This is a slight hack, because the stage field was really
meant for the type checker, and here we are not interested in the
fields of Brack, hence the error thunks in thRnBrack.
-}
extendGlobalRdrEnvRn :: [AvailInfo]
-> MiniFixityEnv
-> RnM (TcGblEnv, TcLclEnv)
-- Updates both the GlobalRdrEnv and the FixityEnv
-- We return a new TcLclEnv only because we might have to
-- delete some bindings from it;
-- see Note [Top-level Names in Template Haskell decl quotes]
extendGlobalRdrEnvRn avails new_fixities
= do { (gbl_env, lcl_env) <- getEnvs
; stage <- getStage
; isGHCi <- getIsGHCi
; let rdr_env = tcg_rdr_env gbl_env
fix_env = tcg_fix_env gbl_env
th_bndrs = tcl_th_bndrs lcl_env
th_lvl = thLevel stage
-- Delete new_occs from global and local envs
-- If we are in a TemplateHaskell decl bracket,
-- we are going to shadow them
-- See Note [GlobalRdrEnv shadowing]
inBracket = isBrackStage stage
lcl_env_TH = lcl_env { tcl_rdr = delLocalRdrEnvList (tcl_rdr lcl_env) new_occs }
-- See Note [GlobalRdrEnv shadowing]
lcl_env2 | inBracket = lcl_env_TH
| otherwise = lcl_env
-- Deal with shadowing: see Note [GlobalRdrEnv shadowing]
want_shadowing = isGHCi || inBracket
rdr_env1 | want_shadowing = shadowNames rdr_env new_names
| otherwise = rdr_env
lcl_env3 = lcl_env2 { tcl_th_bndrs = extendNameEnvList th_bndrs
[ (n, (TopLevel, th_lvl))
| n <- new_names ] }
; rdr_env2 <- foldlM add_gre rdr_env1 new_gres
; let fix_env' = foldl extend_fix_env fix_env new_names
gbl_env' = gbl_env { tcg_rdr_env = rdr_env2, tcg_fix_env = fix_env' }
; traceRn (text "extendGlobalRdrEnvRn 2" <+> (pprGlobalRdrEnv True rdr_env2))
; return (gbl_env', lcl_env3) }
where
new_names = concatMap availNames avails
new_occs = map nameOccName new_names
-- If there is a fixity decl for the gre, add it to the fixity env
extend_fix_env fix_env name
| Just (L _ fi) <- lookupFsEnv new_fixities (occNameFS occ)
= extendNameEnv fix_env name (FixItem occ fi)
| otherwise
= fix_env
where
occ = nameOccName name
new_gres :: [GlobalRdrElt] -- New LocalDef GREs, derived from avails
new_gres = concatMap localGREsFromAvail avails
add_gre :: GlobalRdrEnv -> GlobalRdrElt -> RnM GlobalRdrEnv
-- Extend the GlobalRdrEnv with a LocalDef GRE
-- If there is already a LocalDef GRE with the same OccName,
-- report an error and discard the new GRE
-- This establishes INVARIANT 1 of GlobalRdrEnvs
add_gre env gre
| not (null dups) -- Same OccName defined twice
= do { addDupDeclErr (gre : dups); return env }
| otherwise
= return (extendGlobalRdrEnv env gre)
where
name = gre_name gre
occ = nameOccName name
dups = filter isLocalGRE (lookupGlobalRdrEnv env occ)
{- *********************************************************************
* *
getLocalDeclBindersd@ returns the names for an HsDecl
It's used for source code.
*** See "THE NAMING STORY" in HsDecls ****
* *
********************************************************************* -}
getLocalNonValBinders :: MiniFixityEnv -> HsGroup RdrName
-> RnM ((TcGblEnv, TcLclEnv), NameSet)
-- Get all the top-level binders bound the group *except*
-- for value bindings, which are treated separately
-- Specifically we return AvailInfo for
-- * type decls (incl constructors and record selectors)
-- * class decls (including class ops)
-- * associated types
-- * foreign imports
-- * value signatures (in hs-boot files only)
getLocalNonValBinders fixity_env
(HsGroup { hs_valds = binds,
hs_tyclds = tycl_decls,
hs_instds = inst_decls,
hs_fords = foreign_decls })
= do { -- Process all type/class decls *except* family instances
; overload_ok <- xoptM Opt_DuplicateRecordFields
; (tc_avails, tc_fldss) <- fmap unzip $ mapM (new_tc overload_ok)
(tyClGroupConcat tycl_decls)
; traceRn (text "getLocalNonValBinders 1" <+> ppr tc_avails)
; envs <- extendGlobalRdrEnvRn tc_avails fixity_env
; setEnvs envs $ do {
-- Bring these things into scope first
-- See Note [Looking up family names in family instances]
-- Process all family instances
-- to bring new data constructors into scope
; (nti_availss, nti_fldss) <- mapAndUnzipM (new_assoc overload_ok)
inst_decls
-- Finish off with value binders:
-- foreign decls and pattern synonyms for an ordinary module
-- type sigs in case of a hs-boot file only
; is_boot <- tcIsHsBootOrSig
; let val_bndrs | is_boot = hs_boot_sig_bndrs
| otherwise = for_hs_bndrs
; val_avails <- mapM new_simple val_bndrs
; let avails = concat nti_availss ++ val_avails
new_bndrs = availsToNameSet avails `unionNameSet`
availsToNameSet tc_avails
flds = concat nti_fldss ++ concat tc_fldss
; traceRn (text "getLocalNonValBinders 2" <+> ppr avails)
; (tcg_env, tcl_env) <- extendGlobalRdrEnvRn avails fixity_env
-- Extend tcg_field_env with new fields (this used to be the
-- work of extendRecordFieldEnv)
; let field_env = extendNameEnvList (tcg_field_env tcg_env) flds
envs = (tcg_env { tcg_field_env = field_env }, tcl_env)
; return (envs, new_bndrs) } }
where
ValBindsIn _val_binds val_sigs = binds
for_hs_bndrs :: [Located RdrName]
for_hs_bndrs = hsForeignDeclsBinders foreign_decls
-- In a hs-boot file, the value binders come from the
-- *signatures*, and there should be no foreign binders
hs_boot_sig_bndrs = [ L decl_loc (unLoc n)
| L decl_loc (TypeSig ns _ _) <- val_sigs, n <- ns]
-- the SrcSpan attached to the input should be the span of the
-- declaration, not just the name
new_simple :: Located RdrName -> RnM AvailInfo
new_simple rdr_name = do{ nm <- newTopSrcBinder rdr_name
; return (avail nm) }
new_tc :: Bool -> LTyClDecl RdrName
-> RnM (AvailInfo, [(Name, [FieldLabel])])
new_tc overload_ok tc_decl -- NOT for type/data instances
= do { let (bndrs, flds) = hsLTyClDeclBinders tc_decl
; names@(main_name : sub_names) <- mapM newTopSrcBinder bndrs
; flds' <- mapM (newRecordSelector overload_ok sub_names) flds
; let fld_env = case unLoc tc_decl of
DataDecl { tcdDataDefn = d } -> mk_fld_env d names flds'
_ -> []
; return (AvailTC main_name names flds', fld_env) }
-- Calculate the mapping from constructor names to fields, which
-- will go in tcg_field_env. It's convenient to do this here where
-- we are working with a single datatype definition.
mk_fld_env :: HsDataDefn RdrName -> [Name] -> [FieldLabel] -> [(Name, [FieldLabel])]
mk_fld_env d names flds = concatMap find_con_flds (dd_cons d)
where
find_con_flds (L _ (ConDecl { con_names = rdrs
, con_details = RecCon cdflds }))
= map (\ (L _ rdr) -> ( find_con_name rdr
, concatMap find_con_decl_flds (unLoc cdflds)))
rdrs
find_con_flds _ = []
find_con_name rdr
= expectJust "getLocalNonValBinders/find_con_name" $
find (\ n -> nameOccName n == rdrNameOcc rdr) names
find_con_decl_flds (L _ x)
= map find_con_decl_fld (cd_fld_names x)
find_con_decl_fld (L _ (FieldOcc rdr _))
= expectJust "getLocalNonValBinders/find_con_decl_fld" $
find (\ fl -> flLabel fl == lbl) flds
where lbl = occNameFS (rdrNameOcc rdr)
new_assoc :: Bool -> LInstDecl RdrName
-> RnM ([AvailInfo], [(Name, [FieldLabel])])
new_assoc _ (L _ (TyFamInstD {})) = return ([], [])
-- type instances don't bind new names
new_assoc overload_ok (L _ (DataFamInstD d))
= do { (avail, flds) <- new_di overload_ok Nothing d
; return ([avail], flds) }
new_assoc overload_ok (L _ (ClsInstD (ClsInstDecl { cid_poly_ty = inst_ty
, cid_datafam_insts = adts })))
| Just (_, _, L loc cls_rdr, _) <-
splitLHsInstDeclTy_maybe (flattenTopLevelLHsForAllTy inst_ty)
= do { cls_nm <- setSrcSpan loc $ lookupGlobalOccRn cls_rdr
; (avails, fldss)
<- mapAndUnzipM (new_loc_di overload_ok (Just cls_nm)) adts
; return (avails, concat fldss) }
| otherwise
= return ([], []) -- Do not crash on ill-formed instances
-- Eg instance !Show Int Trac #3811c
new_di :: Bool -> Maybe Name -> DataFamInstDecl RdrName
-> RnM (AvailInfo, [(Name, [FieldLabel])])
new_di overload_ok mb_cls ti_decl
= do { main_name <- lookupFamInstName mb_cls (dfid_tycon ti_decl)
; let (bndrs, flds) = hsDataFamInstBinders ti_decl
; sub_names <- mapM newTopSrcBinder bndrs
; flds' <- mapM (newRecordSelector overload_ok sub_names) flds
; let avail = AvailTC (unLoc main_name) sub_names flds'
-- main_name is not bound here!
fld_env = mk_fld_env (dfid_defn ti_decl) sub_names flds'
; return (avail, fld_env) }
new_loc_di :: Bool -> Maybe Name -> LDataFamInstDecl RdrName
-> RnM (AvailInfo, [(Name, [FieldLabel])])
new_loc_di overload_ok mb_cls (L _ d) = new_di overload_ok mb_cls d
newRecordSelector :: Bool -> [Name] -> LFieldOcc RdrName -> RnM FieldLabel
newRecordSelector _ [] _ = error "newRecordSelector: datatype has no constructors!"
newRecordSelector overload_ok (dc:_) (L loc (FieldOcc fld _)) =
do { sel_name <- newTopSrcBinder $ L loc $ mkRdrUnqual sel_occ
; return $ fl { flSelector = sel_name } }
where
lbl = occNameFS $ rdrNameOcc fld
fl = mkFieldLabelOccs lbl (nameOccName dc) overload_ok
sel_occ = flSelector fl
{-
Note [Looking up family names in family instances]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Consider
module M where
type family T a :: *
type instance M.T Int = Bool
We might think that we can simply use 'lookupOccRn' when processing the type
instance to look up 'M.T'. Alas, we can't! The type family declaration is in
the *same* HsGroup as the type instance declaration. Hence, as we are
currently collecting the binders declared in that HsGroup, these binders will
not have been added to the global environment yet.
Solution is simple: process the type family declarations first, extend
the environment, and then process the type instances.
************************************************************************
* *
\subsection{Filtering imports}
* *
************************************************************************
@filterImports@ takes the @ExportEnv@ telling what the imported module makes
available, and filters it through the import spec (if any).
Note [Dealing with imports]
~~~~~~~~~~~~~~~~~~~~~~~~~~~
For import M( ies ), we take the mi_exports of M, and make
imp_occ_env :: OccEnv (Name, AvailInfo, Maybe Name)
One entry for each Name that M exports; the AvailInfo describes just
that Name.
The situation is made more complicated by associated types. E.g.
module M where
class C a where { data T a }
instance C Int where { data T Int = T1 | T2 }
instance C Bool where { data T Int = T3 }
Then M's export_avails are (recall the AvailTC invariant from Avails.hs)
C(C,T), T(T,T1,T2,T3)
Notice that T appears *twice*, once as a child and once as a parent.
From this we construct the imp_occ_env
C -> (C, C(C,T), Nothing)
T -> (T, T(T,T1,T2,T3), Just C)
T1 -> (T1, T(T1,T2,T3), Nothing) -- similarly T2,T3
If we say
import M( T(T1,T2) )
then we get *two* Avails: C(T), T(T1,T2)
Note that the imp_occ_env will have entries for data constructors too,
although we never look up data constructors.
-}
filterImports
:: ModIface
-> ImpDeclSpec -- The span for the entire import decl
-> Maybe (Bool, Located [LIE RdrName]) -- Import spec; True => hiding
-> RnM (Maybe (Bool, Located [LIE Name]), -- Import spec w/ Names
[GlobalRdrElt]) -- Same again, but in GRE form
filterImports iface decl_spec Nothing
= return (Nothing, gresFromAvails (Just imp_spec) (mi_exports iface))
where
imp_spec = ImpSpec { is_decl = decl_spec, is_item = ImpAll }
filterImports iface decl_spec (Just (want_hiding, L l import_items))
= do -- check for errors, convert RdrNames to Names
items1 <- mapM lookup_lie import_items
let items2 :: [(LIE Name, AvailInfo)]
items2 = concat items1
-- NB the AvailInfo may have duplicates, and several items
-- for the same parent; e.g N(x) and N(y)
names = availsToNameSet (map snd items2)
keep n = not (n `elemNameSet` names)
pruned_avails = filterAvails keep all_avails
hiding_spec = ImpSpec { is_decl = decl_spec, is_item = ImpAll }
gres | want_hiding = gresFromAvails (Just hiding_spec) pruned_avails
| otherwise = concatMap (gresFromIE decl_spec) items2
return (Just (want_hiding, L l (map fst items2)), gres)
where
all_avails = mi_exports iface
-- See Note [Dealing with imports]
imp_occ_env :: OccEnv (Name, -- the name
AvailInfo, -- the export item providing the name
Maybe Name) -- the parent of associated types
imp_occ_env = mkOccEnv_C combine [ (nameOccName n, (n, a, Nothing))
| a <- all_avails, n <- availNames a]
where
-- See example in Note [Dealing with imports]
-- 'combine' is only called for associated types which appear twice
-- in the all_avails. In the example, we combine
-- T(T,T1,T2,T3) and C(C,T) to give (T, T(T,T1,T2,T3), Just C)
combine (name1, a1@(AvailTC p1 _ []), mp1)
(name2, a2@(AvailTC p2 _ []), mp2)
= ASSERT( name1 == name2 && isNothing mp1 && isNothing mp2 )
if p1 == name1 then (name1, a1, Just p2)
else (name1, a2, Just p1)
combine x y = pprPanic "filterImports/combine" (ppr x $$ ppr y)
lookup_name :: RdrName -> IELookupM (Name, AvailInfo, Maybe Name)
lookup_name rdr | isQual rdr = failLookupWith (QualImportError rdr)
| Just succ <- mb_success = return succ
| otherwise = failLookupWith BadImport
where
mb_success = lookupOccEnv imp_occ_env (rdrNameOcc rdr)
lookup_lie :: LIE RdrName -> TcRn [(LIE Name, AvailInfo)]
lookup_lie (L loc ieRdr)
= do (stuff, warns) <- setSrcSpan loc $
liftM (fromMaybe ([],[])) $
run_lookup (lookup_ie ieRdr)
mapM_ emit_warning warns
return [ (L loc ie, avail) | (ie,avail) <- stuff ]
where
-- Warn when importing T(..) if T was exported abstractly
emit_warning (DodgyImport n) = whenWOptM Opt_WarnDodgyImports $
addWarn (dodgyImportWarn n)
emit_warning MissingImportList = whenWOptM Opt_WarnMissingImportList $
addWarn (missingImportListItem ieRdr)
emit_warning BadImportW = whenWOptM Opt_WarnDodgyImports $
addWarn (lookup_err_msg BadImport)
run_lookup :: IELookupM a -> TcRn (Maybe a)
run_lookup m = case m of
Failed err -> addErr (lookup_err_msg err) >> return Nothing
Succeeded a -> return (Just a)
lookup_err_msg err = case err of
BadImport -> badImportItemErr iface decl_spec ieRdr all_avails
IllegalImport -> illegalImportItemErr
QualImportError rdr -> qualImportItemErr rdr
-- For each import item, we convert its RdrNames to Names,
-- and at the same time construct an AvailInfo corresponding
-- to what is actually imported by this item.
-- Returns Nothing on error.
-- We return a list here, because in the case of an import
-- item like C, if we are hiding, then C refers to *both* a
-- type/class and a data constructor. Moreover, when we import
-- data constructors of an associated family, we need separate
-- AvailInfos for the data constructors and the family (as they have
-- different parents). See Note [Dealing with imports]
lookup_ie :: IE RdrName -> IELookupM ([(IE Name, AvailInfo)], [IELookupWarning])
lookup_ie ie = handle_bad_import $ do
case ie of
IEVar (L l n) -> do
(name, avail, _) <- lookup_name n
return ([(IEVar (L l name), trimAvail avail name)], [])
IEThingAll (L l tc) -> do
(name, avail, mb_parent) <- lookup_name tc
let warns = case avail of
Avail {} -- e.g. f(..)
-> [DodgyImport tc]
AvailTC _ subs fs
| null (drop 1 subs) && null fs -- e.g. T(..) where T is a synonym
-> [DodgyImport tc]
| not (is_qual decl_spec) -- e.g. import M( T(..) )
-> [MissingImportList]
| otherwise
-> []
renamed_ie = IEThingAll (L l name)
sub_avails = case avail of
Avail {} -> []
AvailTC name2 subs fs -> [(renamed_ie, AvailTC name2 (subs \\ [name]) fs)]
case mb_parent of
Nothing -> return ([(renamed_ie, avail)], warns)
-- non-associated ty/cls
Just parent -> return ((renamed_ie, AvailTC parent [name] []) : sub_avails, warns)
-- associated type
IEThingAbs (L l tc)
| want_hiding -- hiding ( C )
-- Here the 'C' can be a data constructor
-- *or* a type/class, or even both
-> let tc_name = lookup_name tc
dc_name = lookup_name (setRdrNameSpace tc srcDataName)
in
case catIELookupM [ tc_name, dc_name ] of
[] -> failLookupWith BadImport
names -> return ([mkIEThingAbs l name | name <- names], [])
| otherwise
-> do nameAvail <- lookup_name tc
return ([mkIEThingAbs l nameAvail], [])
IEThingWith (L l rdr_tc) wc rdr_ns rdr_fs ->
ASSERT2(null rdr_fs, ppr rdr_fs) do
(name, AvailTC _ ns subflds, mb_parent) <- lookup_name rdr_tc
-- Look up the children in the sub-names of the parent
let subnames = case ns of -- The tc is first in ns,
[] -> [] -- if it is there at all
-- See the AvailTC Invariant in Avail.hs
(n1:ns1) | n1 == name -> ns1
| otherwise -> ns
case lookupChildren (map Left subnames ++ map Right subflds) rdr_ns of
Nothing -> failLookupWith BadImport
Just (childnames, childflds) ->
case mb_parent of
-- non-associated ty/cls
Nothing
-> return ([(IEThingWith (L l name) wc childnames childflds,
AvailTC name (name:map unLoc childnames) (map unLoc childflds))],
[])
-- associated ty
Just parent
-> return ([(IEThingWith (L l name) wc childnames childflds,
AvailTC name (map unLoc childnames) (map unLoc childflds)),
(IEThingWith (L l name) wc childnames childflds,
AvailTC parent [name] [])],
[])
_other -> failLookupWith IllegalImport
-- could be IEModuleContents, IEGroup, IEDoc, IEDocNamed
-- all errors.
where
mkIEThingAbs l (n, av, Nothing ) = (IEThingAbs (L l n),
trimAvail av n)
mkIEThingAbs l (n, _, Just parent) = (IEThingAbs (L l n),
AvailTC parent [n] [])
handle_bad_import m = catchIELookup m $ \err -> case err of
BadImport | want_hiding -> return ([], [BadImportW])
_ -> failLookupWith err
type IELookupM = MaybeErr IELookupError
data IELookupWarning
= BadImportW
| MissingImportList
| DodgyImport RdrName
-- NB. use the RdrName for reporting a "dodgy" import
data IELookupError
= QualImportError RdrName
| BadImport
| IllegalImport
failLookupWith :: IELookupError -> IELookupM a
failLookupWith err = Failed err
catchIELookup :: IELookupM a -> (IELookupError -> IELookupM a) -> IELookupM a
catchIELookup m h = case m of
Succeeded r -> return r
Failed err -> h err
catIELookupM :: [IELookupM a] -> [a]
catIELookupM ms = [ a | Succeeded a <- ms ]
{-
************************************************************************
* *
\subsection{Import/Export Utils}
* *
************************************************************************
-}
plusAvail :: AvailInfo -> AvailInfo -> AvailInfo
plusAvail a1 a2
| debugIsOn && availName a1 /= availName a2
= pprPanic "RnEnv.plusAvail names differ" (hsep [ppr a1,ppr a2])
plusAvail a1@(Avail {}) (Avail {}) = a1
plusAvail (AvailTC _ [] []) a2@(AvailTC {}) = a2
plusAvail a1@(AvailTC {}) (AvailTC _ [] []) = a1
plusAvail (AvailTC n1 (s1:ss1) fs1) (AvailTC n2 (s2:ss2) fs2)
= case (n1==s1, n2==s2) of -- Maintain invariant the parent is first
(True,True) -> AvailTC n1 (s1 : (ss1 `unionLists` ss2))
(fs1 `unionLists` fs2)
(True,False) -> AvailTC n1 (s1 : (ss1 `unionLists` (s2:ss2)))
(fs1 `unionLists` fs2)
(False,True) -> AvailTC n1 (s2 : ((s1:ss1) `unionLists` ss2))
(fs1 `unionLists` fs2)
(False,False) -> AvailTC n1 ((s1:ss1) `unionLists` (s2:ss2))
(fs1 `unionLists` fs2)
plusAvail (AvailTC n1 ss1 fs1) (AvailTC _ [] fs2)
= AvailTC n1 ss1 (fs1 `unionLists` fs2)
plusAvail (AvailTC n1 [] fs1) (AvailTC _ ss2 fs2)
= AvailTC n1 ss2 (fs1 `unionLists` fs2)
plusAvail a1 a2 = pprPanic "RnEnv.plusAvail" (hsep [ppr a1,ppr a2])
-- | trims an 'AvailInfo' to keep only a single name
trimAvail :: AvailInfo -> Name -> AvailInfo
trimAvail (Avail b n) _ = Avail b n
trimAvail (AvailTC n ns fs) m = case find ((== m) . flSelector) fs of
Just x -> AvailTC n [] [x]
Nothing -> ASSERT( m `elem` ns ) AvailTC n [m] []
-- | filters 'AvailInfo's by the given predicate
filterAvails :: (Name -> Bool) -> [AvailInfo] -> [AvailInfo]
filterAvails keep avails = foldr (filterAvail keep) [] avails
-- | filters an 'AvailInfo' by the given predicate
filterAvail :: (Name -> Bool) -> AvailInfo -> [AvailInfo] -> [AvailInfo]
filterAvail keep ie rest =
case ie of
Avail _ n | keep n -> ie : rest
| otherwise -> rest
AvailTC tc ns fs ->
let ns' = filter keep ns
fs' = filter (keep . flSelector) fs in
if null ns' && null fs' then rest else AvailTC tc ns' fs' : rest
-- | Given an import\/export spec, construct the appropriate 'GlobalRdrElt's.
gresFromIE :: ImpDeclSpec -> (LIE Name, AvailInfo) -> [GlobalRdrElt]
gresFromIE decl_spec (L loc ie, avail)
= gresFromAvail prov_fn avail
where
is_explicit = case ie of
IEThingAll (L _ name) -> \n -> n == name
_ -> \_ -> True
prov_fn name
= Just (ImpSpec { is_decl = decl_spec, is_item = item_spec })
where
item_spec = ImpSome { is_explicit = is_explicit name, is_iloc = loc }
{-
Note [Children for duplicate record fields]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Consider the module
{-# LANGUAGE DuplicateRecordFields #-}
module M (F(foo, MkFInt, MkFBool)) where
data family F a
data instance F Int = MkFInt { foo :: Int }
data instance F Bool = MkFBool { foo :: Bool }
The `foo` in the export list refers to *both* selectors! For this
reason, lookupChildren builds an environment that maps the FastString
to a list of items, rather than a single item.
-}
mkChildEnv :: [GlobalRdrElt] -> NameEnv [GlobalRdrElt]
mkChildEnv gres = foldr add emptyNameEnv gres
where
add gre env = case gre_par gre of
FldParent p _ -> extendNameEnv_Acc (:) singleton env p gre
ParentIs p -> extendNameEnv_Acc (:) singleton env p gre
NoParent -> env
PatternSynonym -> env
findPatSyns :: [GlobalRdrElt] -> [GlobalRdrElt]
findPatSyns gres = foldr add [] gres
where
add g@(GRE { gre_par = PatternSynonym }) ps =
g:ps
add _ ps = ps
findChildren :: NameEnv [a] -> Name -> [a]
findChildren env n = lookupNameEnv env n `orElse` []
lookupChildren :: [Either Name FieldLabel] -> [Located RdrName]
-> Maybe ([Located Name], [Located FieldLabel])
-- (lookupChildren all_kids rdr_items) maps each rdr_item to its
-- corresponding Name all_kids, if the former exists
-- The matching is done by FastString, not OccName, so that
-- Cls( meth, AssocTy )
-- will correctly find AssocTy among the all_kids of Cls, even though
-- the RdrName for AssocTy may have a (bogus) DataName namespace
-- (Really the rdr_items should be FastStrings in the first place.)
lookupChildren all_kids rdr_items
= do xs <- mapM doOne rdr_items
return (fmap concat (partitionEithers xs))
where
doOne (L l r) = case (lookupFsEnv kid_env . occNameFS . rdrNameOcc) r of
Just [Left n] -> Just (Left (L l n))
Just rs | all isRight rs -> Just (Right (map (L l) (rights rs)))
_ -> Nothing
-- See Note [Children for duplicate record fields]
kid_env = extendFsEnvList_C (++) emptyFsEnv
[(either (occNameFS . nameOccName) flLabel x, [x]) | x <- all_kids]
classifyGREs :: [GlobalRdrElt] -> ([Name], [FieldLabel])
classifyGREs = partitionEithers . map classifyGRE
classifyGRE :: GlobalRdrElt -> Either Name FieldLabel
classifyGRE gre = case gre_par gre of
FldParent _ Nothing -> Right (FieldLabel (occNameFS (nameOccName n)) False n)
FldParent _ (Just lbl) -> Right (FieldLabel lbl True n)
_ -> Left n
where
n = gre_name gre
-- | Combines 'AvailInfo's from the same family
-- 'avails' may have several items with the same availName
-- E.g import Ix( Ix(..), index )
-- will give Ix(Ix,index,range) and Ix(index)
-- We want to combine these; addAvail does that
nubAvails :: [AvailInfo] -> [AvailInfo]
nubAvails avails = nameEnvElts (foldl add emptyNameEnv avails)
where
add env avail = extendNameEnv_C plusAvail env (availName avail) avail
{-
************************************************************************
* *
\subsection{Export list processing}
* *
************************************************************************
Processing the export list.
You might think that we should record things that appear in the export
list as ``occurrences'' (using @addOccurrenceName@), but you'd be
wrong. We do check (here) that they are in scope, but there is no
need to slurp in their actual declaration (which is what
@addOccurrenceName@ forces).
Indeed, doing so would big trouble when compiling @PrelBase@, because
it re-exports @GHC@, which includes @takeMVar#@, whose type includes
@ConcBase.StateAndSynchVar#@, and so on...
Note [Exports of data families]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Suppose you see (Trac #5306)
module M where
import X( F )
data instance F Int = FInt
What does M export? AvailTC F [FInt]
or AvailTC F [F,FInt]?
The former is strictly right because F isn't defined in this module.
But then you can never do an explicit import of M, thus
import M( F( FInt ) )
because F isn't exported by M. Nor can you import FInt alone from here
import M( FInt )
because we don't have syntax to support that. (It looks like an import of
the type FInt.)
At one point I implemented a compromise:
* When constructing exports with no export list, or with module M(
module M ), we add the parent to the exports as well.
* But not when you see module M( f ), even if f is a
class method with a parent.
* Nor when you see module M( module N ), with N /= M.
But the compromise seemed too much of a hack, so we backed it out.
You just have to use an explicit export list:
module M( F(..) ) where ...
-}
type ExportAccum -- The type of the accumulating parameter of
-- the main worker function in rnExports
= ([LIE Name], -- Export items with Names
ExportOccMap, -- Tracks exported occurrence names
[AvailInfo]) -- The accumulated exported stuff
-- Not nub'd!
emptyExportAccum :: ExportAccum
emptyExportAccum = ([], emptyOccEnv, [])
type ExportOccMap = OccEnv (Name, IE RdrName)
-- Tracks what a particular exported OccName
-- in an export list refers to, and which item
-- it came from. It's illegal to export two distinct things
-- that have the same occurrence name
rnExports :: Bool -- False => no 'module M(..) where' header at all
-> Maybe (Located [LIE RdrName]) -- Nothing => no explicit export list
-> TcGblEnv
-> RnM (Maybe [LIE Name], TcGblEnv)
-- Complains if two distinct exports have same OccName
-- Warns about identical exports.
-- Complains about exports items not in scope
rnExports explicit_mod exports
tcg_env@(TcGblEnv { tcg_mod = this_mod,
tcg_rdr_env = rdr_env,
tcg_imports = imports })
= unsetWOptM Opt_WarnWarningsDeprecations $
-- Do not report deprecations arising from the export
-- list, to avoid bleating about re-exporting a deprecated
-- thing (especially via 'module Foo' export item)
do {
-- If the module header is omitted altogether, then behave
-- as if the user had written "module Main(main) where..."
-- EXCEPT in interactive mode, when we behave as if he had
-- written "module Main where ..."
-- Reason: don't want to complain about 'main' not in scope
-- in interactive mode
; dflags <- getDynFlags
; let real_exports
| explicit_mod = exports
| ghcLink dflags == LinkInMemory = Nothing
| otherwise
= Just (noLoc [noLoc (IEVar (noLoc main_RDR_Unqual))])
-- ToDo: the 'noLoc' here is unhelpful if 'main'
-- turns out to be out of scope
; (rn_exports, avails) <- exports_from_avail real_exports rdr_env imports this_mod
; traceRn (ppr avails)
; let final_avails = nubAvails avails -- Combine families
final_ns = availsToNameSetWithSelectors final_avails
; traceRn (text "rnExports: Exports:" <+> ppr final_avails)
; let new_tcg_env =
(tcg_env { tcg_exports = final_avails,
tcg_rn_exports = case tcg_rn_exports tcg_env of
Nothing -> Nothing
Just _ -> rn_exports,
tcg_dus = tcg_dus tcg_env `plusDU`
usesOnly final_ns })
; return (rn_exports, new_tcg_env) }
exports_from_avail :: Maybe (Located [LIE RdrName])
-- Nothing => no explicit export list
-> GlobalRdrEnv
-> ImportAvails
-> Module
-> RnM (Maybe [LIE Name], [AvailInfo])
exports_from_avail Nothing rdr_env _imports _this_mod
= -- The same as (module M) where M is the current module name,
-- so that's how we handle it.
let
avails = [ availFromGRE gre
| gre <- globalRdrEnvElts rdr_env
, isLocalGRE gre ]
in
return (Nothing, avails)
exports_from_avail (Just (L _ rdr_items)) rdr_env imports this_mod
= do (ie_names, _, exports) <- foldlM do_litem emptyExportAccum rdr_items
return (Just ie_names, exports)
where
do_litem :: ExportAccum -> LIE RdrName -> RnM ExportAccum
do_litem acc lie = setSrcSpan (getLoc lie) (exports_from_item acc lie)
-- Maps a parent to its in-scope children
kids_env :: NameEnv [GlobalRdrElt]
kids_env = mkChildEnv (globalRdrEnvElts rdr_env)
pat_syns :: [GlobalRdrElt]
pat_syns = findPatSyns (globalRdrEnvElts rdr_env)
imported_modules = [ qual_name
| xs <- moduleEnvElts $ imp_mods imports,
(qual_name, _, _, _) <- xs ]
exports_from_item :: ExportAccum -> LIE RdrName -> RnM ExportAccum
exports_from_item acc@(ie_names, occs, exports)
(L loc (IEModuleContents (L lm mod)))
| let earlier_mods = [ mod
| (L _ (IEModuleContents (L _ mod))) <- ie_names ]
, mod `elem` earlier_mods -- Duplicate export of M
= do { warn_dup_exports <- woptM Opt_WarnDuplicateExports ;
warnIf warn_dup_exports (dupModuleExport mod) ;
return acc }
| otherwise
= do { warnDodgyExports <- woptM Opt_WarnDodgyExports
; let { exportValid = (mod `elem` imported_modules)
|| (moduleName this_mod == mod)
; gre_prs = pickGREsModExp mod (globalRdrEnvElts rdr_env)
; new_exports = map (availFromGRE . fst) gre_prs
; names = map (gre_name . fst) gre_prs
; all_gres = foldr (\(gre1,gre2) gres -> gre1 : gre2 : gres) [] gre_prs
}
; checkErr exportValid (moduleNotImported mod)
; warnIf (warnDodgyExports && exportValid && null gre_prs)
(nullModuleExport mod)
; traceRn (text "efa" <+> (ppr mod $$ ppr all_gres))
; addUsedGREs all_gres
; occs' <- check_occs (IEModuleContents (noLoc mod)) occs names
-- This check_occs not only finds conflicts
-- between this item and others, but also
-- internally within this item. That is, if
-- 'M.x' is in scope in several ways, we'll have
-- several members of mod_avails with the same
-- OccName.
; traceRn (vcat [ text "export mod" <+> ppr mod
, ppr new_exports ])
; return (L loc (IEModuleContents (L lm mod)) : ie_names,
occs', new_exports ++ exports) }
exports_from_item acc@(lie_names, occs, exports) (L loc ie)
| isDoc ie
= do new_ie <- lookup_doc_ie ie
return (L loc new_ie : lie_names, occs, exports)
| otherwise
= do (new_ie, avail) <- lookup_ie ie
if isUnboundName (ieName new_ie)
then return acc -- Avoid error cascade
else do
occs' <- check_occs ie occs (availNames avail)
return (L loc new_ie : lie_names, occs', avail : exports)
-------------
lookup_ie :: IE RdrName -> RnM (IE Name, AvailInfo)
lookup_ie (IEVar (L l rdr))
= do (name, avail) <- lookupGreAvailRn rdr
return (IEVar (L l name), avail)
lookup_ie (IEThingAbs (L l rdr))
= do (name, avail) <- lookupGreAvailRn rdr
return (IEThingAbs (L l name), avail)
lookup_ie ie@(IEThingAll n)
= do
(n, avail, flds) <- lookup_ie_all ie n
let name = unLoc n
return (IEThingAll n, AvailTC name (name:avail) flds)
lookup_ie ie@(IEThingWith l wc sub_rdrs _)
= do
(lname, subs, avails, flds) <- lookup_ie_with ie l sub_rdrs
(_, all_avail, all_flds) <-
case wc of
NoIEWildcard -> return (lname, [], [])
IEWildcard _ -> lookup_ie_all ie l
let name = unLoc lname
return (IEThingWith lname wc subs [],
AvailTC name (name : avails ++ all_avail)
(flds ++ all_flds))
lookup_ie _ = panic "lookup_ie" -- Other cases covered earlier
lookup_ie_with :: IE RdrName -> Located RdrName -> [Located RdrName]
-> RnM (Located Name, [Located Name], [Name], [FieldLabel])
lookup_ie_with ie (L l rdr) sub_rdrs
= do name <- lookupGlobalOccRn rdr
let gres = findChildren kids_env name
mchildren =
lookupChildren (map classifyGRE (gres ++ pat_syns)) sub_rdrs
addUsedKids rdr gres
if isUnboundName name
then return (L l name, [], [name], [])
else
case mchildren of
Nothing -> do
addErr (exportItemErr ie)
return (L l name, [], [name], [])
Just (non_flds, flds) -> do
addUsedKids rdr gres
return (L l name, non_flds
, map unLoc non_flds
, map unLoc flds)
lookup_ie_all :: IE RdrName -> Located RdrName
-> RnM (Located Name, [Name], [FieldLabel])
lookup_ie_all ie (L l rdr) =
do name <- lookupGlobalOccRn rdr
let gres = findChildren kids_env name
(non_flds, flds) = classifyGREs gres
addUsedKids rdr gres
warnDodgyExports <- woptM Opt_WarnDodgyExports
when (null gres) $
if isTyConName name
then when warnDodgyExports $ addWarn (dodgyExportWarn name)
else -- This occurs when you export T(..), but
-- only import T abstractly, or T is a synonym.
addErr (exportItemErr ie)
return (L l name, non_flds, flds)
-------------
lookup_doc_ie :: IE RdrName -> RnM (IE Name)
lookup_doc_ie (IEGroup lev doc) = do rn_doc <- rnHsDoc doc
return (IEGroup lev rn_doc)
lookup_doc_ie (IEDoc doc) = do rn_doc <- rnHsDoc doc
return (IEDoc rn_doc)
lookup_doc_ie (IEDocNamed str) = return (IEDocNamed str)
lookup_doc_ie _ = panic "lookup_doc_ie" -- Other cases covered earlier
-- In an export item M.T(A,B,C), we want to treat the uses of
-- A,B,C as if they were M.A, M.B, M.C
-- Happily pickGREs does just the right thing
addUsedKids :: RdrName -> [GlobalRdrElt] -> RnM ()
addUsedKids parent_rdr kid_gres = addUsedGREs (pickGREs parent_rdr kid_gres)
isDoc :: IE RdrName -> Bool
isDoc (IEDoc _) = True
isDoc (IEDocNamed _) = True
isDoc (IEGroup _ _) = True
isDoc _ = False
-------------------------------
check_occs :: IE RdrName -> ExportOccMap -> [Name] -> RnM ExportOccMap
check_occs ie occs names -- 'names' are the entities specifed by 'ie'
= foldlM check occs names
where
check occs name
= case lookupOccEnv occs name_occ of
Nothing -> return (extendOccEnv occs name_occ (name, ie))
Just (name', ie')
| name == name' -- Duplicate export
-- But we don't want to warn if the same thing is exported
-- by two different module exports. See ticket #4478.
-> do unless (dupExport_ok name ie ie') $ do
warn_dup_exports <- woptM Opt_WarnDuplicateExports
warnIf warn_dup_exports (dupExportWarn name_occ ie ie')
return occs
| otherwise -- Same occ name but different names: an error
-> do { global_env <- getGlobalRdrEnv ;
addErr (exportClashErr global_env name' name ie' ie) ;
return occs }
where
name_occ = nameOccName name
dupExport_ok :: Name -> IE RdrName -> IE RdrName -> Bool
-- The Name is exported by both IEs. Is that ok?
-- "No" iff the name is mentioned explicitly in both IEs
-- or one of the IEs mentions the name *alone*
-- "Yes" otherwise
--
-- Examples of "no": module M( f, f )
-- module M( fmap, Functor(..) )
-- module M( module Data.List, head )
--
-- Example of "yes"
-- module M( module A, module B ) where
-- import A( f )
-- import B( f )
--
-- Example of "yes" (Trac #2436)
-- module M( C(..), T(..) ) where
-- class C a where { data T a }
-- instace C Int where { data T Int = TInt }
--
-- Example of "yes" (Trac #2436)
-- module Foo ( T ) where
-- data family T a
-- module Bar ( T(..), module Foo ) where
-- import Foo
-- data instance T Int = TInt
dupExport_ok n ie1 ie2
= not ( single ie1 || single ie2
|| (explicit_in ie1 && explicit_in ie2) )
where
explicit_in (IEModuleContents _) = False -- module M
explicit_in (IEThingAll r) = nameOccName n == rdrNameOcc (unLoc r) -- T(..)
explicit_in _ = True
single (IEVar {}) = True
single (IEThingAbs {}) = True
single _ = False
{-
*********************************************************
* *
\subsection{Unused names}
* *
*********************************************************
-}
reportUnusedNames :: Maybe (Located [LIE RdrName]) -- Export list
-> TcGblEnv -> RnM ()
reportUnusedNames _export_decls gbl_env
= do { traceRn ((text "RUN") <+> (ppr (tcg_dus gbl_env)))
; warnUnusedImportDecls gbl_env
; warnUnusedTopBinds unused_locals }
where
used_names :: NameSet
used_names = findUses (tcg_dus gbl_env) emptyNameSet
-- NB: currently, if f x = g, we only treat 'g' as used if 'f' is used
-- Hence findUses
-- Collect the defined names from the in-scope environment
defined_names :: [GlobalRdrElt]
defined_names = globalRdrEnvElts (tcg_rdr_env gbl_env)
-- Note that defined_and_used, defined_but_not_used
-- are both [GRE]; that's why we need defined_and_used
-- rather than just used_names
_defined_and_used, defined_but_not_used :: [GlobalRdrElt]
(_defined_and_used, defined_but_not_used)
= partition (gre_is_used used_names) defined_names
kids_env = mkChildEnv defined_names
-- This is done in mkExports too; duplicated work
gre_is_used :: NameSet -> GlobalRdrElt -> Bool
gre_is_used used_names (GRE {gre_name = name})
= name `elemNameSet` used_names
|| any (\ gre -> gre_name gre `elemNameSet` used_names) (findChildren kids_env name)
-- A use of C implies a use of T,
-- if C was brought into scope by T(..) or T(C)
-- Filter out the ones that are
-- (a) defined in this module, and
-- (b) not defined by a 'deriving' clause
-- The latter have an Internal Name, so we can filter them out easily
unused_locals :: [GlobalRdrElt]
unused_locals = filter is_unused_local defined_but_not_used
is_unused_local :: GlobalRdrElt -> Bool
is_unused_local gre = isLocalGRE gre && isExternalName (gre_name gre)
{-
*********************************************************
* *
\subsection{Unused imports}
* *
*********************************************************
This code finds which import declarations are unused. The
specification and implementation notes are here:
http://ghc.haskell.org/trac/ghc/wiki/Commentary/Compiler/UnusedImports
-}
type ImportDeclUsage
= ( LImportDecl Name -- The import declaration
, [AvailInfo] -- What *is* used (normalised)
, [Name] ) -- What is imported but *not* used
warnUnusedImportDecls :: TcGblEnv -> RnM ()
warnUnusedImportDecls gbl_env
= do { uses <- readMutVar (tcg_used_gres gbl_env)
; let user_imports = filterOut (ideclImplicit . unLoc) (tcg_rn_imports gbl_env)
-- This whole function deals only with *user* imports
-- both for warning about unnecessary ones, and for
-- deciding the minimal ones
rdr_env = tcg_rdr_env gbl_env
fld_env = mkFieldEnv rdr_env
; let usage :: [ImportDeclUsage]
usage = findImportUsage user_imports uses
; traceRn (vcat [ ptext (sLit "Uses:") <+> ppr uses
, ptext (sLit "Import usage") <+> ppr usage])
; whenWOptM Opt_WarnUnusedImports $
mapM_ (warnUnusedImport fld_env) usage
; whenGOptM Opt_D_dump_minimal_imports $
printMinimalImports usage }
{-
Note [The ImportMap]
~~~~~~~~~~~~~~~~~~~~
The ImportMap is a short-lived intermediate data struture records, for
each import declaration, what stuff brought into scope by that
declaration is actually used in the module.
The SrcLoc is the location of the END of a particular 'import'
declaration. Why *END*? Because we don't want to get confused
by the implicit Prelude import. Consider (Trac #7476) the module
import Foo( foo )
main = print foo
There is an implicit 'import Prelude(print)', and it gets a SrcSpan
of line 1:1 (just the point, not a span). If we use the *START* of
the SrcSpan to identify the import decl, we'll confuse the implicit
import Prelude with the explicit 'import Foo'. So we use the END.
It's just a cheap hack; we could equally well use the Span too.
The AvailInfos are the things imported from that decl (just a list,
not normalised).
-}
type ImportMap = Map SrcLoc [AvailInfo] -- See [The ImportMap]
findImportUsage :: [LImportDecl Name]
-> [GlobalRdrElt]
-> [ImportDeclUsage]
findImportUsage imports used_gres
= map unused_decl imports
where
import_usage :: ImportMap
import_usage
= foldr extendImportMap Map.empty used_gres
unused_decl decl@(L loc (ImportDecl { ideclHiding = imps }))
= (decl, nubAvails used_avails, nameSetElems unused_imps)
where
used_avails = Map.lookup (srcSpanEnd loc) import_usage `orElse` []
-- srcSpanEnd: see Note [The ImportMap]
used_names = availsToNameSetWithSelectors used_avails
used_parents = mkNameSet [n | AvailTC n _ _ <- used_avails]
unused_imps -- Not trivial; see eg Trac #7454
= case imps of
Just (False, L _ imp_ies) ->
foldr (add_unused . unLoc) emptyNameSet imp_ies
_other -> emptyNameSet -- No explicit import list => no unused-name list
add_unused :: IE Name -> NameSet -> NameSet
add_unused (IEVar (L _ n)) acc = add_unused_name n acc
add_unused (IEThingAbs (L _ n)) acc = add_unused_name n acc
add_unused (IEThingAll (L _ n)) acc = add_unused_all n acc
add_unused (IEThingWith (L _ p) wc ns fs) acc =
add_wc_all (add_unused_with p xs acc)
where xs = map unLoc ns ++ map (flSelector . unLoc) fs
add_wc_all = case wc of
NoIEWildcard -> id
IEWildcard _ -> add_unused_all p
add_unused _ acc = acc
add_unused_name n acc
| n `elemNameSet` used_names = acc
| otherwise = acc `extendNameSet` n
add_unused_all n acc
| n `elemNameSet` used_names = acc
| n `elemNameSet` used_parents = acc
| otherwise = acc `extendNameSet` n
add_unused_with p ns acc
| all (`elemNameSet` acc1) ns = add_unused_name p acc1
| otherwise = acc1
where
acc1 = foldr add_unused_name acc ns
-- If you use 'signum' from Num, then the user may well have
-- imported Num(signum). We don't want to complain that
-- Num is not itself mentioned. Hence the two cases in add_unused_with.
extendImportMap :: GlobalRdrElt -> ImportMap -> ImportMap
-- For each of a list of used GREs, find all the import decls that brought
-- it into scope; choose one of them (bestImport), and record
-- the RdrName in that import decl's entry in the ImportMap
extendImportMap gre imp_map
= add_imp gre (bestImport (gre_imp gre)) imp_map
where
add_imp :: GlobalRdrElt -> ImportSpec -> ImportMap -> ImportMap
add_imp gre (ImpSpec { is_decl = imp_decl_spec }) imp_map
= Map.insertWith add decl_loc [avail] imp_map
where
add _ avails = avail : avails -- add is really just a specialised (++)
decl_loc = srcSpanEnd (is_dloc imp_decl_spec)
-- For srcSpanEnd see Note [The ImportMap]
avail = availFromGRE gre
warnUnusedImport :: NameEnv (FieldLabelString, Name) -> ImportDeclUsage
-> RnM ()
warnUnusedImport fld_env (L loc decl, used, unused)
| Just (False,L _ []) <- ideclHiding decl
= return () -- Do not warn for 'import M()'
| Just (True, L _ hides) <- ideclHiding decl
, not (null hides)
, pRELUDE_NAME == unLoc (ideclName decl)
= return () -- Note [Do not warn about Prelude hiding]
| null used = addWarnAt loc msg1 -- Nothing used; drop entire decl
| null unused = return () -- Everything imported is used; nop
| otherwise = addWarnAt loc msg2 -- Some imports are unused
where
msg1 = vcat [pp_herald <+> quotes pp_mod <+> pp_not_used,
nest 2 (ptext (sLit "except perhaps to import instances from")
<+> quotes pp_mod),
ptext (sLit "To import instances alone, use:")
<+> ptext (sLit "import") <+> pp_mod <> parens Outputable.empty ]
msg2 = sep [pp_herald <+> quotes sort_unused,
text "from module" <+> quotes pp_mod <+> pp_not_used]
pp_herald = text "The" <+> pp_qual <+> text "import of"
pp_qual
| ideclQualified decl = text "qualified"
| otherwise = Outputable.empty
pp_mod = ppr (unLoc (ideclName decl))
pp_not_used = text "is redundant"
ppr_possible_field n = case lookupNameEnv fld_env n of
Just (fld, p) -> ppr p <> parens (ppr fld)
Nothing -> ppr n
-- Print unused names in a deterministic (lexicographic) order
sort_unused = pprWithCommas ppr_possible_field $
sortBy (comparing nameOccName) unused
{-
Note [Do not warn about Prelude hiding]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
We do not warn about
import Prelude hiding( x, y )
because even if nothing else from Prelude is used, it may be essential to hide
x,y to avoid name-shadowing warnings. Example (Trac #9061)
import Prelude hiding( log )
f x = log where log = ()
Note [Printing minimal imports]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
To print the minimal imports we walk over the user-supplied import
decls, and simply trim their import lists. NB that
* We do *not* change the 'qualified' or 'as' parts!
* We do not disard a decl altogether; we might need instances
from it. Instead we just trim to an empty import list
-}
printMinimalImports :: [ImportDeclUsage] -> RnM ()
-- See Note [Printing minimal imports]
printMinimalImports imports_w_usage
= do { imports' <- mapM mk_minimal imports_w_usage
; this_mod <- getModule
; dflags <- getDynFlags
; liftIO $
do { h <- openFile (mkFilename dflags this_mod) WriteMode
; printForUser dflags h neverQualify (vcat (map ppr imports')) }
-- The neverQualify is important. We are printing Names
-- but they are in the context of an 'import' decl, and
-- we never qualify things inside there
-- E.g. import Blag( f, b )
-- not import Blag( Blag.f, Blag.g )!
}
where
mkFilename dflags this_mod
| Just d <- dumpDir dflags = d </> basefn
| otherwise = basefn
where
basefn = moduleNameString (moduleName this_mod) ++ ".imports"
mk_minimal (L l decl, used, unused)
| null unused
, Just (False, _) <- ideclHiding decl
= return (L l decl)
| otherwise
= do { let ImportDecl { ideclName = L _ mod_name
, ideclSource = is_boot
, ideclPkgQual = mb_pkg } = decl
; iface <- loadSrcInterface doc mod_name is_boot (fmap sl_fs mb_pkg)
; let lies = map (L l) (concatMap (to_ie iface) used)
; return (L l (decl { ideclHiding = Just (False, L l lies) })) }
where
doc = text "Compute minimal imports for" <+> ppr decl
to_ie :: ModIface -> AvailInfo -> [IE Name]
-- The main trick here is that if we're importing all the constructors
-- we want to say "T(..)", but if we're importing only a subset we want
-- to say "T(A,B,C)". So we have to find out what the module exports.
to_ie _ (Avail _ n)
= [IEVar (noLoc n)]
to_ie _ (AvailTC n [m] [])
| n==m = [IEThingAbs (noLoc n)]
to_ie iface (AvailTC n ns fs)
= case [(xs,gs) | AvailTC x xs gs <- mi_exports iface
, x == n
, x `elem` xs -- Note [Partial export]
] of
[xs] | all_used xs -> [IEThingAll (noLoc n)]
| otherwise -> [IEThingWith (noLoc n) NoIEWildcard
(map noLoc (filter (/= n) ns))
(map noLoc fs)]
-- Note [Overloaded field import]
_other | all_non_overloaded fs
-> map (IEVar . noLoc) $ ns ++ map flSelector fs
| otherwise -> [IEThingWith (noLoc n) NoIEWildcard
(map noLoc (filter (/= n) ns)) (map noLoc fs)]
where
fld_lbls = map flLabel fs
all_used (avail_occs, avail_flds)
= all (`elem` ns) avail_occs
&& all (`elem` fld_lbls) (map flLabel avail_flds)
all_non_overloaded = all (not . flIsOverloaded)
{-
Note [Partial export]
~~~~~~~~~~~~~~~~~~~~~
Suppose we have
module A( op ) where
class C a where
op :: a -> a
module B where
import A
f = ..op...
Then the minimal import for module B is
import A( op )
not
import A( C( op ) )
which we would usually generate if C was exported from B. Hence
the (x `elem` xs) test when deciding what to generate.
Note [Overloaded field import]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
On the other hand, if we have
{-# LANGUAGE DuplicateRecordFields #-}
module A where
data T = MkT { foo :: Int }
module B where
import A
f = ...foo...
then the minimal import for module B must be
import A ( T(foo) )
because when DuplicateRecordFields is enabled, field selectors are
not in scope without their enclosing datatype.
************************************************************************
* *
\subsection{Errors}
* *
************************************************************************
-}
qualImportItemErr :: RdrName -> SDoc
qualImportItemErr rdr
= hang (ptext (sLit "Illegal qualified name in import item:"))
2 (ppr rdr)
badImportItemErrStd :: ModIface -> ImpDeclSpec -> IE RdrName -> SDoc
badImportItemErrStd iface decl_spec ie
= sep [ptext (sLit "Module"), quotes (ppr (is_mod decl_spec)), source_import,
ptext (sLit "does not export"), quotes (ppr ie)]
where
source_import | mi_boot iface = ptext (sLit "(hi-boot interface)")
| otherwise = Outputable.empty
badImportItemErrDataCon :: OccName -> ModIface -> ImpDeclSpec -> IE RdrName -> SDoc
badImportItemErrDataCon dataType_occ iface decl_spec ie
= vcat [ ptext (sLit "In module")
<+> quotes (ppr (is_mod decl_spec))
<+> source_import <> colon
, nest 2 $ quotes datacon
<+> ptext (sLit "is a data constructor of")
<+> quotes dataType
, ptext (sLit "To import it use")
, nest 2 $ quotes (ptext (sLit "import"))
<+> ppr (is_mod decl_spec)
<> parens_sp (dataType <> parens_sp datacon)
, ptext (sLit "or")
, nest 2 $ quotes (ptext (sLit "import"))
<+> ppr (is_mod decl_spec)
<> parens_sp (dataType <> ptext (sLit "(..)"))
]
where
datacon_occ = rdrNameOcc $ ieName ie
datacon = parenSymOcc datacon_occ (ppr datacon_occ)
dataType = parenSymOcc dataType_occ (ppr dataType_occ)
source_import | mi_boot iface = ptext (sLit "(hi-boot interface)")
| otherwise = Outputable.empty
parens_sp d = parens (space <> d <> space) -- T( f,g )
badImportItemErr :: ModIface -> ImpDeclSpec -> IE RdrName -> [AvailInfo] -> SDoc
badImportItemErr iface decl_spec ie avails
= case find checkIfDataCon avails of
Just con -> badImportItemErrDataCon (availOccName con) iface decl_spec ie
Nothing -> badImportItemErrStd iface decl_spec ie
where
checkIfDataCon (AvailTC _ ns _) =
case find (\n -> importedFS == nameOccNameFS n) ns of
Just n -> isDataConName n
Nothing -> False
checkIfDataCon _ = False
availOccName = nameOccName . availName
nameOccNameFS = occNameFS . nameOccName
importedFS = occNameFS . rdrNameOcc $ ieName ie
illegalImportItemErr :: SDoc
illegalImportItemErr = ptext (sLit "Illegal import item")
dodgyImportWarn :: RdrName -> SDoc
dodgyImportWarn item = dodgyMsg (ptext (sLit "import")) item
dodgyExportWarn :: Name -> SDoc
dodgyExportWarn item = dodgyMsg (ptext (sLit "export")) item
dodgyMsg :: (OutputableBndr n, HasOccName n) => SDoc -> n -> SDoc
dodgyMsg kind tc
= sep [ ptext (sLit "The") <+> kind <+> ptext (sLit "item")
<+> quotes (ppr (IEThingAll (noLoc tc)))
<+> ptext (sLit "suggests that"),
quotes (ppr tc) <+> ptext (sLit "has (in-scope) constructors or class methods,"),
ptext (sLit "but it has none") ]
exportItemErr :: IE RdrName -> SDoc
exportItemErr export_item
= sep [ ptext (sLit "The export item") <+> quotes (ppr export_item),
ptext (sLit "attempts to export constructors or class methods that are not visible here") ]
exportClashErr :: GlobalRdrEnv -> Name -> Name -> IE RdrName -> IE RdrName
-> MsgDoc
exportClashErr global_env name1 name2 ie1 ie2
= vcat [ ptext (sLit "Conflicting exports for") <+> quotes (ppr occ) <> colon
, ppr_export ie1' name1'
, ppr_export ie2' name2' ]
where
occ = nameOccName name1
ppr_export ie name = nest 3 (hang (quotes (ppr ie) <+> ptext (sLit "exports") <+>
quotes (ppr name))
2 (pprNameProvenance (get_gre name)))
-- get_gre finds a GRE for the Name, so that we can show its provenance
get_gre name
= case lookupGRE_Name global_env name of
(gre:_) -> gre
[] -> pprPanic "exportClashErr" (ppr name)
get_loc name = greSrcSpan (get_gre name)
(name1', ie1', name2', ie2') = if get_loc name1 < get_loc name2
then (name1, ie1, name2, ie2)
else (name2, ie2, name1, ie1)
addDupDeclErr :: [GlobalRdrElt] -> TcRn ()
addDupDeclErr [] = panic "addDupDeclErr: empty list"
addDupDeclErr gres@(gre : _)
= addErrAt (getSrcSpan (last sorted_names)) $
-- Report the error at the later location
vcat [ptext (sLit "Multiple declarations of") <+>
quotes (ppr (nameOccName name)),
-- NB. print the OccName, not the Name, because the
-- latter might not be in scope in the RdrEnv and so will
-- be printed qualified.
ptext (sLit "Declared at:") <+>
vcat (map (ppr . nameSrcLoc) sorted_names)]
where
name = gre_name gre
sorted_names = sortWith nameSrcLoc (map gre_name gres)
dupExportWarn :: OccName -> IE RdrName -> IE RdrName -> SDoc
dupExportWarn occ_name ie1 ie2
= hsep [quotes (ppr occ_name),
ptext (sLit "is exported by"), quotes (ppr ie1),
ptext (sLit "and"), quotes (ppr ie2)]
dupModuleExport :: ModuleName -> SDoc
dupModuleExport mod
= hsep [ptext (sLit "Duplicate"),
quotes (ptext (sLit "Module") <+> ppr mod),
ptext (sLit "in export list")]
moduleNotImported :: ModuleName -> SDoc
moduleNotImported mod
= ptext (sLit "The export item `module") <+> ppr mod <>
ptext (sLit "' is not imported")
nullModuleExport :: ModuleName -> SDoc
nullModuleExport mod
= ptext (sLit "The export item `module") <+> ppr mod <> ptext (sLit "' exports nothing")
missingImportListWarn :: ModuleName -> SDoc
missingImportListWarn mod
= ptext (sLit "The module") <+> quotes (ppr mod) <+> ptext (sLit "does not have an explicit import list")
missingImportListItem :: IE RdrName -> SDoc
missingImportListItem ie
= ptext (sLit "The import item") <+> quotes (ppr ie) <+> ptext (sLit "does not have an explicit import list")
moduleWarn :: ModuleName -> WarningTxt -> SDoc
moduleWarn mod (WarningTxt _ txt)
= sep [ ptext (sLit "Module") <+> quotes (ppr mod) <> ptext (sLit ":"),
nest 2 (vcat (map (ppr . sl_fs . unLoc) txt)) ]
moduleWarn mod (DeprecatedTxt _ txt)
= sep [ ptext (sLit "Module") <+> quotes (ppr mod)
<+> ptext (sLit "is deprecated:"),
nest 2 (vcat (map (ppr . sl_fs . unLoc) txt)) ]
packageImportErr :: SDoc
packageImportErr
= ptext (sLit "Package-qualified imports are not enabled; use PackageImports")
-- This data decl will parse OK
-- data T = a Int
-- treating "a" as the constructor.
-- It is really hard to make the parser spot this malformation.
-- So the renamer has to check that the constructor is legal
--
-- We can get an operator as the constructor, even in the prefix form:
-- data T = :% Int Int
-- from interface files, which always print in prefix form
checkConName :: RdrName -> TcRn ()
checkConName name = checkErr (isRdrDataCon name) (badDataCon name)
badDataCon :: RdrName -> SDoc
badDataCon name
= hsep [ptext (sLit "Illegal data constructor name"), quotes (ppr name)]
|