{-# LANGUAGE NondecreasingIndentation #-} {-# LANGUAGE TypeSynonymInstances #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE CPP #-} -- | This is the driver for the 'ghc --backpack' mode, which -- is a reimplementation of the "package manager" bits of -- Backpack directly in GHC. The basic method of operation -- is to compile packages and then directly insert them into -- GHC's in memory database. -- -- The compilation products of this mode aren't really suitable -- for Cabal, because GHC makes up component IDs for the things -- it builds and doesn't serialize out the database contents. -- But it's still handy for constructing tests. module GHC.Driver.Backpack (doBackpack) where #include "HsVersions.h" import GhcPrelude -- In a separate module because it hooks into the parser. import GHC.Driver.Backpack.Syntax import GHC.Parser.Annotation import GHC hiding (Failed, Succeeded) import GHC.Driver.Packages import GHC.Parser import GHC.Parser.Lexer import GHC.Driver.Monad import GHC.Driver.Session import GHC.Tc.Utils.Monad import GHC.Tc.Module import GHC.Types.Module import GHC.Driver.Types import StringBuffer import FastString import ErrUtils import GHC.Types.SrcLoc import GHC.Driver.Main import GHC.Types.Unique.FM import GHC.Types.Unique.DFM import Outputable import Maybes import GHC.Parser.Header import GHC.Iface.Recomp import GHC.Driver.Make import GHC.Types.Unique.DSet import GHC.Builtin.Names import GHC.Types.Basic hiding (SuccessFlag(..)) import GHC.Driver.Finder import Util import qualified GHC.LanguageExtensions as LangExt import Panic import Data.List ( partition ) import System.Exit import Control.Monad import System.FilePath import Data.Version -- for the unification import Data.IORef import Data.Map (Map) import qualified Data.Map as Map -- | Entry point to compile a Backpack file. doBackpack :: [FilePath] -> Ghc () doBackpack [src_filename] = do -- Apply options from file to dflags dflags0 <- getDynFlags let dflags1 = dflags0 src_opts <- liftIO $ getOptionsFromFile dflags1 src_filename (dflags, unhandled_flags, warns) <- liftIO $ parseDynamicFilePragma dflags1 src_opts modifySession (\hsc_env -> hsc_env {hsc_dflags = dflags}) -- Cribbed from: preprocessFile / GHC.Driver.Pipeline liftIO $ checkProcessArgsResult dflags unhandled_flags liftIO $ handleFlagWarnings dflags warns -- TODO: Preprocessing not implemented buf <- liftIO $ hGetStringBuffer src_filename let loc = mkRealSrcLoc (mkFastString src_filename) 1 1 -- TODO: not great case unP parseBackpack (mkPState dflags buf loc) of PFailed pst -> throwErrors (getErrorMessages pst dflags) POk _ pkgname_bkp -> do -- OK, so we have an LHsUnit PackageName, but we want an -- LHsUnit HsComponentId. So let's rename it. let pkgstate = pkgState dflags let bkp = renameHsUnits pkgstate (packageNameMap pkgstate pkgname_bkp) pkgname_bkp initBkpM src_filename bkp $ forM_ (zip [1..] bkp) $ \(i, lunit) -> do let comp_name = unLoc (hsunitName (unLoc lunit)) msgTopPackage (i,length bkp) comp_name innerBkpM $ do let (cid, insts) = computeUnitId lunit if null insts then if cid == ComponentId (fsLit "main") Nothing then compileExe lunit else compileUnit cid [] else typecheckUnit cid insts doBackpack _ = throwGhcException (CmdLineError "--backpack can only process a single file") computeUnitId :: LHsUnit HsComponentId -> (ComponentId, [(ModuleName, Module)]) computeUnitId (L _ unit) = (cid, [ (r, mkHoleModule r) | r <- reqs ]) where cid = hsComponentId (unLoc (hsunitName unit)) reqs = uniqDSetToList (unionManyUniqDSets (map (get_reqs . unLoc) (hsunitBody unit))) get_reqs (DeclD HsigFile (L _ modname) _) = unitUniqDSet modname get_reqs (DeclD HsSrcFile _ _) = emptyUniqDSet get_reqs (DeclD HsBootFile _ _) = emptyUniqDSet get_reqs (IncludeD (IncludeDecl (L _ hsuid) _ _)) = unitIdFreeHoles (convertHsUnitId hsuid) -- | Tiny enum for all types of Backpack operations we may do. data SessionType -- | A compilation operation which will result in a -- runnable executable being produced. = ExeSession -- | A type-checking operation which produces only -- interface files, no object files. | TcSession -- | A compilation operation which produces both -- interface files and object files. | CompSession deriving (Eq) -- | Create a temporary Session to do some sort of type checking or -- compilation. withBkpSession :: ComponentId -> [(ModuleName, Module)] -> [(UnitId, ModRenaming)] -> SessionType -- what kind of session are we doing -> BkpM a -- actual action to run -> BkpM a withBkpSession cid insts deps session_type do_this = do dflags <- getDynFlags let (ComponentId cid_fs _) = cid is_primary = False uid_str = unpackFS (hashUnitId cid insts) cid_str = unpackFS cid_fs -- There are multiple units in a single Backpack file, so we -- need to separate out the results in those cases. Right now, -- we follow this hierarchy: -- $outputdir/$compid --> typecheck results -- $outputdir/$compid/$unitid --> compile results key_base p | Just f <- p dflags = f | otherwise = "." sub_comp p | is_primary = p | otherwise = p cid_str outdir p | CompSession <- session_type -- Special case when package is definite , not (null insts) = sub_comp (key_base p) uid_str | otherwise = sub_comp (key_base p) withTempSession (overHscDynFlags (\dflags -> -- If we're type-checking an indefinite package, we want to -- turn on interface writing. However, if the user also -- explicitly passed in `-fno-code`, we DON'T want to write -- interfaces unless the user also asked for `-fwrite-interface`. -- See Note [-fno-code mode] (case session_type of -- Make sure to write interfaces when we are type-checking -- indefinite packages. TcSession | hscTarget dflags /= HscNothing -> flip gopt_set Opt_WriteInterface | otherwise -> id CompSession -> id ExeSession -> id) $ dflags { hscTarget = case session_type of TcSession -> HscNothing _ -> hscTarget dflags, thisUnitIdInsts_ = Just insts, thisComponentId_ = Just cid, thisInstalledUnitId = case session_type of TcSession -> newInstalledUnitId cid Nothing -- No hash passed if no instances _ | null insts -> newInstalledUnitId cid Nothing | otherwise -> newInstalledUnitId cid (Just (hashUnitId cid insts)), -- Setup all of the output directories according to our hierarchy objectDir = Just (outdir objectDir), hiDir = Just (outdir hiDir), stubDir = Just (outdir stubDir), -- Unset output-file for non exe builds outputFile = if session_type == ExeSession then outputFile dflags else Nothing, -- Clear the import path so we don't accidentally grab anything importPaths = [], -- Synthesized the flags packageFlags = packageFlags dflags ++ map (\(uid0, rn) -> let uid = unwireUnitId dflags (improveUnitId (getUnitInfoMap dflags) $ renameHoleUnitId dflags (listToUFM insts) uid0) in ExposePackage (showSDoc dflags (text "-unit-id" <+> ppr uid <+> ppr rn)) (UnitIdArg uid) rn) deps } )) $ do dflags <- getSessionDynFlags -- pprTrace "flags" (ppr insts <> ppr deps) $ return () -- Calls initPackages _ <- setSessionDynFlags dflags do_this withBkpExeSession :: [(UnitId, ModRenaming)] -> BkpM a -> BkpM a withBkpExeSession deps do_this = do withBkpSession (ComponentId (fsLit "main") Nothing) [] deps ExeSession do_this getSource :: ComponentId -> BkpM (LHsUnit HsComponentId) getSource cid = do bkp_env <- getBkpEnv case Map.lookup cid (bkp_table bkp_env) of Nothing -> pprPanic "missing needed dependency" (ppr cid) Just lunit -> return lunit typecheckUnit :: ComponentId -> [(ModuleName, Module)] -> BkpM () typecheckUnit cid insts = do lunit <- getSource cid buildUnit TcSession cid insts lunit compileUnit :: ComponentId -> [(ModuleName, Module)] -> BkpM () compileUnit cid insts = do -- Let everyone know we're building this unit ID msgUnitId (newUnitId cid insts) lunit <- getSource cid buildUnit CompSession cid insts lunit -- | Compute the dependencies with instantiations of a syntactic -- HsUnit; e.g., wherever you see @dependency p[A=]@ in a -- unit file, return the 'UnitId' corresponding to @p[A=]@. -- The @include_sigs@ parameter controls whether or not we also -- include @dependency signature@ declarations in this calculation. -- -- Invariant: this NEVER returns InstalledUnitId. hsunitDeps :: Bool {- include sigs -} -> HsUnit HsComponentId -> [(UnitId, ModRenaming)] hsunitDeps include_sigs unit = concatMap get_dep (hsunitBody unit) where get_dep (L _ (IncludeD (IncludeDecl (L _ hsuid) mb_lrn is_sig))) | include_sigs || not is_sig = [(convertHsUnitId hsuid, go mb_lrn)] | otherwise = [] where go Nothing = ModRenaming True [] go (Just lrns) = ModRenaming False (map convRn lrns) where convRn (L _ (Renaming (L _ from) Nothing)) = (from, from) convRn (L _ (Renaming (L _ from) (Just (L _ to)))) = (from, to) get_dep _ = [] buildUnit :: SessionType -> ComponentId -> [(ModuleName, Module)] -> LHsUnit HsComponentId -> BkpM () buildUnit session cid insts lunit = do -- NB: include signature dependencies ONLY when typechecking. -- If we're compiling, it's not necessary to recursively -- compile a signature since it isn't going to produce -- any object files. let deps_w_rns = hsunitDeps (session == TcSession) (unLoc lunit) raw_deps = map fst deps_w_rns dflags <- getDynFlags -- The compilation dependencies are just the appropriately filled -- in unit IDs which must be compiled before we can compile. let hsubst = listToUFM insts deps0 = map (renameHoleUnitId dflags hsubst) raw_deps -- Build dependencies OR make sure they make sense. BUT NOTE, -- we can only check the ones that are fully filled; the rest -- we have to defer until we've typechecked our local signature. -- TODO: work this into GHC.Driver.Make!! forM_ (zip [1..] deps0) $ \(i, dep) -> case session of TcSession -> return () _ -> compileInclude (length deps0) (i, dep) dflags <- getDynFlags -- IMPROVE IT let deps = map (improveUnitId (getUnitInfoMap dflags)) deps0 mb_old_eps <- case session of TcSession -> fmap Just getEpsGhc _ -> return Nothing conf <- withBkpSession cid insts deps_w_rns session $ do dflags <- getDynFlags mod_graph <- hsunitModuleGraph dflags (unLoc lunit) -- pprTrace "mod_graph" (ppr mod_graph) $ return () msg <- mkBackpackMsg ok <- load' LoadAllTargets (Just msg) mod_graph when (failed ok) (liftIO $ exitWith (ExitFailure 1)) let hi_dir = expectJust (panic "hiDir Backpack") $ hiDir dflags export_mod ms = (ms_mod_name ms, ms_mod ms) -- Export everything! mods = [ export_mod ms | ms <- mgModSummaries mod_graph , ms_hsc_src ms == HsSrcFile ] -- Compile relevant only hsc_env <- getSession let home_mod_infos = eltsUDFM (hsc_HPT hsc_env) linkables = map (expectJust "bkp link" . hm_linkable) . filter ((==HsSrcFile) . mi_hsc_src . hm_iface) $ home_mod_infos getOfiles (LM _ _ us) = map nameOfObject (filter isObject us) obj_files = concatMap getOfiles linkables let compat_fs = (case cid of ComponentId fs _ -> fs) compat_pn = PackageName compat_fs return InstalledPackageInfo { -- Stub data abiHash = "", sourcePackageId = SourcePackageId compat_fs, packageName = compat_pn, packageVersion = makeVersion [0], unitId = toInstalledUnitId (thisPackage dflags), sourceLibName = Nothing, componentId = cid, instantiatedWith = insts, -- Slight inefficiency here haha exposedModules = map (\(m,n) -> (m,Just n)) mods, hiddenModules = [], -- TODO: doc only depends = case session of -- Technically, we should state that we depend -- on all the indefinite libraries we used to -- typecheck this. However, this field isn't -- really used for anything, so we leave it -- blank for now. TcSession -> [] _ -> map (toInstalledUnitId . unwireUnitId dflags) $ deps ++ [ moduleUnitId mod | (_, mod) <- insts , not (isHoleModule mod) ], abiDepends = [], ldOptions = case session of TcSession -> [] _ -> obj_files, importDirs = [ hi_dir ], exposed = False, indefinite = case session of TcSession -> True _ -> False, -- nope hsLibraries = [], extraLibraries = [], extraGHCiLibraries = [], libraryDynDirs = [], libraryDirs = [], frameworks = [], frameworkDirs = [], ccOptions = [], includes = [], includeDirs = [], haddockInterfaces = [], haddockHTMLs = [], trusted = False } addPackage conf case mb_old_eps of Just old_eps -> updateEpsGhc_ (const old_eps) _ -> return () compileExe :: LHsUnit HsComponentId -> BkpM () compileExe lunit = do msgUnitId mainUnitId let deps_w_rns = hsunitDeps False (unLoc lunit) deps = map fst deps_w_rns -- no renaming necessary forM_ (zip [1..] deps) $ \(i, dep) -> compileInclude (length deps) (i, dep) withBkpExeSession deps_w_rns $ do dflags <- getDynFlags mod_graph <- hsunitModuleGraph dflags (unLoc lunit) msg <- mkBackpackMsg ok <- load' LoadAllTargets (Just msg) mod_graph when (failed ok) (liftIO $ exitWith (ExitFailure 1)) -- | Register a new virtual package database containing a single unit addPackage :: GhcMonad m => UnitInfo -> m () addPackage pkg = do dflags <- GHC.getSessionDynFlags case pkgDatabase dflags of Nothing -> panic "addPackage: called too early" Just dbs -> do let newdb = PackageDatabase { packageDatabasePath = "(in memory " ++ showSDoc dflags (ppr (unitId pkg)) ++ ")" , packageDatabaseUnits = [pkg] } _ <- GHC.setSessionDynFlags (dflags { pkgDatabase = Just (dbs ++ [newdb]) }) return () -- Precondition: UnitId is NOT InstalledUnitId compileInclude :: Int -> (Int, UnitId) -> BkpM () compileInclude n (i, uid) = do hsc_env <- getSession let dflags = hsc_dflags hsc_env msgInclude (i, n) uid -- Check if we've compiled it already case lookupUnit dflags uid of Nothing -> do case splitUnitIdInsts uid of (_, Just indef) -> innerBkpM $ compileUnit (indefUnitIdComponentId indef) (indefUnitIdInsts indef) _ -> return () Just _ -> return () -- ---------------------------------------------------------------------------- -- Backpack monad -- | Backpack monad is a 'GhcMonad' which also maintains a little extra state -- beyond the 'Session', c.f. 'BkpEnv'. type BkpM = IOEnv BkpEnv -- | Backpack environment. NB: this has a 'Session' and not an 'HscEnv', -- because we are going to update the 'HscEnv' as we go. data BkpEnv = BkpEnv { -- | The session bkp_session :: Session, -- | The filename of the bkp file we're compiling bkp_filename :: FilePath, -- | Table of source units which we know how to compile bkp_table :: Map ComponentId (LHsUnit HsComponentId), -- | When a package we are compiling includes another package -- which has not been compiled, we bump the level and compile -- that. bkp_level :: Int } -- Blah, to get rid of the default instance for IOEnv -- TODO: just make a proper new monad for BkpM, rather than use IOEnv instance {-# OVERLAPPING #-} HasDynFlags BkpM where getDynFlags = fmap hsc_dflags getSession instance GhcMonad BkpM where getSession = do Session s <- fmap bkp_session getEnv readMutVar s setSession hsc_env = do Session s <- fmap bkp_session getEnv writeMutVar s hsc_env -- | Get the current 'BkpEnv'. getBkpEnv :: BkpM BkpEnv getBkpEnv = getEnv -- | Get the nesting level, when recursively compiling modules. getBkpLevel :: BkpM Int getBkpLevel = bkp_level `fmap` getBkpEnv -- | Apply a function on 'DynFlags' on an 'HscEnv' overHscDynFlags :: (DynFlags -> DynFlags) -> HscEnv -> HscEnv overHscDynFlags f hsc_env = hsc_env { hsc_dflags = f (hsc_dflags hsc_env) } -- | Run a 'BkpM' computation, with the nesting level bumped one. innerBkpM :: BkpM a -> BkpM a innerBkpM do_this = do -- NB: withTempSession mutates, so we don't have to worry -- about bkp_session being stale. updEnv (\env -> env { bkp_level = bkp_level env + 1 }) do_this -- | Update the EPS from a 'GhcMonad'. TODO move to appropriate library spot. updateEpsGhc_ :: GhcMonad m => (ExternalPackageState -> ExternalPackageState) -> m () updateEpsGhc_ f = do hsc_env <- getSession liftIO $ atomicModifyIORef' (hsc_EPS hsc_env) (\x -> (f x, ())) -- | Get the EPS from a 'GhcMonad'. getEpsGhc :: GhcMonad m => m ExternalPackageState getEpsGhc = do hsc_env <- getSession liftIO $ readIORef (hsc_EPS hsc_env) -- | Run 'BkpM' in 'Ghc'. initBkpM :: FilePath -> [LHsUnit HsComponentId] -> BkpM a -> Ghc a initBkpM file bkp m = do reifyGhc $ \session -> do let env = BkpEnv { bkp_session = session, bkp_table = Map.fromList [(hsComponentId (unLoc (hsunitName (unLoc u))), u) | u <- bkp], bkp_filename = file, bkp_level = 0 } runIOEnv env m -- ---------------------------------------------------------------------------- -- Messaging -- | Print a compilation progress message, but with indentation according -- to @level@ (for nested compilation). backpackProgressMsg :: Int -> DynFlags -> String -> IO () backpackProgressMsg level dflags msg = compilationProgressMsg dflags $ replicate (level * 2) ' ' ++ msg -- | Creates a 'Messager' for Backpack compilation; this is basically -- a carbon copy of 'batchMsg' but calling 'backpackProgressMsg', which -- handles indentation. mkBackpackMsg :: BkpM Messager mkBackpackMsg = do level <- getBkpLevel return $ \hsc_env mod_index recomp mod_summary -> let dflags = hsc_dflags hsc_env showMsg msg reason = backpackProgressMsg level dflags $ showModuleIndex mod_index ++ msg ++ showModMsg dflags (hscTarget dflags) (recompileRequired recomp) mod_summary ++ reason in case recomp of MustCompile -> showMsg "Compiling " "" UpToDate | verbosity (hsc_dflags hsc_env) >= 2 -> showMsg "Skipping " "" | otherwise -> return () RecompBecause reason -> showMsg "Compiling " (" [" ++ reason ++ "]") -- | 'PprStyle' for Backpack messages; here we usually want the module to -- be qualified (so we can tell how it was instantiated.) But we try not -- to qualify packages so we can use simple names for them. backpackStyle :: DynFlags -> PprStyle backpackStyle dflags = mkUserStyle dflags (QueryQualify neverQualifyNames alwaysQualifyModules neverQualifyPackages) AllTheWay -- | Message when we initially process a Backpack unit. msgTopPackage :: (Int,Int) -> HsComponentId -> BkpM () msgTopPackage (i,n) (HsComponentId (PackageName fs_pn) _) = do dflags <- getDynFlags level <- getBkpLevel liftIO . backpackProgressMsg level dflags $ showModuleIndex (i, n) ++ "Processing " ++ unpackFS fs_pn -- | Message when we instantiate a Backpack unit. msgUnitId :: UnitId -> BkpM () msgUnitId pk = do dflags <- getDynFlags level <- getBkpLevel liftIO . backpackProgressMsg level dflags $ "Instantiating " ++ renderWithStyle (initSDocContext dflags (backpackStyle dflags)) (ppr pk) -- | Message when we include a Backpack unit. msgInclude :: (Int,Int) -> UnitId -> BkpM () msgInclude (i,n) uid = do dflags <- getDynFlags level <- getBkpLevel liftIO . backpackProgressMsg level dflags $ showModuleIndex (i, n) ++ "Including " ++ renderWithStyle (initSDocContext dflags (backpackStyle dflags)) (ppr uid) -- ---------------------------------------------------------------------------- -- Conversion from PackageName to HsComponentId type PackageNameMap a = Map PackageName a -- For now, something really simple, since we're not actually going -- to use this for anything unitDefines :: PackageState -> LHsUnit PackageName -> (PackageName, HsComponentId) unitDefines pkgstate (L _ HsUnit{ hsunitName = L _ pn@(PackageName fs) }) = (pn, HsComponentId pn (mkComponentId pkgstate fs)) packageNameMap :: PackageState -> [LHsUnit PackageName] -> PackageNameMap HsComponentId packageNameMap pkgstate units = Map.fromList (map (unitDefines pkgstate) units) renameHsUnits :: PackageState -> PackageNameMap HsComponentId -> [LHsUnit PackageName] -> [LHsUnit HsComponentId] renameHsUnits pkgstate m units = map (fmap renameHsUnit) units where renamePackageName :: PackageName -> HsComponentId renamePackageName pn = case Map.lookup pn m of Nothing -> case lookupPackageName pkgstate pn of Nothing -> error "no package name" Just cid -> HsComponentId pn cid Just hscid -> hscid renameHsUnit :: HsUnit PackageName -> HsUnit HsComponentId renameHsUnit u = HsUnit { hsunitName = fmap renamePackageName (hsunitName u), hsunitBody = map (fmap renameHsUnitDecl) (hsunitBody u) } renameHsUnitDecl :: HsUnitDecl PackageName -> HsUnitDecl HsComponentId renameHsUnitDecl (DeclD a b c) = DeclD a b c renameHsUnitDecl (IncludeD idecl) = IncludeD IncludeDecl { idUnitId = fmap renameHsUnitId (idUnitId idecl), idModRenaming = idModRenaming idecl, idSignatureInclude = idSignatureInclude idecl } renameHsUnitId :: HsUnitId PackageName -> HsUnitId HsComponentId renameHsUnitId (HsUnitId ln subst) = HsUnitId (fmap renamePackageName ln) (map (fmap renameHsModuleSubst) subst) renameHsModuleSubst :: HsModuleSubst PackageName -> HsModuleSubst HsComponentId renameHsModuleSubst (lk, lm) = (lk, fmap renameHsModuleId lm) renameHsModuleId :: HsModuleId PackageName -> HsModuleId HsComponentId renameHsModuleId (HsModuleVar lm) = HsModuleVar lm renameHsModuleId (HsModuleId luid lm) = HsModuleId (fmap renameHsUnitId luid) lm convertHsUnitId :: HsUnitId HsComponentId -> UnitId convertHsUnitId (HsUnitId (L _ hscid) subst) = newUnitId (hsComponentId hscid) (map (convertHsModuleSubst . unLoc) subst) convertHsModuleSubst :: HsModuleSubst HsComponentId -> (ModuleName, Module) convertHsModuleSubst (L _ modname, L _ m) = (modname, convertHsModuleId m) convertHsModuleId :: HsModuleId HsComponentId -> Module convertHsModuleId (HsModuleVar (L _ modname)) = mkHoleModule modname convertHsModuleId (HsModuleId (L _ hsuid) (L _ modname)) = mkModule (convertHsUnitId hsuid) modname {- ************************************************************************ * * Module graph construction * * ************************************************************************ -} -- | This is our version of GHC.Driver.Make.downsweep, but with a few modifications: -- -- 1. Every module is required to be mentioned, so we don't do any funny -- business with targets or recursively grabbing dependencies. (We -- could support this in principle). -- 2. We support inline modules, whose summary we have to synthesize ourself. -- -- We don't bother trying to support GHC.Driver.Make for now, it's more trouble -- than it's worth for inline modules. hsunitModuleGraph :: DynFlags -> HsUnit HsComponentId -> BkpM ModuleGraph hsunitModuleGraph dflags unit = do let decls = hsunitBody unit pn = hsPackageName (unLoc (hsunitName unit)) -- 1. Create a HsSrcFile/HsigFile summary for every -- explicitly mentioned module/signature. let get_decl (L _ (DeclD hsc_src lmodname mb_hsmod)) = do Just `fmap` summariseDecl pn hsc_src lmodname mb_hsmod get_decl _ = return Nothing nodes <- catMaybes `fmap` mapM get_decl decls -- 2. For each hole which does not already have an hsig file, -- create an "empty" hsig file to induce compilation for the -- requirement. let node_map = Map.fromList [ ((ms_mod_name n, ms_hsc_src n == HsigFile), n) | n <- nodes ] req_nodes <- fmap catMaybes . forM (thisUnitIdInsts dflags) $ \(mod_name, _) -> let has_local = Map.member (mod_name, True) node_map in if has_local then return Nothing else fmap Just $ summariseRequirement pn mod_name -- 3. Return the kaboodle return $ mkModuleGraph $ nodes ++ req_nodes summariseRequirement :: PackageName -> ModuleName -> BkpM ModSummary summariseRequirement pn mod_name = do hsc_env <- getSession let dflags = hsc_dflags hsc_env let PackageName pn_fs = pn location <- liftIO $ mkHomeModLocation2 dflags mod_name (unpackFS pn_fs moduleNameSlashes mod_name) "hsig" env <- getBkpEnv time <- liftIO $ getModificationUTCTime (bkp_filename env) hi_timestamp <- liftIO $ modificationTimeIfExists (ml_hi_file location) hie_timestamp <- liftIO $ modificationTimeIfExists (ml_hie_file location) let loc = srcLocSpan (mkSrcLoc (mkFastString (bkp_filename env)) 1 1) mod <- liftIO $ addHomeModuleToFinder hsc_env mod_name location extra_sig_imports <- liftIO $ findExtraSigImports hsc_env HsigFile mod_name return ModSummary { ms_mod = mod, ms_hsc_src = HsigFile, ms_location = location, ms_hs_date = time, ms_obj_date = Nothing, ms_iface_date = hi_timestamp, ms_hie_date = hie_timestamp, ms_srcimps = [], ms_textual_imps = extra_sig_imports, ms_parsed_mod = Just (HsParsedModule { hpm_module = L loc (HsModule { hsmodName = Just (L loc mod_name), hsmodExports = Nothing, hsmodImports = [], hsmodDecls = [], hsmodDeprecMessage = Nothing, hsmodHaddockModHeader = Nothing }), hpm_src_files = [], hpm_annotations = ApiAnns Map.empty Nothing Map.empty [] }), ms_hspp_file = "", -- none, it came inline ms_hspp_opts = dflags, ms_hspp_buf = Nothing } summariseDecl :: PackageName -> HscSource -> Located ModuleName -> Maybe (Located HsModule) -> BkpM ModSummary summariseDecl pn hsc_src (L _ modname) (Just hsmod) = hsModuleToModSummary pn hsc_src modname hsmod summariseDecl _pn hsc_src lmodname@(L loc modname) Nothing = do hsc_env <- getSession let dflags = hsc_dflags hsc_env -- TODO: this looks for modules in the wrong place r <- liftIO $ summariseModule hsc_env Map.empty -- GHC API recomp not supported (hscSourceToIsBoot hsc_src) lmodname True -- Target lets you disallow, but not here Nothing -- GHC API buffer support not supported [] -- No exclusions case r of Nothing -> throwOneError (mkPlainErrMsg dflags loc (text "module" <+> ppr modname <+> text "was not found")) Just (Left err) -> throwErrors err Just (Right summary) -> return summary -- | Up until now, GHC has assumed a single compilation target per source file. -- Backpack files with inline modules break this model, since a single file -- may generate multiple output files. How do we decide to name these files? -- Should there only be one output file? This function our current heuristic, -- which is we make a "fake" module and use that. hsModuleToModSummary :: PackageName -> HscSource -> ModuleName -> Located HsModule -> BkpM ModSummary hsModuleToModSummary pn hsc_src modname hsmod = do let imps = hsmodImports (unLoc hsmod) loc = getLoc hsmod hsc_env <- getSession -- Sort of the same deal as in GHC.Driver.Pipeline's getLocation -- Use the PACKAGE NAME to find the location let PackageName unit_fs = pn dflags = hsc_dflags hsc_env -- Unfortunately, we have to define a "fake" location in -- order to appease the various code which uses the file -- name to figure out where to put, e.g. object files. -- To add insult to injury, we don't even actually use -- these filenames to figure out where the hi files go. -- A travesty! location0 <- liftIO $ mkHomeModLocation2 dflags modname (unpackFS unit_fs moduleNameSlashes modname) (case hsc_src of HsigFile -> "hsig" HsBootFile -> "hs-boot" HsSrcFile -> "hs") -- DANGEROUS: bootifying can POISON the module finder cache let location = case hsc_src of HsBootFile -> addBootSuffixLocnOut location0 _ -> location0 -- This duplicates a pile of logic in GHC.Driver.Make env <- getBkpEnv time <- liftIO $ getModificationUTCTime (bkp_filename env) hi_timestamp <- liftIO $ modificationTimeIfExists (ml_hi_file location) hie_timestamp <- liftIO $ modificationTimeIfExists (ml_hie_file location) -- Also copied from 'getImports' let (src_idecls, ord_idecls) = partition (ideclSource.unLoc) imps -- GHC.Prim doesn't exist physically, so don't go looking for it. ordinary_imps = filter ((/= moduleName gHC_PRIM) . unLoc . ideclName . unLoc) ord_idecls implicit_prelude = xopt LangExt.ImplicitPrelude dflags implicit_imports = mkPrelImports modname loc implicit_prelude imps convImport (L _ i) = (fmap sl_fs (ideclPkgQual i), ideclName i) extra_sig_imports <- liftIO $ findExtraSigImports hsc_env hsc_src modname let normal_imports = map convImport (implicit_imports ++ ordinary_imps) required_by_imports <- liftIO $ implicitRequirements hsc_env normal_imports -- So that Finder can find it, even though it doesn't exist... this_mod <- liftIO $ addHomeModuleToFinder hsc_env modname location return ModSummary { ms_mod = this_mod, ms_hsc_src = hsc_src, ms_location = location, ms_hspp_file = (case hiDir dflags of Nothing -> "" Just d -> d) ".." moduleNameSlashes modname <.> "hi", ms_hspp_opts = dflags, ms_hspp_buf = Nothing, ms_srcimps = map convImport src_idecls, ms_textual_imps = normal_imports -- We have to do something special here: -- due to merging, requirements may end up with -- extra imports ++ extra_sig_imports ++ required_by_imports, -- This is our hack to get the parse tree to the right spot ms_parsed_mod = Just (HsParsedModule { hpm_module = hsmod, hpm_src_files = [], -- TODO if we preprocessed it hpm_annotations = ApiAnns Map.empty Nothing Map.empty [] -- BOGUS }), ms_hs_date = time, ms_obj_date = Nothing, -- TODO do this, but problem: hi_timestamp is BOGUS ms_iface_date = hi_timestamp, ms_hie_date = hie_timestamp } -- | Create a new, externally provided hashed unit id from -- a hash. newInstalledUnitId :: ComponentId -> Maybe FastString -> InstalledUnitId newInstalledUnitId (ComponentId cid_fs _) (Just fs) = InstalledUnitId (cid_fs `appendFS` mkFastString "+" `appendFS` fs) newInstalledUnitId (ComponentId cid_fs _) Nothing = InstalledUnitId cid_fs