{-# OPTIONS -fno-cse #-} -- -fno-cse is needed for GLOBAL_VAR's to behave properly ----------------------------------------------------------------------------- -- -- GHC Driver -- -- (c) The University of Glasgow 2005 -- ----------------------------------------------------------------------------- module DriverPipeline ( -- Run a series of compilation steps in a pipeline, for a -- collection of source files. oneShot, compileFile, -- Interfaces for the batch-mode driver linkBinary, -- Interfaces for the compilation manager (interpreted/batch-mode) preprocess, compile, compile', link, ) where #include "HsVersions.h" import Packages import HeaderInfo import DriverPhases import SysTools import HscMain import Finder import HscTypes import Outputable import Module import UniqFM ( eltsUFM ) import ErrUtils import DynFlags import StaticFlags ( v_Ld_inputs, opt_PIC, opt_Static, WayName(..) ) import Config import Panic import Util import StringBuffer ( hGetStringBuffer ) import BasicTypes ( SuccessFlag(..) ) import Maybes ( expectJust ) import ParserCoreUtils ( getCoreModuleName ) import SrcLoc import FastString import LlvmCodeGen ( llvmFixupAsm ) import MonadUtils -- import Data.Either import Exception import Data.IORef ( readIORef ) -- import GHC.Exts ( Int(..) ) import System.Directory import System.FilePath import System.IO import Control.Monad import Data.List ( isSuffixOf ) import Data.Maybe import System.Environment -- --------------------------------------------------------------------------- -- Pre-process -- | Just preprocess a file, put the result in a temp. file (used by the -- compilation manager during the summary phase). -- -- We return the augmented DynFlags, because they contain the result -- of slurping in the OPTIONS pragmas preprocess :: HscEnv -> (FilePath, Maybe Phase) -- ^ filename and starting phase -> IO (DynFlags, FilePath) preprocess hsc_env (filename, mb_phase) = ASSERT2(isJust mb_phase || isHaskellSrcFilename filename, text filename) runPipeline anyHsc hsc_env (filename, mb_phase) Nothing Temporary Nothing{-no ModLocation-} -- --------------------------------------------------------------------------- -- | Compile -- -- Compile a single module, under the control of the compilation manager. -- -- This is the interface between the compilation manager and the -- compiler proper (hsc), where we deal with tedious details like -- reading the OPTIONS pragma from the source file, converting the -- C or assembly that GHC produces into an object file, and compiling -- FFI stub files. -- -- NB. No old interface can also mean that the source has changed. compile :: HscEnv -> ModSummary -- ^ summary for module being compiled -> Int -- ^ module N ... -> Int -- ^ ... of M -> Maybe ModIface -- ^ old interface, if we have one -> Maybe Linkable -- ^ old linkable, if we have one -> IO HomeModInfo -- ^ the complete HomeModInfo, if successful compile = compile' (hscCompileNothing, hscCompileInteractive, hscCompileBatch) compile' :: (Compiler (HscStatus, ModIface, ModDetails), Compiler (InteractiveStatus, ModIface, ModDetails), Compiler (HscStatus, ModIface, ModDetails)) -> HscEnv -> ModSummary -- ^ summary for module being compiled -> Int -- ^ module N ... -> Int -- ^ ... of M -> Maybe ModIface -- ^ old interface, if we have one -> Maybe Linkable -- ^ old linkable, if we have one -> IO HomeModInfo -- ^ the complete HomeModInfo, if successful compile' (nothingCompiler, interactiveCompiler, batchCompiler) hsc_env0 summary mod_index nmods mb_old_iface maybe_old_linkable = do let dflags0 = ms_hspp_opts summary this_mod = ms_mod summary src_flavour = ms_hsc_src summary location = ms_location summary input_fn = expectJust "compile:hs" (ml_hs_file location) input_fnpp = ms_hspp_file summary debugTraceMsg dflags0 2 (text "compile: input file" <+> text input_fnpp) let basename = dropExtension input_fn -- We add the directory in which the .hs files resides) to the import path. -- This is needed when we try to compile the .hc file later, if it -- imports a _stub.h file that we created here. let current_dir = case takeDirectory basename of "" -> "." -- XXX Hack d -> d old_paths = includePaths dflags0 dflags = dflags0 { includePaths = current_dir : old_paths } hsc_env = hsc_env0 {hsc_dflags = dflags} -- Figure out what lang we're generating let hsc_lang = hscMaybeAdjustTarget dflags StopLn src_flavour (hscTarget dflags) -- ... and what the next phase should be let next_phase = hscNextPhase dflags src_flavour hsc_lang -- ... and what file to generate the output into output_fn <- getOutputFilename next_phase Temporary basename dflags next_phase (Just location) let dflags' = dflags { hscTarget = hsc_lang, hscOutName = output_fn, extCoreName = basename ++ ".hcr" } let hsc_env' = hsc_env { hsc_dflags = dflags' } -- -fforce-recomp should also work with --make let force_recomp = dopt Opt_ForceRecomp dflags source_unchanged = isJust maybe_old_linkable && not force_recomp object_filename = ml_obj_file location let getStubLinkable False = return [] getStubLinkable True = do stub_o <- compileStub hsc_env' this_mod location return [ DotO stub_o ] handleBatch HscNoRecomp = ASSERT (isJust maybe_old_linkable) return maybe_old_linkable handleBatch (HscRecomp hasStub _) | isHsBoot src_flavour = do when (isObjectTarget hsc_lang) $ -- interpreted reaches here too liftIO $ SysTools.touch dflags' "Touching object file" object_filename return maybe_old_linkable | otherwise = do stub_unlinked <- getStubLinkable hasStub (hs_unlinked, unlinked_time) <- case hsc_lang of HscNothing -> return ([], ms_hs_date summary) -- We're in --make mode: finish the compilation pipeline. _other -> do _ <- runPipeline StopLn hsc_env' (output_fn,Nothing) (Just basename) Persistent (Just location) -- The object filename comes from the ModLocation o_time <- getModificationTime object_filename return ([DotO object_filename], o_time) let linkable = LM unlinked_time this_mod (hs_unlinked ++ stub_unlinked) return (Just linkable) handleInterpreted HscNoRecomp = ASSERT (isJust maybe_old_linkable) return maybe_old_linkable handleInterpreted (HscRecomp _hasStub Nothing) = ASSERT (isHsBoot src_flavour) return maybe_old_linkable handleInterpreted (HscRecomp hasStub (Just (comp_bc, modBreaks))) = do stub_unlinked <- getStubLinkable hasStub let hs_unlinked = [BCOs comp_bc modBreaks] unlinked_time = ms_hs_date summary -- Why do we use the timestamp of the source file here, -- rather than the current time? This works better in -- the case where the local clock is out of sync -- with the filesystem's clock. It's just as accurate: -- if the source is modified, then the linkable will -- be out of date. let linkable = LM unlinked_time this_mod (hs_unlinked ++ stub_unlinked) return (Just linkable) let -- runCompiler :: Compiler result -> (result -> Maybe Linkable) -- -> m HomeModInfo runCompiler compiler handle = do (result, iface, details) <- compiler hsc_env' summary source_unchanged mb_old_iface (Just (mod_index, nmods)) linkable <- handle result return (HomeModInfo{ hm_details = details, hm_iface = iface, hm_linkable = linkable }) -- run the compiler case hsc_lang of HscInterpreted -> runCompiler interactiveCompiler handleInterpreted HscNothing -> runCompiler nothingCompiler handleBatch _other -> runCompiler batchCompiler handleBatch ----------------------------------------------------------------------------- -- stub .h and .c files (for foreign export support) -- The _stub.c file is derived from the haskell source file, possibly taking -- into account the -stubdir option. -- -- Consequently, we derive the _stub.o filename from the haskell object -- filename. -- -- This isn't necessarily the same as the object filename we -- would get if we just compiled the _stub.c file using the pipeline. -- For example: -- -- ghc src/A.hs -odir obj -- -- results in obj/A.o, and src/A_stub.c. If we compile src/A_stub.c with -- -odir obj, we would get obj/src/A_stub.o, which is wrong; we want -- obj/A_stub.o. compileStub :: HscEnv -> Module -> ModLocation -> IO FilePath compileStub hsc_env mod location = do -- compile the _stub.c file w/ gcc let (stub_c,_,stub_o) = mkStubPaths (hsc_dflags hsc_env) (moduleName mod) location _ <- runPipeline StopLn hsc_env (stub_c,Nothing) Nothing (SpecificFile stub_o) Nothing{-no ModLocation-} return stub_o -- --------------------------------------------------------------------------- -- Link link :: GhcLink -- interactive or batch -> DynFlags -- dynamic flags -> Bool -- attempt linking in batch mode? -> HomePackageTable -- what to link -> IO SuccessFlag -- For the moment, in the batch linker, we don't bother to tell doLink -- which packages to link -- it just tries all that are available. -- batch_attempt_linking should only be *looked at* in batch mode. It -- should only be True if the upsweep was successful and someone -- exports main, i.e., we have good reason to believe that linking -- will succeed. #ifdef GHCI link LinkInMemory _ _ _ = do -- Not Linking...(demand linker will do the job) return Succeeded #endif link NoLink _ _ _ = return Succeeded link LinkBinary dflags batch_attempt_linking hpt = link' dflags batch_attempt_linking hpt link LinkDynLib dflags batch_attempt_linking hpt = link' dflags batch_attempt_linking hpt #ifndef GHCI -- warning suppression link other _ _ _ = panicBadLink other #endif panicBadLink :: GhcLink -> a panicBadLink other = panic ("link: GHC not built to link this way: " ++ show other) link' :: DynFlags -- dynamic flags -> Bool -- attempt linking in batch mode? -> HomePackageTable -- what to link -> IO SuccessFlag link' dflags batch_attempt_linking hpt | batch_attempt_linking = do let home_mod_infos = eltsUFM hpt -- the packages we depend on pkg_deps = concatMap (dep_pkgs . mi_deps . hm_iface) home_mod_infos -- the linkables to link linkables = map (expectJust "link".hm_linkable) home_mod_infos debugTraceMsg dflags 3 (text "link: linkables are ..." $$ vcat (map ppr linkables)) -- check for the -no-link flag if isNoLink (ghcLink dflags) then do debugTraceMsg dflags 3 (text "link(batch): linking omitted (-c flag given).") return Succeeded else do let getOfiles (LM _ _ us) = map nameOfObject (filter isObject us) obj_files = concatMap getOfiles linkables exe_file = exeFileName dflags linking_needed <- linkingNeeded dflags linkables pkg_deps if not (dopt Opt_ForceRecomp dflags) && not linking_needed then do debugTraceMsg dflags 2 (text exe_file <+> ptext (sLit "is up to date, linking not required.")) return Succeeded else do debugTraceMsg dflags 1 (ptext (sLit "Linking") <+> text exe_file <+> text "...") -- Don't showPass in Batch mode; doLink will do that for us. let link = case ghcLink dflags of LinkBinary -> linkBinary LinkDynLib -> linkDynLib other -> panicBadLink other link dflags obj_files pkg_deps debugTraceMsg dflags 3 (text "link: done") -- linkBinary only returns if it succeeds return Succeeded | otherwise = do debugTraceMsg dflags 3 (text "link(batch): upsweep (partially) failed OR" $$ text " Main.main not exported; not linking.") return Succeeded linkingNeeded :: DynFlags -> [Linkable] -> [PackageId] -> IO Bool linkingNeeded dflags linkables pkg_deps = do -- if the modification time on the executable is later than the -- modification times on all of the objects and libraries, then omit -- linking (unless the -fforce-recomp flag was given). let exe_file = exeFileName dflags e_exe_time <- tryIO $ getModificationTime exe_file case e_exe_time of Left _ -> return True Right t -> do -- first check object files and extra_ld_inputs extra_ld_inputs <- readIORef v_Ld_inputs e_extra_times <- mapM (tryIO . getModificationTime) extra_ld_inputs let (errs,extra_times) = splitEithers e_extra_times let obj_times = map linkableTime linkables ++ extra_times if not (null errs) || any (t <) obj_times then return True else do -- next, check libraries. XXX this only checks Haskell libraries, -- not extra_libraries or -l things from the command line. let pkg_map = pkgIdMap (pkgState dflags) pkg_hslibs = [ (libraryDirs c, lib) | Just c <- map (lookupPackage pkg_map) pkg_deps, lib <- packageHsLibs dflags c ] pkg_libfiles <- mapM (uncurry findHSLib) pkg_hslibs if any isNothing pkg_libfiles then return True else do e_lib_times <- mapM (tryIO . getModificationTime) (catMaybes pkg_libfiles) let (lib_errs,lib_times) = splitEithers e_lib_times if not (null lib_errs) || any (t <) lib_times then return True else return False findHSLib :: [String] -> String -> IO (Maybe FilePath) findHSLib dirs lib = do let batch_lib_file = "lib" ++ lib <.> "a" found <- filterM doesFileExist (map ( batch_lib_file) dirs) case found of [] -> return Nothing (x:_) -> return (Just x) -- ----------------------------------------------------------------------------- -- Compile files in one-shot mode. oneShot :: HscEnv -> Phase -> [(String, Maybe Phase)] -> IO () oneShot hsc_env stop_phase srcs = do o_files <- mapM (compileFile hsc_env stop_phase) srcs doLink (hsc_dflags hsc_env) stop_phase o_files compileFile :: HscEnv -> Phase -> (FilePath, Maybe Phase) -> IO FilePath compileFile hsc_env stop_phase (src, mb_phase) = do exists <- doesFileExist src when (not exists) $ ghcError (CmdLineError ("does not exist: " ++ src)) let dflags = hsc_dflags hsc_env split = dopt Opt_SplitObjs dflags mb_o_file = outputFile dflags ghc_link = ghcLink dflags -- Set by -c or -no-link -- When linking, the -o argument refers to the linker's output. -- otherwise, we use it as the name for the pipeline's output. output | StopLn <- stop_phase, not (isNoLink ghc_link) = Persistent -- -o foo applies to linker | Just o_file <- mb_o_file = SpecificFile o_file -- -o foo applies to the file we are compiling now | otherwise = Persistent stop_phase' = case stop_phase of As | split -> SplitAs _ -> stop_phase ( _, out_file) <- runPipeline stop_phase' hsc_env (src, mb_phase) Nothing output Nothing{-no ModLocation-} return out_file doLink :: DynFlags -> Phase -> [FilePath] -> IO () doLink dflags stop_phase o_files | not (isStopLn stop_phase) = return () -- We stopped before the linking phase | otherwise = case ghcLink dflags of NoLink -> return () LinkBinary -> linkBinary dflags o_files [] LinkDynLib -> linkDynLib dflags o_files [] other -> panicBadLink other -- --------------------------------------------------------------------------- data PipelineOutput = Temporary -- ^ Output should be to a temporary file: we're going to -- run more compilation steps on this output later. | Persistent -- ^ We want a persistent file, i.e. a file in the current directory -- derived from the input filename, but with the appropriate extension. -- eg. in "ghc -c Foo.hs" the output goes into ./Foo.o. | SpecificFile FilePath -- ^ The output must go into the specified file. -- | Run a compilation pipeline, consisting of multiple phases. -- -- This is the interface to the compilation pipeline, which runs -- a series of compilation steps on a single source file, specifying -- at which stage to stop. -- -- The DynFlags can be modified by phases in the pipeline (eg. by -- OPTIONS_GHC pragmas), and the changes affect later phases in the -- pipeline. runPipeline :: Phase -- ^ When to stop -> HscEnv -- ^ Compilation environment -> (FilePath,Maybe Phase) -- ^ Input filename (and maybe -x suffix) -> Maybe FilePath -- ^ original basename (if different from ^^^) -> PipelineOutput -- ^ Output filename -> Maybe ModLocation -- ^ A ModLocation, if this is a Haskell module -> IO (DynFlags, FilePath) -- ^ (final flags, output filename) runPipeline stop_phase hsc_env0 (input_fn, mb_phase) mb_basename output maybe_loc = do let dflags0 = hsc_dflags hsc_env0 (input_basename, suffix) = splitExtension input_fn suffix' = drop 1 suffix -- strip off the . basename | Just b <- mb_basename = b | otherwise = input_basename -- Decide where dump files should go based on the pipeline output dflags = dflags0 { dumpPrefix = Just (basename ++ ".") } hsc_env = hsc_env0 {hsc_dflags = dflags} -- If we were given a -x flag, then use that phase to start from start_phase = fromMaybe (startPhase suffix') mb_phase -- We want to catch cases of "you can't get there from here" before -- we start the pipeline, because otherwise it will just run off the -- end. -- -- There is a partial ordering on phases, where A < B iff A occurs -- before B in a normal compilation pipeline. when (not (start_phase `happensBefore` stop_phase)) $ ghcError (UsageError ("cannot compile this file to desired target: " ++ input_fn)) -- this is a function which will be used to calculate output file names -- as we go along (we partially apply it to some of its inputs here) let get_output_fn = getOutputFilename stop_phase output basename -- Execute the pipeline... (dflags', output_fn, maybe_loc) <- pipeLoop hsc_env start_phase stop_phase input_fn basename suffix' get_output_fn maybe_loc -- Sometimes, a compilation phase doesn't actually generate any output -- (eg. the CPP phase when -fcpp is not turned on). If we end on this -- stage, but we wanted to keep the output, then we have to explicitly -- copy the file, remembering to prepend a {-# LINE #-} pragma so that -- further compilation stages can tell what the original filename was. case output of Temporary -> return (dflags', output_fn) _other -> do final_fn <- get_output_fn dflags' stop_phase maybe_loc when (final_fn /= output_fn) $ do let msg = ("Copying `" ++ output_fn ++"' to `" ++ final_fn ++ "'") line_prag = Just ("{-# LINE 1 \"" ++ input_fn ++ "\" #-}\n") copyWithHeader dflags msg line_prag output_fn final_fn return (dflags', final_fn) pipeLoop :: HscEnv -> Phase -> Phase -> FilePath -> String -> Suffix -> (DynFlags -> Phase -> Maybe ModLocation -> IO FilePath) -> Maybe ModLocation -> IO (DynFlags, FilePath, Maybe ModLocation) pipeLoop hsc_env phase stop_phase input_fn orig_basename orig_suff orig_get_output_fn maybe_loc | phase `eqPhase` stop_phase -- All done = return (hsc_dflags hsc_env, input_fn, maybe_loc) | not (phase `happensBefore` stop_phase) -- Something has gone wrong. We'll try to cover all the cases when -- this could happen, so if we reach here it is a panic. -- eg. it might happen if the -C flag is used on a source file that -- has {-# OPTIONS -fasm #-}. = panic ("pipeLoop: at phase " ++ show phase ++ " but I wanted to stop at phase " ++ show stop_phase) | otherwise = do debugTraceMsg (hsc_dflags hsc_env) 4 (ptext (sLit "Running phase") <+> ppr phase) (next_phase, dflags', maybe_loc, output_fn) <- runPhase phase stop_phase hsc_env orig_basename orig_suff input_fn orig_get_output_fn maybe_loc let hsc_env' = hsc_env {hsc_dflags = dflags'} pipeLoop hsc_env' next_phase stop_phase output_fn orig_basename orig_suff orig_get_output_fn maybe_loc getOutputFilename :: Phase -> PipelineOutput -> String -> DynFlags -> Phase{-next phase-} -> Maybe ModLocation -> IO FilePath getOutputFilename stop_phase output basename = func where func dflags next_phase maybe_location | is_last_phase, Persistent <- output = persistent_fn | is_last_phase, SpecificFile f <- output = return f | keep_this_output = persistent_fn | otherwise = newTempName dflags suffix where hcsuf = hcSuf dflags odir = objectDir dflags osuf = objectSuf dflags keep_hc = dopt Opt_KeepHcFiles dflags keep_raw_s = dopt Opt_KeepRawSFiles dflags keep_s = dopt Opt_KeepSFiles dflags keep_bc = dopt Opt_KeepLlvmFiles dflags myPhaseInputExt HCc = hcsuf myPhaseInputExt StopLn = osuf myPhaseInputExt other = phaseInputExt other is_last_phase = next_phase `eqPhase` stop_phase -- sometimes, we keep output from intermediate stages keep_this_output = case next_phase of StopLn -> True Mangle | keep_raw_s -> True As | keep_s -> True LlvmOpt | keep_bc -> True HCc | keep_hc -> True _other -> False suffix = myPhaseInputExt next_phase -- persistent object files get put in odir persistent_fn | StopLn <- next_phase = return odir_persistent | otherwise = return persistent persistent = basename <.> suffix odir_persistent | Just loc <- maybe_location = ml_obj_file loc | Just d <- odir = d persistent | otherwise = persistent -- ----------------------------------------------------------------------------- -- | Each phase in the pipeline returns the next phase to execute, and the -- name of the file in which the output was placed. -- -- We must do things dynamically this way, because we often don't know -- what the rest of the phases will be until part-way through the -- compilation: for example, an {-# OPTIONS -fasm #-} at the beginning -- of a source file can change the latter stages of the pipeline from -- taking the via-C route to using the native code generator. -- runPhase :: Phase -- ^ Do this phase first -> Phase -- ^ Stop just before this phase -> HscEnv -> String -- ^ basename of original input source -> String -- ^ its extension -> FilePath -- ^ name of file which contains the input to this phase. -> (DynFlags -> Phase -> Maybe ModLocation -> IO FilePath) -- ^ how to calculate the output filename -> Maybe ModLocation -- ^ the ModLocation, if we have one -> IO (Phase, -- next phase DynFlags, -- new dynamic flags Maybe ModLocation, -- the ModLocation, if we have one FilePath) -- output filename -- Invariant: the output filename always contains the output -- Interesting case: Hsc when there is no recompilation to do -- Then the output filename is still a .o file ------------------------------------------------------------------------------- -- Unlit phase runPhase (Unlit sf) _stop hsc_env _basename _suff input_fn get_output_fn maybe_loc = do let dflags = hsc_dflags hsc_env output_fn <- get_output_fn dflags (Cpp sf) maybe_loc let unlit_flags = getOpts dflags opt_L flags = map SysTools.Option unlit_flags ++ [ -- The -h option passes the file name for unlit to -- put in a #line directive SysTools.Option "-h" -- cpp interprets \b etc as escape sequences, -- so we use / for filenames in pragmas , SysTools.Option $ reslash Forwards $ normalise input_fn , SysTools.FileOption "" input_fn , SysTools.FileOption "" output_fn ] SysTools.runUnlit dflags flags return (Cpp sf, dflags, maybe_loc, output_fn) ------------------------------------------------------------------------------- -- Cpp phase : (a) gets OPTIONS out of file -- (b) runs cpp if necessary runPhase (Cpp sf) _stop hsc_env _basename _suff input_fn get_output_fn maybe_loc = do let dflags0 = hsc_dflags hsc_env src_opts <- getOptionsFromFile dflags0 input_fn (dflags1, unhandled_flags, warns) <- parseDynamicNoPackageFlags dflags0 src_opts checkProcessArgsResult unhandled_flags if not (xopt Opt_Cpp dflags1) then do -- we have to be careful to emit warnings only once. unless (dopt Opt_Pp dflags1) $ handleFlagWarnings dflags1 warns -- no need to preprocess CPP, just pass input file along -- to the next phase of the pipeline. return (HsPp sf, dflags1, maybe_loc, input_fn) else do output_fn <- get_output_fn dflags1 (HsPp sf) maybe_loc doCpp dflags1 True{-raw-} False{-no CC opts-} input_fn output_fn -- re-read the pragmas now that we've preprocessed the file -- See #2464,#3457 src_opts <- getOptionsFromFile dflags0 output_fn (dflags2, unhandled_flags, warns) <- parseDynamicNoPackageFlags dflags0 src_opts unless (dopt Opt_Pp dflags2) $ handleFlagWarnings dflags2 warns -- the HsPp pass below will emit warnings checkProcessArgsResult unhandled_flags return (HsPp sf, dflags2, maybe_loc, output_fn) ------------------------------------------------------------------------------- -- HsPp phase runPhase (HsPp sf) _stop hsc_env basename suff input_fn get_output_fn maybe_loc = do let dflags = hsc_dflags hsc_env if not (dopt Opt_Pp dflags) then -- no need to preprocess, just pass input file along -- to the next phase of the pipeline. return (Hsc sf, dflags, maybe_loc, input_fn) else do let hspp_opts = getOpts dflags opt_F let orig_fn = basename <.> suff output_fn <- get_output_fn dflags (Hsc sf) maybe_loc SysTools.runPp dflags ( [ SysTools.Option orig_fn , SysTools.Option input_fn , SysTools.FileOption "" output_fn ] ++ map SysTools.Option hspp_opts ) -- re-read pragmas now that we've parsed the file (see #3674) src_opts <- getOptionsFromFile dflags output_fn (dflags1, unhandled_flags, warns) <- parseDynamicNoPackageFlags dflags src_opts handleFlagWarnings dflags1 warns checkProcessArgsResult unhandled_flags return (Hsc sf, dflags1, maybe_loc, output_fn) ----------------------------------------------------------------------------- -- Hsc phase -- Compilation of a single module, in "legacy" mode (_not_ under -- the direction of the compilation manager). runPhase (Hsc src_flavour) stop hsc_env basename suff input_fn get_output_fn _maybe_loc = do -- normal Hsc mode, not mkdependHS let dflags0 = hsc_dflags hsc_env -- we add the current directory (i.e. the directory in which -- the .hs files resides) to the include path, since this is -- what gcc does, and it's probably what you want. let current_dir = case takeDirectory basename of "" -> "." -- XXX Hack d -> d paths = includePaths dflags0 dflags = dflags0 { includePaths = current_dir : paths } -- gather the imports and module name (hspp_buf,mod_name,imps,src_imps) <- case src_flavour of ExtCoreFile -> do -- no explicit imports in ExtCore input. m <- getCoreModuleName input_fn return (Nothing, mkModuleName m, [], []) _ -> do buf <- hGetStringBuffer input_fn (src_imps,imps,L _ mod_name) <- getImports dflags buf input_fn (basename <.> suff) return (Just buf, mod_name, imps, src_imps) -- Build a ModLocation to pass to hscMain. -- The source filename is rather irrelevant by now, but it's used -- by hscMain for messages. hscMain also needs -- the .hi and .o filenames, and this is as good a way -- as any to generate them, and better than most. (e.g. takes -- into accout the -osuf flags) location1 <- mkHomeModLocation2 dflags mod_name basename suff -- Boot-ify it if necessary let location2 | isHsBoot src_flavour = addBootSuffixLocn location1 | otherwise = location1 -- Take -ohi into account if present -- This can't be done in mkHomeModuleLocation because -- it only applies to the module being compiles let ohi = outputHi dflags location3 | Just fn <- ohi = location2{ ml_hi_file = fn } | otherwise = location2 -- Take -o into account if present -- Very like -ohi, but we must *only* do this if we aren't linking -- (If we're linking then the -o applies to the linked thing, not to -- the object file for one module.) -- Note the nasty duplication with the same computation in compileFile above let expl_o_file = outputFile dflags location4 | Just ofile <- expl_o_file , isNoLink (ghcLink dflags) = location3 { ml_obj_file = ofile } | otherwise = location3 o_file = ml_obj_file location4 -- The real object file -- Figure out if the source has changed, for recompilation avoidance. -- -- Setting source_unchanged to True means that M.o seems -- to be up to date wrt M.hs; so no need to recompile unless imports have -- changed (which the compiler itself figures out). -- Setting source_unchanged to False tells the compiler that M.o is out of -- date wrt M.hs (or M.o doesn't exist) so we must recompile regardless. src_timestamp <- getModificationTime (basename <.> suff) let force_recomp = dopt Opt_ForceRecomp dflags hsc_lang = hscMaybeAdjustTarget dflags stop src_flavour (hscTarget dflags) source_unchanged <- if force_recomp || not (isStopLn stop) -- Set source_unchanged to False unconditionally if -- (a) recompilation checker is off, or -- (b) we aren't going all the way to .o file (e.g. ghc -S) then return False -- Otherwise look at file modification dates else do o_file_exists <- doesFileExist o_file if not o_file_exists then return False -- Need to recompile else do t2 <- getModificationTime o_file if t2 > src_timestamp then return True else return False -- get the DynFlags let next_phase = hscNextPhase dflags src_flavour hsc_lang output_fn <- get_output_fn dflags next_phase (Just location4) let dflags' = dflags { hscTarget = hsc_lang, hscOutName = output_fn, extCoreName = basename ++ ".hcr" } let hsc_env' = hsc_env {hsc_dflags = dflags'} -- Tell the finder cache about this module mod <- addHomeModuleToFinder hsc_env' mod_name location4 -- Make the ModSummary to hand to hscMain let mod_summary = ModSummary { ms_mod = mod, ms_hsc_src = src_flavour, ms_hspp_file = input_fn, ms_hspp_opts = dflags, ms_hspp_buf = hspp_buf, ms_location = location4, ms_hs_date = src_timestamp, ms_obj_date = Nothing, ms_imps = imps, ms_srcimps = src_imps } -- run the compiler! result <- hscCompileOneShot hsc_env' mod_summary source_unchanged Nothing -- No iface Nothing -- No "module i of n" progress info case result of HscNoRecomp -> do SysTools.touch dflags' "Touching object file" o_file -- The .o file must have a later modification date -- than the source file (else we wouldn't be in HscNoRecomp) -- but we touch it anyway, to keep 'make' happy (we think). return (StopLn, dflags', Just location4, o_file) (HscRecomp hasStub _) -> do when hasStub $ do stub_o <- compileStub hsc_env' mod location4 liftIO $ consIORef v_Ld_inputs stub_o -- In the case of hs-boot files, generate a dummy .o-boot -- stamp file for the benefit of Make when (isHsBoot src_flavour) $ SysTools.touch dflags' "Touching object file" o_file return (next_phase, dflags', Just location4, output_fn) ----------------------------------------------------------------------------- -- Cmm phase runPhase CmmCpp _stop hsc_env _basename _suff input_fn get_output_fn maybe_loc = do let dflags = hsc_dflags hsc_env output_fn <- get_output_fn dflags Cmm maybe_loc doCpp dflags False{-not raw-} True{-include CC opts-} input_fn output_fn return (Cmm, dflags, maybe_loc, output_fn) runPhase Cmm stop hsc_env basename _ input_fn get_output_fn maybe_loc = do let dflags = hsc_dflags hsc_env let hsc_lang = hscMaybeAdjustTarget dflags stop HsSrcFile (hscTarget dflags) let next_phase = hscNextPhase dflags HsSrcFile hsc_lang output_fn <- get_output_fn dflags next_phase maybe_loc let dflags' = dflags { hscTarget = hsc_lang, hscOutName = output_fn, extCoreName = basename ++ ".hcr" } let hsc_env' = hsc_env {hsc_dflags = dflags'} hscCompileCmmFile hsc_env' input_fn -- XXX: catch errors above and convert them into ghcError? Original -- code was: -- --when (not ok) $ ghcError (PhaseFailed "cmm" (ExitFailure 1)) return (next_phase, dflags, maybe_loc, output_fn) ----------------------------------------------------------------------------- -- Cc phase -- we don't support preprocessing .c files (with -E) now. Doing so introduces -- way too many hacks, and I can't say I've ever used it anyway. runPhase cc_phase _stop hsc_env _basename _suff input_fn get_output_fn maybe_loc | cc_phase `eqPhase` Cc || cc_phase `eqPhase` Ccpp || cc_phase `eqPhase` HCc = do let dflags = hsc_dflags hsc_env let cc_opts = getOpts dflags opt_c hcc = cc_phase `eqPhase` HCc let cmdline_include_paths = includePaths dflags -- HC files have the dependent packages stamped into them pkgs <- if hcc then getHCFilePackages input_fn else return [] -- add package include paths even if we're just compiling .c -- files; this is the Value Add(TM) that using ghc instead of -- gcc gives you :) pkg_include_dirs <- getPackageIncludePath dflags pkgs let include_paths = foldr (\ x xs -> "-I" : x : xs) [] (cmdline_include_paths ++ pkg_include_dirs) let (md_c_flags, md_regd_c_flags) = machdepCCOpts dflags gcc_extra_viac_flags <- getExtraViaCOpts dflags let pic_c_flags = picCCOpts dflags let verb = getVerbFlag dflags -- cc-options are not passed when compiling .hc files. Our -- hc code doesn't not #include any header files anyway, so these -- options aren't necessary. pkg_extra_cc_opts <- if cc_phase `eqPhase` HCc then return [] else getPackageExtraCcOpts dflags pkgs #ifdef darwin_TARGET_OS pkg_framework_paths <- getPackageFrameworkPath dflags pkgs let cmdline_framework_paths = frameworkPaths dflags let framework_paths = map ("-F"++) (cmdline_framework_paths ++ pkg_framework_paths) #endif let split_objs = dopt Opt_SplitObjs dflags split_opt | hcc && split_objs = [ "-DUSE_SPLIT_MARKERS" ] | otherwise = [ ] let cc_opt | optLevel dflags >= 2 = "-O2" | otherwise = "-O" -- Decide next phase let mangle = dopt Opt_DoAsmMangling dflags next_phase | hcc && mangle = Mangle | otherwise = As output_fn <- get_output_fn dflags next_phase maybe_loc let more_hcc_opts = #if i386_TARGET_ARCH -- on x86 the floating point regs have greater precision -- than a double, which leads to unpredictable results. -- By default, we turn this off with -ffloat-store unless -- the user specified -fexcess-precision. (if dopt Opt_ExcessPrecision dflags then [] else [ "-ffloat-store" ]) ++ #endif -- gcc's -fstrict-aliasing allows two accesses to memory -- to be considered non-aliasing if they have different types. -- This interacts badly with the C code we generate, which is -- very weakly typed, being derived from C--. ["-fno-strict-aliasing"] SysTools.runCc dflags ( -- force the C compiler to interpret this file as C when -- compiling .hc files, by adding the -x c option. -- Also useful for plain .c files, just in case GHC saw a -- -x c option. [ SysTools.Option "-x", if cc_phase `eqPhase` Ccpp then SysTools.Option "c++" else SysTools.Option "c"] ++ [ SysTools.FileOption "" input_fn , SysTools.Option "-o" , SysTools.FileOption "" output_fn ] ++ map SysTools.Option ( md_c_flags ++ pic_c_flags #if defined(mingw32_TARGET_OS) -- Stub files generated for foreign exports references the runIO_closure -- and runNonIO_closure symbols, which are defined in the base package. -- These symbols are imported into the stub.c file via RtsAPI.h, and the -- way we do the import depends on whether we're currently compiling -- the base package or not. ++ (if thisPackage dflags == basePackageId then [ "-DCOMPILING_BASE_PACKAGE" ] else []) #endif #ifdef sparc_TARGET_ARCH -- We only support SparcV9 and better because V8 lacks an atomic CAS -- instruction. Note that the user can still override this -- (e.g., -mcpu=ultrasparc) as GCC picks the "best" -mcpu flag -- regardless of the ordering. -- -- This is a temporary hack. ++ ["-mcpu=v9"] #endif ++ (if hcc && mangle then md_regd_c_flags else []) ++ (if hcc then if mangle then gcc_extra_viac_flags else filter (=="-fwrapv") gcc_extra_viac_flags -- still want -fwrapv even for unreg'd else []) ++ (if hcc then more_hcc_opts else []) ++ [ verb, "-S", "-Wimplicit", cc_opt ] ++ [ "-D__GLASGOW_HASKELL__="++cProjectVersionInt ] #ifdef darwin_TARGET_OS ++ framework_paths #endif ++ cc_opts ++ split_opt ++ include_paths ++ pkg_extra_cc_opts )) return (next_phase, dflags, maybe_loc, output_fn) -- ToDo: postprocess the output from gcc ----------------------------------------------------------------------------- -- Mangle phase runPhase Mangle _stop hsc_env _basename _suff input_fn get_output_fn maybe_loc = do let dflags = hsc_dflags hsc_env let mangler_opts = getOpts dflags opt_m #if i386_TARGET_ARCH machdep_opts <- return [ show (stolen_x86_regs dflags) ] #else machdep_opts <- return [] #endif let split = dopt Opt_SplitObjs dflags next_phase | split = SplitMangle | otherwise = As output_fn <- get_output_fn dflags next_phase maybe_loc SysTools.runMangle dflags (map SysTools.Option mangler_opts ++ [ SysTools.FileOption "" input_fn , SysTools.FileOption "" output_fn ] ++ map SysTools.Option machdep_opts) return (next_phase, dflags, maybe_loc, output_fn) ----------------------------------------------------------------------------- -- Splitting phase runPhase SplitMangle _stop hsc_env _basename _suff input_fn _get_output_fn maybe_loc = do -- tmp_pfx is the prefix used for the split .s files -- We also use it as the file to contain the no. of split .s files (sigh) let dflags = hsc_dflags hsc_env split_s_prefix <- SysTools.newTempName dflags "split" let n_files_fn = split_s_prefix SysTools.runSplit dflags [ SysTools.FileOption "" input_fn , SysTools.FileOption "" split_s_prefix , SysTools.FileOption "" n_files_fn ] -- Save the number of split files for future references s <- readFile n_files_fn let n_files = read s :: Int dflags' = dflags { splitInfo = Just (split_s_prefix, n_files) } -- Remember to delete all these files addFilesToClean dflags' [ split_s_prefix ++ "__" ++ show n ++ ".s" | n <- [1..n_files]] return (SplitAs, dflags', maybe_loc, "**splitmangle**") -- we don't use the filename ----------------------------------------------------------------------------- -- As phase runPhase As _stop hsc_env _basename _suff input_fn get_output_fn maybe_loc = do let dflags = hsc_dflags hsc_env let as_opts = getOpts dflags opt_a let cmdline_include_paths = includePaths dflags output_fn <- get_output_fn dflags StopLn maybe_loc -- we create directories for the object file, because it -- might be a hierarchical module. createDirectoryHierarchy (takeDirectory output_fn) let (md_c_flags, _) = machdepCCOpts dflags SysTools.runAs dflags (map SysTools.Option as_opts ++ [ SysTools.Option ("-I" ++ p) | p <- cmdline_include_paths ] #ifdef sparc_TARGET_ARCH -- We only support SparcV9 and better because V8 lacks an atomic CAS -- instruction so we have to make sure that the assembler accepts the -- instruction set. Note that the user can still override this -- (e.g., -mcpu=ultrasparc). GCC picks the "best" -mcpu flag -- regardless of the ordering. -- -- This is a temporary hack. ++ [ SysTools.Option "-mcpu=v9" ] #endif ++ [ SysTools.Option "-c" , SysTools.FileOption "" input_fn , SysTools.Option "-o" , SysTools.FileOption "" output_fn ] ++ map SysTools.Option md_c_flags) return (StopLn, dflags, maybe_loc, output_fn) runPhase SplitAs _stop hsc_env _basename _suff _input_fn get_output_fn maybe_loc = do let dflags = hsc_dflags hsc_env output_fn <- get_output_fn dflags StopLn maybe_loc let base_o = dropExtension output_fn osuf = objectSuf dflags split_odir = base_o ++ "_" ++ osuf ++ "_split" createDirectoryHierarchy split_odir -- remove M_split/ *.o, because we're going to archive M_split/ *.o -- later and we don't want to pick up any old objects. fs <- getDirectoryContents split_odir mapM_ removeFile $ map (split_odir ) $ filter (osuf `isSuffixOf`) fs let as_opts = getOpts dflags opt_a let (split_s_prefix, n) = case splitInfo dflags of Nothing -> panic "No split info" Just x -> x let split_s n = split_s_prefix ++ "__" ++ show n <.> "s" split_obj n = split_odir takeFileName base_o ++ "__" ++ show n <.> osuf let (md_c_flags, _) = machdepCCOpts dflags let assemble_file n = SysTools.runAs dflags (map SysTools.Option as_opts ++ #ifdef sparc_TARGET_ARCH -- We only support SparcV9 and better because V8 lacks an atomic CAS -- instruction so we have to make sure that the assembler accepts the -- instruction set. Note that the user can still override this -- (e.g., -mcpu=ultrasparc). GCC picks the "best" -mcpu flag -- regardless of the ordering. -- -- This is a temporary hack. [ SysTools.Option "-mcpu=v9" ] ++ #endif [ SysTools.Option "-c" , SysTools.Option "-o" , SysTools.FileOption "" (split_obj n) , SysTools.FileOption "" (split_s n) ] ++ map SysTools.Option md_c_flags) mapM_ assemble_file [1..n] -- join them into a single .o file joinObjectFiles dflags (map split_obj [1..n]) output_fn return (StopLn, dflags, maybe_loc, output_fn) ----------------------------------------------------------------------------- -- LlvmOpt phase runPhase LlvmOpt _stop hsc_env _basename _suff input_fn get_output_fn maybe_loc = do let dflags = hsc_dflags hsc_env let lo_opts = getOpts dflags opt_lo let opt_lvl = max 0 (min 2 $ optLevel dflags) -- don't specify anything if user has specified commands. We do this for -- opt but not llc since opt is very specifically for optimisation passes -- only, so if the user is passing us extra options we assume they know -- what they are doing and don't get in the way. let optFlag = if null lo_opts then [SysTools.Option (llvmOpts !! opt_lvl)] else [] output_fn <- get_output_fn dflags LlvmLlc maybe_loc SysTools.runLlvmOpt dflags ([ SysTools.FileOption "" input_fn, SysTools.Option "-o", SysTools.FileOption "" output_fn] ++ optFlag ++ map SysTools.Option lo_opts) return (LlvmLlc, dflags, maybe_loc, output_fn) where -- we always (unless -optlo specified) run Opt since we rely on it to -- fix up some pretty big deficiencies in the code we generate llvmOpts = ["-mem2reg", "-O1", "-O2"] ----------------------------------------------------------------------------- -- LlvmLlc phase runPhase LlvmLlc _stop hsc_env _basename _suff input_fn get_output_fn maybe_loc = do let dflags = hsc_dflags hsc_env let lc_opts = getOpts dflags opt_lc let opt_lvl = max 0 (min 2 $ optLevel dflags) #if darwin_TARGET_OS let nphase = LlvmMangle #else let nphase = As #endif let rmodel | opt_PIC = "pic" | not opt_Static = "dynamic-no-pic" | otherwise = "static" output_fn <- get_output_fn dflags nphase maybe_loc SysTools.runLlvmLlc dflags ([ SysTools.Option (llvmOpts !! opt_lvl), SysTools.Option $ "-relocation-model=" ++ rmodel, SysTools.FileOption "" input_fn, SysTools.Option "-o", SysTools.FileOption "" output_fn] ++ map SysTools.Option lc_opts) return (nphase, dflags, maybe_loc, output_fn) where #if darwin_TARGET_OS llvmOpts = ["-O1", "-O2", "-O2"] #else llvmOpts = ["-O1", "-O2", "-O3"] #endif ----------------------------------------------------------------------------- -- LlvmMangle phase runPhase LlvmMangle _stop hsc_env _basename _suff input_fn get_output_fn maybe_loc = do let dflags = hsc_dflags hsc_env output_fn <- get_output_fn dflags As maybe_loc llvmFixupAsm input_fn output_fn return (As, dflags, maybe_loc, output_fn) -- warning suppression runPhase other _stop _dflags _basename _suff _input_fn _get_output_fn _maybe_loc = panic ("runPhase: don't know how to run phase " ++ show other) ----------------------------------------------------------------------------- -- MoveBinary sort-of-phase -- After having produced a binary, move it somewhere else and generate a -- wrapper script calling the binary. Currently, we need this only in -- a parallel way (i.e. in GUM), because PVM expects the binary in a -- central directory. -- This is called from linkBinary below, after linking. I haven't made it -- a separate phase to minimise interfering with other modules, and -- we don't need the generality of a phase (MoveBinary is always -- done after linking and makes only sense in a parallel setup) -- HWL runPhase_MoveBinary :: DynFlags -> FilePath -> IO Bool runPhase_MoveBinary dflags input_fn | WayPar `elem` (wayNames dflags) && not opt_Static = panic ("Don't know how to combine PVM wrapper and dynamic wrapper") | WayPar `elem` (wayNames dflags) = do let sysMan = pgm_sysman dflags pvm_root <- getEnv "PVM_ROOT" pvm_arch <- getEnv "PVM_ARCH" let pvm_executable_base = "=" ++ input_fn pvm_executable = pvm_root ++ "/bin/" ++ pvm_arch ++ "/" ++ pvm_executable_base -- nuke old binary; maybe use configur'ed names for cp and rm? _ <- tryIO (removeFile pvm_executable) -- move the newly created binary into PVM land copy dflags "copying PVM executable" input_fn pvm_executable -- generate a wrapper script for running a parallel prg under PVM writeFile input_fn (mk_pvm_wrapper_script pvm_executable pvm_executable_base sysMan) return True | otherwise = return True mkExtraCObj :: DynFlags -> [String] -> IO FilePath mkExtraCObj dflags xs = do cFile <- newTempName dflags "c" oFile <- newTempName dflags "o" writeFile cFile $ unlines xs let rtsDetails = getPackageDetails (pkgState dflags) rtsPackageId (md_c_flags, _) = machdepCCOpts dflags SysTools.runCc dflags ([Option "-c", FileOption "" cFile, Option "-o", FileOption "" oFile] ++ map (FileOption "-I") (includeDirs rtsDetails) ++ map Option md_c_flags) return oFile mkRtsOptionsLevelObj :: DynFlags -> IO [FilePath] mkRtsOptionsLevelObj dflags = do let mkRtsEnabledObj val = do fn <- mkExtraCObj dflags ["#include \"Rts.h\"", "#include \"RtsOpts.h\"", "const rtsOptsEnabledEnum rtsOptsEnabled = " ++ val ++ ";"] return [fn] case rtsOptsEnabled dflags of RtsOptsNone -> mkRtsEnabledObj "rtsOptsNone" RtsOptsSafeOnly -> return [] -- The default RtsOptsAll -> mkRtsEnabledObj "rtsOptsAll" -- generates a Perl skript starting a parallel prg under PVM mk_pvm_wrapper_script :: String -> String -> String -> String mk_pvm_wrapper_script pvm_executable pvm_executable_base sysMan = unlines $ [ "eval 'exec perl -S $0 ${1+\"$@\"}'", " if $running_under_some_shell;", "# =!=!=!=!=!=!=!=!=!=!=!", "# This script is automatically generated: DO NOT EDIT!!!", "# Generated by Glasgow Haskell Compiler", "# ngoqvam choHbogh vaj' vIHoHnISbej !!!!", "#", "$pvm_executable = '" ++ pvm_executable ++ "';", "$pvm_executable_base = '" ++ pvm_executable_base ++ "';", "$SysMan = '" ++ sysMan ++ "';", "", {- ToDo: add the magical shortcuts again iff we actually use them -- HWL "# first, some magical shortcuts to run "commands" on the binary", "# (which is hidden)", "if ($#ARGV == 1 && $ARGV[0] eq '+RTS' && $ARGV[1] =~ /^--((size|file|strip|rm|nm).*)/ ) {", " local($cmd) = $1;", " system("$cmd $pvm_executable");", " exit(0); # all done", "}", -} "", "# Now, run the real binary; process the args first", "$ENV{'PE'} = $pvm_executable_base;", -- ++ pvm_executable_base, "$debug = '';", "$nprocessors = 0; # the default: as many PEs as machines in PVM config", "@nonPVM_args = ();", "$in_RTS_args = 0;", "", "args: while ($a = shift(@ARGV)) {", " if ( $a eq '+RTS' ) {", " $in_RTS_args = 1;", " } elsif ( $a eq '-RTS' ) {", " $in_RTS_args = 0;", " }", " if ( $a eq '-d' && $in_RTS_args ) {", " $debug = '-';", " } elsif ( $a =~ /^-qN(\\d+)/ && $in_RTS_args ) {", " $nprocessors = $1;", " } elsif ( $a =~ /^-qp(\\d+)/ && $in_RTS_args ) {", " $nprocessors = $1;", " } else {", " push(@nonPVM_args, $a);", " }", "}", "", "local($return_val) = 0;", "# Start the parallel execution by calling SysMan", "system(\"$SysMan $debug $pvm_executable $nprocessors @nonPVM_args\");", "$return_val = $?;", "# ToDo: fix race condition moving files and flushing them!!", "system(\"cp $ENV{'HOME'}/$pvm_executable_base.???.gr .\") if -f \"$ENV{'HOME'}/$pvm_executable_base.002.gr\";", "exit($return_val);" ] ----------------------------------------------------------------------------- -- Look for the /* GHC_PACKAGES ... */ comment at the top of a .hc file getHCFilePackages :: FilePath -> IO [PackageId] getHCFilePackages filename = Exception.bracket (openFile filename ReadMode) hClose $ \h -> do l <- hGetLine h case l of '/':'*':' ':'G':'H':'C':'_':'P':'A':'C':'K':'A':'G':'E':'S':rest -> return (map stringToPackageId (words rest)) _other -> return [] ----------------------------------------------------------------------------- -- Static linking, of .o files -- The list of packages passed to link is the list of packages on -- which this program depends, as discovered by the compilation -- manager. It is combined with the list of packages that the user -- specifies on the command line with -package flags. -- -- In one-shot linking mode, we can't discover the package -- dependencies (because we haven't actually done any compilation or -- read any interface files), so the user must explicitly specify all -- the packages. linkBinary :: DynFlags -> [FilePath] -> [PackageId] -> IO () linkBinary dflags o_files dep_packages = do let verb = getVerbFlag dflags output_fn = exeFileName dflags -- get the full list of packages to link with, by combining the -- explicit packages with the auto packages and all of their -- dependencies, and eliminating duplicates. pkg_lib_paths <- getPackageLibraryPath dflags dep_packages let pkg_lib_path_opts = concat (map get_pkg_lib_path_opts pkg_lib_paths) #ifdef elf_OBJ_FORMAT get_pkg_lib_path_opts l | (dynLibLoader dflags)==SystemDependent && not opt_Static = ["-L" ++ l, "-Wl,-rpath", "-Wl," ++ l] | otherwise = ["-L" ++ l] #else get_pkg_lib_path_opts l = ["-L" ++ l] #endif let lib_paths = libraryPaths dflags let lib_path_opts = map ("-L"++) lib_paths -- The C "main" function is not in the rts but in a separate static -- library libHSrtsmain.a that sits next to the rts lib files. Assuming -- we're using a Haskell main function then we need to link it in. let no_hs_main = dopt Opt_NoHsMain dflags let main_lib | no_hs_main = [] | otherwise = [ "-lHSrtsmain" ] rtsEnabledObj <- mkRtsOptionsLevelObj dflags rtsOptsObj <- case rtsOpts dflags of Just opts -> do fn <- mkExtraCObj dflags -- We assume that the Haskell "show" does -- the right thing here ["char *ghc_rts_opts = " ++ show opts ++ ";"] return [fn] Nothing -> return [] pkg_link_opts <- getPackageLinkOpts dflags dep_packages #ifdef darwin_TARGET_OS pkg_framework_paths <- getPackageFrameworkPath dflags dep_packages let pkg_framework_path_opts = map ("-F"++) pkg_framework_paths let framework_paths = frameworkPaths dflags framework_path_opts = map ("-F"++) framework_paths pkg_frameworks <- getPackageFrameworks dflags dep_packages let pkg_framework_opts = concat [ ["-framework", fw] | fw <- pkg_frameworks ] let frameworks = cmdlineFrameworks dflags framework_opts = concat [ ["-framework", fw] | fw <- reverse frameworks ] -- reverse because they're added in reverse order from the cmd line #endif -- probably _stub.o files extra_ld_inputs <- readIORef v_Ld_inputs -- opts from -optl- (including -l options) let extra_ld_opts = getOpts dflags opt_l let ways = wayNames dflags -- Here are some libs that need to be linked at the *end* of -- the command line, because they contain symbols that are referred to -- by the RTS. We can't therefore use the ordinary way opts for these. let debug_opts | WayDebug `elem` ways = [ #if defined(HAVE_LIBBFD) "-lbfd", "-liberty" #endif ] | otherwise = [] let thread_opts | WayThreaded `elem` ways = [ #if !defined(mingw32_TARGET_OS) && !defined(freebsd_TARGET_OS) && !defined(openbsd_TARGET_OS) && !defined(haiku_TARGET_OS) "-lpthread" #endif #if defined(osf3_TARGET_OS) , "-lexc" #endif ] | otherwise = [] rc_objs <- maybeCreateManifest dflags output_fn let (md_c_flags, _) = machdepCCOpts dflags SysTools.runLink dflags ( [ SysTools.Option verb , SysTools.Option "-o" , SysTools.FileOption "" output_fn ] ++ map SysTools.Option ( md_c_flags #ifdef mingw32_TARGET_OS -- Permit the linker to auto link _symbol to _imp_symbol. -- This lets us link against DLLs without needing an "import library". ++ ["-Wl,--enable-auto-import"] #endif ++ o_files ++ extra_ld_inputs ++ lib_path_opts ++ extra_ld_opts ++ rc_objs #ifdef darwin_TARGET_OS ++ framework_path_opts ++ framework_opts #endif ++ pkg_lib_path_opts ++ main_lib ++ rtsEnabledObj ++ rtsOptsObj ++ pkg_link_opts #ifdef darwin_TARGET_OS ++ pkg_framework_path_opts ++ pkg_framework_opts #endif ++ debug_opts ++ thread_opts )) -- parallel only: move binary to another dir -- HWL success <- runPhase_MoveBinary dflags output_fn if success then return () else ghcError (InstallationError ("cannot move binary")) exeFileName :: DynFlags -> FilePath exeFileName dflags | Just s <- outputFile dflags = #if defined(mingw32_HOST_OS) if null (takeExtension s) then s <.> "exe" else s #else s #endif | otherwise = #if defined(mingw32_HOST_OS) "main.exe" #else "a.out" #endif maybeCreateManifest :: DynFlags -> FilePath -- filename of executable -> IO [FilePath] -- extra objects to embed, maybe #ifndef mingw32_TARGET_OS maybeCreateManifest _ _ = do return [] #else maybeCreateManifest dflags exe_filename = do if not (dopt Opt_GenManifest dflags) then return [] else do let manifest_filename = exe_filename <.> "manifest" writeFile manifest_filename $ "\n"++ " \n"++ " \n\n"++ " \n"++ " \n"++ " \n"++ " \n"++ " \n"++ " \n"++ " \n"++ "\n" -- Windows will find the manifest file if it is named foo.exe.manifest. -- However, for extra robustness, and so that we can move the binary around, -- we can embed the manifest in the binary itself using windres: if not (dopt Opt_EmbedManifest dflags) then return [] else do rc_filename <- newTempName dflags "rc" rc_obj_filename <- newTempName dflags (objectSuf dflags) writeFile rc_filename $ "1 24 MOVEABLE PURE " ++ show manifest_filename ++ "\n" -- magic numbers :-) -- show is a bit hackish above, but we need to escape the -- backslashes in the path. let wr_opts = getOpts dflags opt_windres runWindres dflags $ map SysTools.Option $ ["--input="++rc_filename, "--output="++rc_obj_filename, "--output-format=coff"] ++ wr_opts -- no FileOptions here: windres doesn't like seeing -- backslashes, apparently removeFile manifest_filename return [rc_obj_filename] #endif linkDynLib :: DynFlags -> [String] -> [PackageId] -> IO () linkDynLib dflags o_files dep_packages = do let verb = getVerbFlag dflags let o_file = outputFile dflags pkgs <- getPreloadPackagesAnd dflags dep_packages let pkg_lib_paths = collectLibraryPaths pkgs let pkg_lib_path_opts = concatMap get_pkg_lib_path_opts pkg_lib_paths #ifdef elf_OBJ_FORMAT get_pkg_lib_path_opts l | (dynLibLoader dflags)==SystemDependent && not opt_Static = ["-L" ++ l, "-Wl,-rpath", "-Wl," ++ l] | otherwise = ["-L" ++ l] #else get_pkg_lib_path_opts l = ["-L" ++ l] #endif let lib_paths = libraryPaths dflags let lib_path_opts = map ("-L"++) lib_paths -- We don't want to link our dynamic libs against the RTS package, -- because the RTS lib comes in several flavours and we want to be -- able to pick the flavour when a binary is linked. -- On Windows we need to link the RTS import lib as Windows does -- not allow undefined symbols. -- The RTS library path is still added to the library search path -- above in case the RTS is being explicitly linked in (see #3807). #if !defined(mingw32_HOST_OS) let pkgs_no_rts = filter ((/= rtsPackageId) . packageConfigId) pkgs #else let pkgs_no_rts = pkgs #endif let pkg_link_opts = collectLinkOpts dflags pkgs_no_rts -- probably _stub.o files extra_ld_inputs <- readIORef v_Ld_inputs let (md_c_flags, _) = machdepCCOpts dflags let extra_ld_opts = getOpts dflags opt_l rtsEnabledObj <- mkRtsOptionsLevelObj dflags #if defined(mingw32_HOST_OS) ----------------------------------------------------------------------------- -- Making a DLL ----------------------------------------------------------------------------- let output_fn = case o_file of { Just s -> s; Nothing -> "HSdll.dll"; } SysTools.runLink dflags ([ SysTools.Option verb , SysTools.Option "-o" , SysTools.FileOption "" output_fn , SysTools.Option "-shared" ] ++ [ SysTools.FileOption "-Wl,--out-implib=" (output_fn ++ ".a") | dopt Opt_SharedImplib dflags ] ++ map (SysTools.FileOption "") o_files ++ map SysTools.Option ( md_c_flags -- Permit the linker to auto link _symbol to _imp_symbol -- This lets us link against DLLs without needing an "import library" ++ ["-Wl,--enable-auto-import"] ++ extra_ld_inputs ++ lib_path_opts ++ extra_ld_opts ++ pkg_lib_path_opts ++ rtsEnabledObj ++ pkg_link_opts )) #elif defined(darwin_TARGET_OS) ----------------------------------------------------------------------------- -- Making a darwin dylib ----------------------------------------------------------------------------- -- About the options used for Darwin: -- -dynamiclib -- Apple's way of saying -shared -- -undefined dynamic_lookup: -- Without these options, we'd have to specify the correct dependencies -- for each of the dylibs. Note that we could (and should) do without this -- for all libraries except the RTS; all we need to do is to pass the -- correct HSfoo_dyn.dylib files to the link command. -- This feature requires Mac OS X 10.3 or later; there is a similar feature, -- -flat_namespace -undefined suppress, which works on earlier versions, -- but it has other disadvantages. -- -single_module -- Build the dynamic library as a single "module", i.e. no dynamic binding -- nonsense when referring to symbols from within the library. The NCG -- assumes that this option is specified (on i386, at least). -- -install_name -- Mac OS/X stores the path where a dynamic library is (to be) installed -- in the library itself. It's called the "install name" of the library. -- Then any library or executable that links against it before it's -- installed will search for it in its ultimate install location. By -- default we set the install name to the absolute path at build time, but -- it can be overridden by the -dylib-install-name option passed to ghc. -- Cabal does this. ----------------------------------------------------------------------------- let output_fn = case o_file of { Just s -> s; Nothing -> "a.out"; } instName <- case dylibInstallName dflags of Just n -> return n Nothing -> do pwd <- getCurrentDirectory return $ pwd `combine` output_fn SysTools.runLink dflags ([ SysTools.Option verb , SysTools.Option "-dynamiclib" , SysTools.Option "-o" , SysTools.FileOption "" output_fn ] ++ map SysTools.Option ( md_c_flags ++ o_files ++ [ "-undefined", "dynamic_lookup", "-single_module", "-Wl,-read_only_relocs,suppress", "-install_name", instName ] ++ extra_ld_inputs ++ lib_path_opts ++ extra_ld_opts ++ pkg_lib_path_opts ++ rtsEnabledObj ++ pkg_link_opts )) #else ----------------------------------------------------------------------------- -- Making a DSO ----------------------------------------------------------------------------- let output_fn = case o_file of { Just s -> s; Nothing -> "a.out"; } let buildingRts = thisPackage dflags == rtsPackageId let bsymbolicFlag = if buildingRts then -- -Bsymbolic breaks the way we implement -- hooks in the RTS [] else -- we need symbolic linking to resolve -- non-PIC intra-package-relocations ["-Wl,-Bsymbolic"] SysTools.runLink dflags ([ SysTools.Option verb , SysTools.Option "-o" , SysTools.FileOption "" output_fn ] ++ map SysTools.Option ( md_c_flags ++ o_files ++ [ "-shared" ] ++ bsymbolicFlag ++ [ "-Wl,-soname," ++ takeFileName output_fn ] -- set the library soname ++ extra_ld_inputs ++ lib_path_opts ++ extra_ld_opts ++ pkg_lib_path_opts ++ rtsEnabledObj ++ pkg_link_opts )) #endif -- ----------------------------------------------------------------------------- -- Running CPP doCpp :: DynFlags -> Bool -> Bool -> FilePath -> FilePath -> IO () doCpp dflags raw include_cc_opts input_fn output_fn = do let hscpp_opts = getOpts dflags opt_P let cmdline_include_paths = includePaths dflags pkg_include_dirs <- getPackageIncludePath dflags [] let include_paths = foldr (\ x xs -> "-I" : x : xs) [] (cmdline_include_paths ++ pkg_include_dirs) let verb = getVerbFlag dflags let cc_opts | not include_cc_opts = [] | otherwise = (optc ++ md_c_flags) where optc = getOpts dflags opt_c (md_c_flags, _) = machdepCCOpts dflags let cpp_prog args | raw = SysTools.runCpp dflags args | otherwise = SysTools.runCc dflags (SysTools.Option "-E" : args) let target_defs = [ "-D" ++ HOST_OS ++ "_BUILD_OS=1", "-D" ++ HOST_ARCH ++ "_BUILD_ARCH=1", "-D" ++ TARGET_OS ++ "_HOST_OS=1", "-D" ++ TARGET_ARCH ++ "_HOST_ARCH=1" ] -- remember, in code we *compile*, the HOST is the same our TARGET, -- and BUILD is the same as our HOST. cpp_prog ([SysTools.Option verb] ++ map SysTools.Option include_paths ++ map SysTools.Option hsSourceCppOpts ++ map SysTools.Option target_defs ++ map SysTools.Option hscpp_opts ++ map SysTools.Option cc_opts ++ [ SysTools.Option "-x" , SysTools.Option "c" , SysTools.Option input_fn -- We hackily use Option instead of FileOption here, so that the file -- name is not back-slashed on Windows. cpp is capable of -- dealing with / in filenames, so it works fine. Furthermore -- if we put in backslashes, cpp outputs #line directives -- with *double* backslashes. And that in turn means that -- our error messages get double backslashes in them. -- In due course we should arrange that the lexer deals -- with these \\ escapes properly. , SysTools.Option "-o" , SysTools.FileOption "" output_fn ]) hsSourceCppOpts :: [String] -- Default CPP defines in Haskell source hsSourceCppOpts = [ "-D__GLASGOW_HASKELL__="++cProjectVersionInt ] -- --------------------------------------------------------------------------- -- join object files into a single relocatable object file, using ld -r joinObjectFiles :: DynFlags -> [FilePath] -> FilePath -> IO () joinObjectFiles dflags o_files output_fn = do let ld_r args = SysTools.runLink dflags ([ SysTools.Option "-nostdlib", SysTools.Option "-nodefaultlibs", SysTools.Option "-Wl,-r", SysTools.Option ld_x_flag, SysTools.Option "-o", SysTools.FileOption "" output_fn ] ++ map SysTools.Option md_c_flags ++ args) ld_x_flag | null cLD_X = "" | otherwise = "-Wl,-x" (md_c_flags, _) = machdepCCOpts dflags if cLdIsGNULd == "YES" then do script <- newTempName dflags "ldscript" writeFile script $ "INPUT(" ++ unwords o_files ++ ")" ld_r [SysTools.FileOption "" script] else do ld_r (map (SysTools.FileOption "") o_files) -- ----------------------------------------------------------------------------- -- Misc. hscNextPhase :: DynFlags -> HscSource -> HscTarget -> Phase hscNextPhase _ HsBootFile _ = StopLn hscNextPhase dflags _ hsc_lang = case hsc_lang of HscC -> HCc HscAsm | dopt Opt_SplitObjs dflags -> SplitMangle | otherwise -> As HscLlvm -> LlvmOpt HscNothing -> StopLn HscInterpreted -> StopLn _other -> StopLn hscMaybeAdjustTarget :: DynFlags -> Phase -> HscSource -> HscTarget -> HscTarget hscMaybeAdjustTarget dflags stop _ current_hsc_lang = hsc_lang where keep_hc = dopt Opt_KeepHcFiles dflags hsc_lang -- don't change the lang if we're interpreting | current_hsc_lang == HscInterpreted = current_hsc_lang -- force -fvia-C if we are being asked for a .hc file | HCc <- stop = HscC | keep_hc = HscC -- otherwise, stick to the plan | otherwise = current_hsc_lang