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|
{-# LANGUAGE BangPatterns #-}
{-# LANGUAGE NondecreasingIndentation #-}
{-# LANGUAGE TupleSections #-}
{-# LANGUAGE GADTs #-}
{-# OPTIONS_GHC -fprof-auto-top #-}
-------------------------------------------------------------------------------
--
-- | Main API for compiling plain Haskell source code.
--
-- This module implements compilation of a Haskell source. It is
-- /not/ concerned with preprocessing of source files; this is handled
-- in "GHC.Driver.Pipeline"
--
-- There are various entry points depending on what mode we're in:
-- "batch" mode (@--make@), "one-shot" mode (@-c@, @-S@ etc.), and
-- "interactive" mode (GHCi). There are also entry points for
-- individual passes: parsing, typechecking/renaming, desugaring, and
-- simplification.
--
-- All the functions here take an 'HscEnv' as a parameter, but none of
-- them return a new one: 'HscEnv' is treated as an immutable value
-- from here on in (although it has mutable components, for the
-- caches).
--
-- We use the Hsc monad to deal with warning messages consistently:
-- specifically, while executing within an Hsc monad, warnings are
-- collected. When a Hsc monad returns to an IO monad, the
-- warnings are printed, or compilation aborts if the @-Werror@
-- flag is enabled.
--
-- (c) The GRASP/AQUA Project, Glasgow University, 1993-2000
--
-------------------------------------------------------------------------------
module GHC.Driver.Main
(
-- * Making an HscEnv
newHscEnv
, newHscEnvWithHUG
-- * Compiling complete source files
, Messager, batchMsg, batchMultiMsg
, HscBackendAction (..), HscRecompStatus (..)
, initModDetails
, hscMaybeWriteIface
, hscCompileCmmFile
, hscGenHardCode
, hscInteractive
-- * Running passes separately
, hscRecompStatus
, hscParse
, hscTypecheckRename
, hscTypecheckAndGetWarnings
, hscDesugar
, makeSimpleDetails
, hscSimplify -- ToDo, shouldn't really export this
, hscDesugarAndSimplify
-- * Safe Haskell
, hscCheckSafe
, hscGetSafe
-- * Support for interactive evaluation
, hscParseIdentifier
, hscTcRcLookupName
, hscTcRnGetInfo
, hscIsGHCiMonad
, hscGetModuleInterface
, hscRnImportDecls
, hscTcRnLookupRdrName
, hscStmt, hscParseStmtWithLocation, hscStmtWithLocation, hscParsedStmt
, hscDecls, hscParseDeclsWithLocation, hscDeclsWithLocation, hscParsedDecls
, hscParseModuleWithLocation
, hscTcExpr, TcRnExprMode(..), hscImport, hscKcType
, hscParseExpr
, hscParseType
, hscCompileCoreExpr
-- * Low-level exports for hooks
, hscCompileCoreExpr'
-- We want to make sure that we export enough to be able to redefine
-- hsc_typecheck in client code
, hscParse', hscSimplify', hscDesugar', tcRnModule', doCodeGen
, getHscEnv
, hscSimpleIface'
, oneShotMsg
, dumpIfaceStats
, ioMsgMaybe
, showModuleIndex
, hscAddSptEntries
, writeInterfaceOnlyMode
) where
import GHC.Prelude
import GHC.Driver.Plugins
import GHC.Driver.Session
import GHC.Driver.Backend
import GHC.Driver.Env
import GHC.Driver.Errors
import GHC.Driver.Errors.Types
import GHC.Driver.CodeOutput
import GHC.Driver.Config.Logger (initLogFlags)
import GHC.Driver.Config.Parser (initParserOpts)
import GHC.Driver.Config.Stg.Ppr (initStgPprOpts)
import GHC.Driver.Config.Stg.Pipeline (initStgPipelineOpts)
import GHC.Driver.Config.StgToCmm (initStgToCmmConfig)
import GHC.Driver.Config.Diagnostic
import GHC.Driver.Hooks
import GHC.Runtime.Context
import GHC.Runtime.Interpreter ( addSptEntry )
import GHC.Runtime.Loader ( initializePlugins )
import GHCi.RemoteTypes ( ForeignHValue )
import GHC.ByteCode.Types
import GHC.Linker.Loader
import GHC.Linker.Types
import GHC.Hs
import GHC.Hs.Dump
import GHC.Hs.Stats ( ppSourceStats )
import GHC.HsToCore
import GHC.StgToByteCode ( byteCodeGen )
import GHC.IfaceToCore ( typecheckIface )
import GHC.Iface.Load ( ifaceStats, writeIface )
import GHC.Iface.Make
import GHC.Iface.Recomp
import GHC.Iface.Tidy
import GHC.Iface.Ext.Ast ( mkHieFile )
import GHC.Iface.Ext.Types ( getAsts, hie_asts, hie_module )
import GHC.Iface.Ext.Binary ( readHieFile, writeHieFile , hie_file_result)
import GHC.Iface.Ext.Debug ( diffFile, validateScopes )
import GHC.Core
import GHC.Core.Tidy ( tidyExpr )
import GHC.Core.Type ( Type, Kind )
import GHC.Core.Lint ( lintInteractiveExpr )
import GHC.Core.Multiplicity
import GHC.Core.Utils ( exprType )
import GHC.Core.ConLike
import GHC.Core.Opt.Pipeline
import GHC.Core.TyCon
import GHC.Core.InstEnv
import GHC.Core.FamInstEnv
import GHC.CoreToStg.Prep
import GHC.CoreToStg ( coreToStg )
import GHC.Parser.Errors.Types
import GHC.Parser
import GHC.Parser.Lexer as Lexer
import GHC.Tc.Module
import GHC.Tc.Utils.Monad
import GHC.Tc.Utils.Zonk ( ZonkFlexi (DefaultFlexi) )
import GHC.Stg.Syntax
import GHC.Stg.Pipeline ( stg2stg )
import GHC.Builtin.Utils
import GHC.Builtin.Names
import GHC.Builtin.Uniques ( mkPseudoUniqueE )
import qualified GHC.StgToCmm as StgToCmm ( codeGen )
import GHC.StgToCmm.Types (CgInfos (..), ModuleLFInfos)
import GHC.Cmm
import GHC.Cmm.Parser ( parseCmmFile )
import GHC.Cmm.Info.Build
import GHC.Cmm.Pipeline
import GHC.Cmm.Info
import GHC.Unit
import GHC.Unit.Env
import GHC.Unit.Finder
import GHC.Unit.External
import GHC.Unit.Module.ModDetails
import GHC.Unit.Module.ModGuts
import GHC.Unit.Module.ModIface
import GHC.Unit.Module.ModSummary
import GHC.Unit.Module.Graph
import GHC.Unit.Module.Imported
import GHC.Unit.Module.Deps
import GHC.Unit.Module.Status
import GHC.Unit.Home.ModInfo
import GHC.Types.Id
import GHC.Types.SourceError
import GHC.Types.SafeHaskell
import GHC.Types.ForeignStubs
import GHC.Types.Var.Env ( emptyTidyEnv )
import GHC.Types.Error
import GHC.Types.Fixity.Env
import GHC.Types.CostCentre
import GHC.Types.IPE
import GHC.Types.SourceFile
import GHC.Types.SrcLoc
import GHC.Types.Name
import GHC.Types.Name.Cache ( initNameCache )
import GHC.Types.Name.Reader
import GHC.Types.Name.Ppr
import GHC.Types.TyThing
import GHC.Types.HpcInfo
import GHC.Utils.Fingerprint ( Fingerprint )
import GHC.Utils.Panic
import GHC.Utils.Panic.Plain
import GHC.Utils.Error
import GHC.Utils.Outputable
import GHC.Utils.Misc
import GHC.Utils.Logger
import GHC.Utils.TmpFs
import GHC.Data.FastString
import GHC.Data.Bag
import GHC.Data.StringBuffer
import qualified GHC.Data.Stream as Stream
import GHC.Data.Stream (Stream)
import qualified GHC.SysTools
import Data.Data hiding (Fixity, TyCon)
import Data.List ( nub, isPrefixOf, partition )
import Control.Monad
import Data.IORef
import System.FilePath as FilePath
import System.Directory
import System.IO (fixIO)
import qualified Data.Set as S
import Data.Set (Set)
import Data.Functor
import Control.DeepSeq (force)
import Data.Bifunctor (first)
import GHC.Data.Maybe
import GHC.Driver.Env.KnotVars
import GHC.Types.Name.Set (NonCaffySet)
import GHC.Driver.GenerateCgIPEStub (generateCgIPEStub)
import Data.List.NonEmpty (NonEmpty ((:|)))
{- **********************************************************************
%* *
Initialisation
%* *
%********************************************************************* -}
newHscEnv :: DynFlags -> IO HscEnv
newHscEnv dflags = newHscEnvWithHUG dflags (homeUnitId_ dflags) home_unit_graph
where
home_unit_graph = unitEnv_singleton
(homeUnitId_ dflags)
(mkHomeUnitEnv dflags emptyHomePackageTable Nothing)
newHscEnvWithHUG :: DynFlags -> UnitId -> HomeUnitGraph -> IO HscEnv
newHscEnvWithHUG top_dynflags cur_unit home_unit_graph = do
nc_var <- initNameCache 'r' knownKeyNames
fc_var <- initFinderCache
logger <- initLogger
tmpfs <- initTmpFs
let dflags = homeUnitEnv_dflags $ unitEnv_lookup cur_unit home_unit_graph
unit_env <- initUnitEnv cur_unit home_unit_graph (ghcNameVersion dflags) (targetPlatform dflags)
return HscEnv { hsc_dflags = top_dynflags
, hsc_logger = setLogFlags logger (initLogFlags top_dynflags)
, hsc_targets = []
, hsc_mod_graph = emptyMG
, hsc_IC = emptyInteractiveContext dflags
, hsc_NC = nc_var
, hsc_FC = fc_var
, hsc_type_env_vars = emptyKnotVars
, hsc_interp = Nothing
, hsc_unit_env = unit_env
, hsc_plugins = emptyPlugins
, hsc_hooks = emptyHooks
, hsc_tmpfs = tmpfs
}
-- -----------------------------------------------------------------------------
getDiagnostics :: Hsc (Messages GhcMessage)
getDiagnostics = Hsc $ \_ w -> return (w, w)
clearDiagnostics :: Hsc ()
clearDiagnostics = Hsc $ \_ _ -> return ((), emptyMessages)
logDiagnostics :: Messages GhcMessage -> Hsc ()
logDiagnostics w = Hsc $ \_ w0 -> return ((), w0 `unionMessages` w)
getHscEnv :: Hsc HscEnv
getHscEnv = Hsc $ \e w -> return (e, w)
handleWarnings :: Hsc ()
handleWarnings = do
diag_opts <- initDiagOpts <$> getDynFlags
logger <- getLogger
w <- getDiagnostics
liftIO $ printOrThrowDiagnostics logger diag_opts w
clearDiagnostics
-- | log warning in the monad, and if there are errors then
-- throw a SourceError exception.
logWarningsReportErrors :: (Messages PsWarning, Messages PsError) -> Hsc ()
logWarningsReportErrors (warnings,errors) = do
logDiagnostics (GhcPsMessage <$> warnings)
when (not $ isEmptyMessages errors) $ throwErrors (GhcPsMessage <$> errors)
-- | Log warnings and throw errors, assuming the messages
-- contain at least one error (e.g. coming from PFailed)
handleWarningsThrowErrors :: (Messages PsWarning, Messages PsError) -> Hsc a
handleWarningsThrowErrors (warnings, errors) = do
diag_opts <- initDiagOpts <$> getDynFlags
logDiagnostics (GhcPsMessage <$> warnings)
logger <- getLogger
let (wWarns, wErrs) = partitionMessages warnings
liftIO $ printMessages logger diag_opts wWarns
throwErrors $ fmap GhcPsMessage $ errors `unionMessages` wErrs
-- | Deal with errors and warnings returned by a compilation step
--
-- In order to reduce dependencies to other parts of the compiler, functions
-- outside the "main" parts of GHC return warnings and errors as a parameter
-- and signal success via by wrapping the result in a 'Maybe' type. This
-- function logs the returned warnings and propagates errors as exceptions
-- (of type 'SourceError').
--
-- This function assumes the following invariants:
--
-- 1. If the second result indicates success (is of the form 'Just x'),
-- there must be no error messages in the first result.
--
-- 2. If there are no error messages, but the second result indicates failure
-- there should be warnings in the first result. That is, if the action
-- failed, it must have been due to the warnings (i.e., @-Werror@).
ioMsgMaybe :: IO (Messages GhcMessage, Maybe a) -> Hsc a
ioMsgMaybe ioA = do
(msgs, mb_r) <- liftIO ioA
let (warns, errs) = partitionMessages msgs
logDiagnostics warns
case mb_r of
Nothing -> throwErrors errs
Just r -> assert (isEmptyMessages errs ) return r
-- | like ioMsgMaybe, except that we ignore error messages and return
-- 'Nothing' instead.
ioMsgMaybe' :: IO (Messages GhcMessage, Maybe a) -> Hsc (Maybe a)
ioMsgMaybe' ioA = do
(msgs, mb_r) <- liftIO $ ioA
logDiagnostics (mkMessages $ getWarningMessages msgs)
return mb_r
-- -----------------------------------------------------------------------------
-- | Lookup things in the compiler's environment
hscTcRnLookupRdrName :: HscEnv -> LocatedN RdrName -> IO [Name]
hscTcRnLookupRdrName hsc_env0 rdr_name
= runInteractiveHsc hsc_env0 $
do { hsc_env <- getHscEnv
; ioMsgMaybe $ hoistTcRnMessage $ tcRnLookupRdrName hsc_env rdr_name }
hscTcRcLookupName :: HscEnv -> Name -> IO (Maybe TyThing)
hscTcRcLookupName hsc_env0 name = runInteractiveHsc hsc_env0 $ do
hsc_env <- getHscEnv
ioMsgMaybe' $ hoistTcRnMessage $ tcRnLookupName hsc_env name
-- ignore errors: the only error we're likely to get is
-- "name not found", and the Maybe in the return type
-- is used to indicate that.
hscTcRnGetInfo :: HscEnv -> Name
-> IO (Maybe (TyThing, Fixity, [ClsInst], [FamInst], SDoc))
hscTcRnGetInfo hsc_env0 name
= runInteractiveHsc hsc_env0 $
do { hsc_env <- getHscEnv
; ioMsgMaybe' $ hoistTcRnMessage $ tcRnGetInfo hsc_env name }
hscIsGHCiMonad :: HscEnv -> String -> IO Name
hscIsGHCiMonad hsc_env name
= runHsc hsc_env $ ioMsgMaybe $ hoistTcRnMessage $ isGHCiMonad hsc_env name
hscGetModuleInterface :: HscEnv -> Module -> IO ModIface
hscGetModuleInterface hsc_env0 mod = runInteractiveHsc hsc_env0 $ do
hsc_env <- getHscEnv
ioMsgMaybe $ hoistTcRnMessage $ getModuleInterface hsc_env mod
-- -----------------------------------------------------------------------------
-- | Rename some import declarations
hscRnImportDecls :: HscEnv -> [LImportDecl GhcPs] -> IO GlobalRdrEnv
hscRnImportDecls hsc_env0 import_decls = runInteractiveHsc hsc_env0 $ do
hsc_env <- getHscEnv
ioMsgMaybe $ hoistTcRnMessage $ tcRnImportDecls hsc_env import_decls
-- -----------------------------------------------------------------------------
-- | parse a file, returning the abstract syntax
hscParse :: HscEnv -> ModSummary -> IO HsParsedModule
hscParse hsc_env mod_summary = runHsc hsc_env $ hscParse' mod_summary
-- internal version, that doesn't fail due to -Werror
hscParse' :: ModSummary -> Hsc HsParsedModule
hscParse' mod_summary
| Just r <- ms_parsed_mod mod_summary = return r
| otherwise = do
dflags <- getDynFlags
logger <- getLogger
{-# SCC "Parser" #-} withTiming logger
(text "Parser"<+>brackets (ppr $ ms_mod mod_summary))
(const ()) $ do
let src_filename = ms_hspp_file mod_summary
maybe_src_buf = ms_hspp_buf mod_summary
-------------------------- Parser ----------------
-- sometimes we already have the buffer in memory, perhaps
-- because we needed to parse the imports out of it, or get the
-- module name.
buf <- case maybe_src_buf of
Just b -> return b
Nothing -> liftIO $ hGetStringBuffer src_filename
let loc = mkRealSrcLoc (mkFastString src_filename) 1 1
let diag_opts = initDiagOpts dflags
when (wopt Opt_WarnUnicodeBidirectionalFormatCharacters dflags) $ do
case checkBidirectionFormatChars (PsLoc loc (BufPos 0)) buf of
Nothing -> pure ()
Just chars@((eloc,chr,_) :| _) ->
let span = mkSrcSpanPs $ mkPsSpan eloc (advancePsLoc eloc chr)
in logDiagnostics $ singleMessage $
mkPlainMsgEnvelope diag_opts span $
GhcPsMessage $ PsWarnBidirectionalFormatChars chars
let parseMod | HsigFile == ms_hsc_src mod_summary
= parseSignature
| otherwise = parseModule
case unP parseMod (initParserState (initParserOpts dflags) buf loc) of
PFailed pst ->
handleWarningsThrowErrors (getPsMessages pst)
POk pst rdr_module -> do
let (warns, errs) = getPsMessages pst
logDiagnostics (GhcPsMessage <$> warns)
liftIO $ putDumpFileMaybe logger Opt_D_dump_parsed "Parser"
FormatHaskell (ppr rdr_module)
liftIO $ putDumpFileMaybe logger Opt_D_dump_parsed_ast "Parser AST"
FormatHaskell (showAstData NoBlankSrcSpan
NoBlankEpAnnotations
rdr_module)
liftIO $ putDumpFileMaybe logger Opt_D_source_stats "Source Statistics"
FormatText (ppSourceStats False rdr_module)
when (not $ isEmptyMessages errs) $ throwErrors (GhcPsMessage <$> errs)
-- To get the list of extra source files, we take the list
-- that the parser gave us,
-- - eliminate files beginning with '<'. gcc likes to use
-- pseudo-filenames like "<built-in>" and "<command-line>"
-- - normalise them (eliminate differences between ./f and f)
-- - filter out the preprocessed source file
-- - filter out anything beginning with tmpdir
-- - remove duplicates
-- - filter out the .hs/.lhs source filename if we have one
--
let n_hspp = FilePath.normalise src_filename
TempDir tmp_dir = tmpDir dflags
srcs0 = nub $ filter (not . (tmp_dir `isPrefixOf`))
$ filter (not . (== n_hspp))
$ map FilePath.normalise
$ filter (not . isPrefixOf "<")
$ map unpackFS
$ srcfiles pst
srcs1 = case ml_hs_file (ms_location mod_summary) of
Just f -> filter (/= FilePath.normalise f) srcs0
Nothing -> srcs0
-- sometimes we see source files from earlier
-- preprocessing stages that cannot be found, so just
-- filter them out:
srcs2 <- liftIO $ filterM doesFileExist srcs1
let res = HsParsedModule {
hpm_module = rdr_module,
hpm_src_files = srcs2
}
-- apply parse transformation of plugins
let applyPluginAction p opts
= parsedResultAction p opts mod_summary
hsc_env <- getHscEnv
withPlugins (hsc_plugins hsc_env) applyPluginAction res
checkBidirectionFormatChars :: PsLoc -> StringBuffer -> Maybe (NonEmpty (PsLoc, Char, String))
checkBidirectionFormatChars start_loc sb
| containsBidirectionalFormatChar sb = Just $ go start_loc sb
| otherwise = Nothing
where
go :: PsLoc -> StringBuffer -> NonEmpty (PsLoc, Char, String)
go loc sb
| atEnd sb = panic "checkBidirectionFormatChars: no char found"
| otherwise = case nextChar sb of
(chr, sb)
| Just desc <- lookup chr bidirectionalFormatChars ->
(loc, chr, desc) :| go1 (advancePsLoc loc chr) sb
| otherwise -> go (advancePsLoc loc chr) sb
go1 :: PsLoc -> StringBuffer -> [(PsLoc, Char, String)]
go1 loc sb
| atEnd sb = []
| otherwise = case nextChar sb of
(chr, sb)
| Just desc <- lookup chr bidirectionalFormatChars ->
(loc, chr, desc) : go1 (advancePsLoc loc chr) sb
| otherwise -> go1 (advancePsLoc loc chr) sb
-- -----------------------------------------------------------------------------
-- | If the renamed source has been kept, extract it. Dump it if requested.
extract_renamed_stuff :: ModSummary -> TcGblEnv -> Hsc RenamedStuff
extract_renamed_stuff mod_summary tc_result = do
let rn_info = getRenamedStuff tc_result
dflags <- getDynFlags
logger <- getLogger
liftIO $ putDumpFileMaybe logger Opt_D_dump_rn_ast "Renamer"
FormatHaskell (showAstData NoBlankSrcSpan NoBlankEpAnnotations rn_info)
-- Create HIE files
when (gopt Opt_WriteHie dflags) $ do
-- I assume this fromJust is safe because `-fwrite-hie-file`
-- enables the option which keeps the renamed source.
hieFile <- mkHieFile mod_summary tc_result (fromJust rn_info)
let out_file = ml_hie_file $ ms_location mod_summary
liftIO $ writeHieFile out_file hieFile
liftIO $ putDumpFileMaybe logger Opt_D_dump_hie "HIE AST" FormatHaskell (ppr $ hie_asts hieFile)
-- Validate HIE files
when (gopt Opt_ValidateHie dflags) $ do
hs_env <- Hsc $ \e w -> return (e, w)
liftIO $ do
-- Validate Scopes
case validateScopes (hie_module hieFile) $ getAsts $ hie_asts hieFile of
[] -> putMsg logger $ text "Got valid scopes"
xs -> do
putMsg logger $ text "Got invalid scopes"
mapM_ (putMsg logger) xs
-- Roundtrip testing
file' <- readHieFile (hsc_NC hs_env) out_file
case diffFile hieFile (hie_file_result file') of
[] ->
putMsg logger $ text "Got no roundtrip errors"
xs -> do
putMsg logger $ text "Got roundtrip errors"
let logger' = updateLogFlags logger (log_set_dopt Opt_D_ppr_debug)
mapM_ (putMsg logger') xs
return rn_info
-- -----------------------------------------------------------------------------
-- | Rename and typecheck a module, additionally returning the renamed syntax
hscTypecheckRename :: HscEnv -> ModSummary -> HsParsedModule
-> IO (TcGblEnv, RenamedStuff)
hscTypecheckRename hsc_env mod_summary rdr_module = runHsc hsc_env $
hsc_typecheck True mod_summary (Just rdr_module)
-- | Do Typechecking without throwing SourceError exception with -Werror
hscTypecheckAndGetWarnings :: HscEnv -> ModSummary -> IO (FrontendResult, WarningMessages)
hscTypecheckAndGetWarnings hsc_env summary = runHsc' hsc_env $ do
case hscFrontendHook (hsc_hooks hsc_env) of
Nothing -> FrontendTypecheck . fst <$> hsc_typecheck False summary Nothing
Just h -> h summary
-- | A bunch of logic piled around @tcRnModule'@, concerning a) backpack
-- b) concerning dumping rename info and hie files. It would be nice to further
-- separate this stuff out, probably in conjunction better separating renaming
-- and type checking (#17781).
hsc_typecheck :: Bool -- ^ Keep renamed source?
-> ModSummary -> Maybe HsParsedModule
-> Hsc (TcGblEnv, RenamedStuff)
hsc_typecheck keep_rn mod_summary mb_rdr_module = do
hsc_env <- getHscEnv
let hsc_src = ms_hsc_src mod_summary
dflags = hsc_dflags hsc_env
home_unit = hsc_home_unit hsc_env
outer_mod = ms_mod mod_summary
mod_name = moduleName outer_mod
outer_mod' = mkHomeModule home_unit mod_name
inner_mod = homeModuleNameInstantiation home_unit mod_name
src_filename = ms_hspp_file mod_summary
real_loc = realSrcLocSpan $ mkRealSrcLoc (mkFastString src_filename) 1 1
keep_rn' = gopt Opt_WriteHie dflags || keep_rn
massert (isHomeModule home_unit outer_mod)
tc_result <- if hsc_src == HsigFile && not (isHoleModule inner_mod)
then ioMsgMaybe $ hoistTcRnMessage $ tcRnInstantiateSignature hsc_env outer_mod' real_loc
else
do hpm <- case mb_rdr_module of
Just hpm -> return hpm
Nothing -> hscParse' mod_summary
tc_result0 <- tcRnModule' mod_summary keep_rn' hpm
if hsc_src == HsigFile
then do (iface, _) <- liftIO $ hscSimpleIface hsc_env tc_result0 mod_summary
ioMsgMaybe $ hoistTcRnMessage $
tcRnMergeSignatures hsc_env hpm tc_result0 iface
else return tc_result0
-- TODO are we extracting anything when we merely instantiate a signature?
-- If not, try to move this into the "else" case above.
rn_info <- extract_renamed_stuff mod_summary tc_result
return (tc_result, rn_info)
-- wrapper around tcRnModule to handle safe haskell extras
tcRnModule' :: ModSummary -> Bool -> HsParsedModule
-> Hsc TcGblEnv
tcRnModule' sum save_rn_syntax mod = do
hsc_env <- getHscEnv
dflags <- getDynFlags
let diag_opts = initDiagOpts dflags
-- -Wmissing-safe-haskell-mode
when (not (safeHaskellModeEnabled dflags)
&& wopt Opt_WarnMissingSafeHaskellMode dflags) $
logDiagnostics $ singleMessage $
mkPlainMsgEnvelope diag_opts (getLoc (hpm_module mod)) $
GhcDriverMessage $ DriverMissingSafeHaskellMode (ms_mod sum)
tcg_res <- {-# SCC "Typecheck-Rename" #-}
ioMsgMaybe $ hoistTcRnMessage $
tcRnModule hsc_env sum
save_rn_syntax mod
-- See Note [Safe Haskell Overlapping Instances Implementation]
-- although this is used for more than just that failure case.
tcSafeOK <- liftIO $ readIORef (tcg_safe_infer tcg_res)
whyUnsafe <- liftIO $ readIORef (tcg_safe_infer_reasons tcg_res)
let allSafeOK = safeInferred dflags && tcSafeOK
-- end of the safe haskell line, how to respond to user?
if not (safeHaskellOn dflags)
|| (safeInferOn dflags && not allSafeOK)
-- if safe Haskell off or safe infer failed, mark unsafe
then markUnsafeInfer tcg_res whyUnsafe
-- module (could be) safe, throw warning if needed
else do
tcg_res' <- hscCheckSafeImports tcg_res
safe <- liftIO $ readIORef (tcg_safe_infer tcg_res')
when safe $
case wopt Opt_WarnSafe dflags of
True
| safeHaskell dflags == Sf_Safe -> return ()
| otherwise -> (logDiagnostics $ singleMessage $
mkPlainMsgEnvelope diag_opts (warnSafeOnLoc dflags) $
GhcDriverMessage $ DriverInferredSafeModule (tcg_mod tcg_res'))
False | safeHaskell dflags == Sf_Trustworthy &&
wopt Opt_WarnTrustworthySafe dflags ->
(logDiagnostics $ singleMessage $
mkPlainMsgEnvelope diag_opts (trustworthyOnLoc dflags) $
GhcDriverMessage $ DriverMarkedTrustworthyButInferredSafe (tcg_mod tcg_res'))
False -> return ()
return tcg_res'
-- | Convert a typechecked module to Core
hscDesugar :: HscEnv -> ModSummary -> TcGblEnv -> IO ModGuts
hscDesugar hsc_env mod_summary tc_result =
runHsc hsc_env $ hscDesugar' (ms_location mod_summary) tc_result
hscDesugar' :: ModLocation -> TcGblEnv -> Hsc ModGuts
hscDesugar' mod_location tc_result = do
hsc_env <- getHscEnv
ioMsgMaybe $ hoistDsMessage $
{-# SCC "deSugar" #-}
deSugar hsc_env mod_location tc_result
-- | Make a 'ModDetails' from the results of typechecking. Used when
-- typechecking only, as opposed to full compilation.
makeSimpleDetails :: Logger -> TcGblEnv -> IO ModDetails
makeSimpleDetails logger tc_result = mkBootModDetailsTc logger tc_result
{- **********************************************************************
%* *
The main compiler pipeline
%* *
%********************************************************************* -}
{-
--------------------------------
The compilation proper
--------------------------------
It's the task of the compilation proper to compile Haskell, hs-boot and core
files to either byte-code, hard-code (C, asm, LLVM, etc.) or to nothing at all
(the module is still parsed and type-checked. This feature is mostly used by
IDE's and the likes). Compilation can happen in either 'one-shot', 'batch',
'nothing', or 'interactive' mode. 'One-shot' mode targets hard-code, 'batch'
mode targets hard-code, 'nothing' mode targets nothing and 'interactive' mode
targets byte-code.
The modes are kept separate because of their different types and meanings:
* In 'one-shot' mode, we're only compiling a single file and can therefore
discard the new ModIface and ModDetails. This is also the reason it only
targets hard-code; compiling to byte-code or nothing doesn't make sense when
we discard the result.
* 'Batch' mode is like 'one-shot' except that we keep the resulting ModIface
and ModDetails. 'Batch' mode doesn't target byte-code since that require us to
return the newly compiled byte-code.
* 'Nothing' mode has exactly the same type as 'batch' mode but they're still
kept separate. This is because compiling to nothing is fairly special: We
don't output any interface files, we don't run the simplifier and we don't
generate any code.
* 'Interactive' mode is similar to 'batch' mode except that we return the
compiled byte-code together with the ModIface and ModDetails.
Trying to compile a hs-boot file to byte-code will result in a run-time error.
This is the only thing that isn't caught by the type-system.
-}
type Messager = HscEnv -> (Int,Int) -> RecompileRequired -> ModuleGraphNode -> IO ()
-- | Do the recompilation avoidance checks for both one-shot and --make modes
-- This function is the *only* place in the compiler where we decide whether to
-- recompile a module or not!
hscRecompStatus :: Maybe Messager
-> HscEnv
-> ModSummary
-> Maybe ModIface
-> Maybe Linkable
-> (Int,Int)
-> IO HscRecompStatus
hscRecompStatus
mHscMessage hsc_env mod_summary mb_old_iface old_linkable mod_index
= do
let
msg what = case mHscMessage of
Just hscMessage -> hscMessage hsc_env mod_index what (ModuleNode [] mod_summary)
Nothing -> return ()
-- First check to see if the interface file agrees with the
-- source file.
(recomp_iface_reqd, mb_checked_iface)
<- {-# SCC "checkOldIface" #-}
liftIO $ checkOldIface hsc_env mod_summary mb_old_iface
-- Check to see whether the expected build products already exist.
-- If they don't exists then we trigger recompilation.
let lcl_dflags = ms_hspp_opts mod_summary
(recomp_obj_reqd, mb_linkable) <-
case () of
-- No need for a linkable, we're good to go
_ | NoBackend <- backend lcl_dflags -> return (UpToDate, Nothing)
-- Interpreter can use either already loaded bytecode or loaded object code
| not (backendProducesObject (backend lcl_dflags)) -> do
res <- liftIO $ checkByteCode old_linkable
case res of
(_, Just{}) -> return res
_ -> liftIO $ checkObjects lcl_dflags old_linkable mod_summary
-- Need object files for making object files
| backendProducesObject (backend lcl_dflags) -> liftIO $ checkObjects lcl_dflags old_linkable mod_summary
| otherwise -> pprPanic "hscRecompStatus" (text $ show $ backend lcl_dflags)
let recomp_reqd = recomp_iface_reqd `mappend` recomp_obj_reqd
-- save the interface that comes back from checkOldIface.
-- In one-shot mode we don't have the old iface until this
-- point, when checkOldIface reads it from the disk.
let mb_old_hash = fmap (mi_iface_hash . mi_final_exts) mb_checked_iface
msg recomp_reqd
case mb_checked_iface of
Just iface | not (recompileRequired recomp_reqd) ->
return $ HscUpToDate iface mb_linkable
_ ->
return $ HscRecompNeeded mb_old_hash
-- | Check that the .o files produced by compilation are already up-to-date
-- or not.
checkObjects :: DynFlags -> Maybe Linkable -> ModSummary -> IO (RecompileRequired, Maybe Linkable)
checkObjects dflags mb_old_linkable summary = do
let
dt_enabled = gopt Opt_BuildDynamicToo dflags
this_mod = ms_mod summary
mb_obj_date = ms_obj_date summary
mb_dyn_obj_date = ms_dyn_obj_date summary
mb_if_date = ms_iface_date summary
obj_fn = ml_obj_file (ms_location summary)
-- dynamic-too *also* produces the dyn_o_file, so have to check
-- that's there, and if it's not, regenerate both .o and
-- .dyn_o
checkDynamicObj k = if dt_enabled
then case (>=) <$> mb_dyn_obj_date <*> mb_if_date of
Just True -> k
_ -> return (RecompBecause MissingDynObjectFile, Nothing)
-- Not in dynamic-too mode
else k
checkDynamicObj $
case (,) <$> mb_obj_date <*> mb_if_date of
Just (obj_date, if_date)
| obj_date >= if_date ->
case mb_old_linkable of
Just old_linkable
| isObjectLinkable old_linkable, linkableTime old_linkable == obj_date
-> return $ (UpToDate, Just old_linkable)
_ -> (UpToDate,) . Just <$> findObjectLinkable this_mod obj_fn obj_date
_ -> return (RecompBecause MissingObjectFile, Nothing)
-- | Check to see if we can reuse the old linkable, by this point we will
-- have just checked that the old interface matches up with the source hash, so
-- no need to check that again here
checkByteCode :: Maybe Linkable -> IO (RecompileRequired, Maybe Linkable)
checkByteCode mb_old_linkable =
case mb_old_linkable of
Just old_linkable
| not (isObjectLinkable old_linkable)
-> return $ (UpToDate, Just old_linkable)
_ -> return $ (RecompBecause MissingBytecode, Nothing)
--------------------------------------------------------------
-- Compilers
--------------------------------------------------------------
-- Knot tying! See Note [Knot-tying typecheckIface]
-- See Note [ModDetails and --make mode]
initModDetails :: HscEnv -> ModSummary -> ModIface -> IO ModDetails
initModDetails hsc_env mod_summary iface =
fixIO $ \details' -> do
let act hpt = addToHpt hpt (ms_mod_name mod_summary)
(HomeModInfo iface details' Nothing)
let hsc_env' = hscUpdateHPT act hsc_env
-- NB: This result is actually not that useful
-- in one-shot mode, since we're not going to do
-- any further typechecking. It's much more useful
-- in make mode, since this HMI will go into the HPT.
genModDetails hsc_env' iface
{-
Note [ModDetails and --make mode]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
An interface file consists of two parts
* The `ModIface` which ends up getting written to disk.
The `ModIface` is a completely acyclic tree, which can be serialised
and de-serialised completely straightforwardly. The `ModIface` is
also the structure that is finger-printed for recompilation control.
* The `ModDetails` which provides a more structured view that is suitable
for usage during compilation. The `ModDetails` is heavily cyclic:
An `Id` contains a `Type`, which mentions a `TyCon` that contains kind
that mentions other `TyCons`; the `Id` also includes an unfolding that
in turn mentions more `Id`s; And so on.
The `ModIface` can be created from the `ModDetails` and the `ModDetails` from
a `ModIface`.
During tidying, just before interfaces are written to disk,
the ModDetails is calculated and then converted into a ModIface (see GHC.Iface.Make.mkIface_).
Then when GHC needs to restart typechecking from a certain point it can read the
interface file, and regenerate the ModDetails from the ModIface (see GHC.IfaceToCore.typecheckIface).
The key part about the loading is that the ModDetails is regenerated lazily
from the ModIface, so that there's only a detailed in-memory representation
for declarations which are actually used from the interface. This mode is
also used when reading interface files from external packages.
In the old --make mode implementation, the interface was written after compiling a module
but the in-memory ModDetails which was used to compute the ModIface was retained.
The result was that --make mode used much more memory than `-c` mode, because a large amount of
information about a module would be kept in the ModDetails but never used.
The new idea is that even in `--make` mode, when there is an in-memory `ModDetails`
at hand, we re-create the `ModDetails` from the `ModIface`. Doing this means that
we only have to keep the `ModIface` decls in memory and then lazily load
detailed representations if needed. It turns out this makes a really big difference
to memory usage, halving maximum memory used in some cases.
See !5492 and #13586
-}
-- Runs the post-typechecking frontend (desugar and simplify). We want to
-- generate most of the interface as late as possible. This gets us up-to-date
-- and good unfoldings and other info in the interface file.
--
-- We might create a interface right away, in which case we also return the
-- updated HomeModInfo. But we might also need to run the backend first. In the
-- later case Status will be HscRecomp and we return a function from ModIface ->
-- HomeModInfo.
--
-- HscRecomp in turn will carry the information required to compute a interface
-- when passed the result of the code generator. So all this can and is done at
-- the call site of the backend code gen if it is run.
hscDesugarAndSimplify :: ModSummary
-> FrontendResult
-> Messages GhcMessage
-> Maybe Fingerprint
-> Hsc HscBackendAction
hscDesugarAndSimplify summary (FrontendTypecheck tc_result) tc_warnings mb_old_hash = do
hsc_env <- getHscEnv
dflags <- getDynFlags
logger <- getLogger
let bcknd = backend dflags
hsc_src = ms_hsc_src summary
diag_opts = initDiagOpts dflags
-- Desugar, if appropriate
--
-- We usually desugar even when we are not generating code, otherwise we
-- would miss errors thrown by the desugaring (see #10600). The only
-- exceptions are when the Module is Ghc.Prim or when it is not a
-- HsSrcFile Module.
mb_desugar <-
if ms_mod summary /= gHC_PRIM && hsc_src == HsSrcFile
then Just <$> hscDesugar' (ms_location summary) tc_result
else pure Nothing
-- Report the warnings from both typechecking and desugar together
w <- getDiagnostics
liftIO $ printOrThrowDiagnostics logger diag_opts (unionMessages tc_warnings w)
clearDiagnostics
-- Simplify, if appropriate, and (whether we simplified or not) generate an
-- interface file.
case mb_desugar of
-- Just cause we desugared doesn't mean we are generating code, see above.
Just desugared_guts | bcknd /= NoBackend -> do
plugins <- liftIO $ readIORef (tcg_th_coreplugins tc_result)
simplified_guts <- hscSimplify' plugins desugared_guts
(cg_guts, details) <- {-# SCC "CoreTidy" #-}
liftIO $ tidyProgram hsc_env simplified_guts
let !partial_iface =
{-# SCC "GHC.Driver.Main.mkPartialIface" #-}
-- This `force` saves 2M residency in test T10370
-- See Note [Avoiding space leaks in toIface*] for details.
force (mkPartialIface hsc_env details summary simplified_guts)
return HscRecomp { hscs_guts = cg_guts,
hscs_mod_location = ms_location summary,
hscs_partial_iface = partial_iface,
hscs_old_iface_hash = mb_old_hash
}
-- We are not generating code, so we can skip simplification
-- and generate a simple interface.
_ -> do
(iface, _details) <- liftIO $
hscSimpleIface hsc_env tc_result summary
liftIO $ hscMaybeWriteIface logger dflags True iface mb_old_hash (ms_location summary)
return $ HscUpdate iface
{-
Note [Writing interface files]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
We write one interface file per module and per compilation, except with
-dynamic-too where we write two interface files (non-dynamic and dynamic).
We can write two kinds of interfaces (see Note [Interface file stages] in
"GHC.Driver.Types"):
* simple interface: interface generated after the core pipeline
* full interface: simple interface completed with information from the
backend
Depending on the situation, we write one or the other (using
`hscMaybeWriteIface`). We must be careful with `-dynamic-too` because only the
backend is run twice, so if we write a simple interface we need to write both
the non-dynamic and the dynamic interfaces at the same time (with the same
contents).
Cases for which we generate simple interfaces:
* GHC.Driver.Main.hscDesugarAndSimplify: when a compilation does NOT require (re)compilation
of the hard code
* GHC.Driver.Pipeline.compileOne': when we run in One Shot mode and target
bytecode (if interface writing is forced).
* GHC.Driver.Backpack uses simple interfaces for indefinite units
(units with module holes). It writes them indirectly by forcing the
-fwrite-interface flag while setting backend to NoBackend.
Cases for which we generate full interfaces:
* GHC.Driver.Pipeline.runPhase: when we must be compiling to regular hard
code and/or require recompilation.
By default interface file names are derived from module file names by adding
suffixes. The interface file name can be overloaded with "-ohi", except when
`-dynamic-too` is used.
-}
-- | Write interface files
hscMaybeWriteIface
:: Logger
-> DynFlags
-> Bool
-- ^ Is this a simple interface generated after the core pipeline, or one
-- with information from the backend? See: Note [Writing interface files]
-> ModIface
-> Maybe Fingerprint
-- ^ The old interface hash, used to decide if we need to actually write the
-- new interface.
-> ModLocation
-> IO ()
hscMaybeWriteIface logger dflags is_simple iface old_iface mod_location = do
let force_write_interface = gopt Opt_WriteInterface dflags
write_interface = case backend dflags of
NoBackend -> False
Interpreter -> False
_ -> True
write_iface dflags' iface =
let !iface_name = if dynamicNow dflags' then ml_dyn_hi_file mod_location else ml_hi_file mod_location
profile = targetProfile dflags'
in
{-# SCC "writeIface" #-}
withTiming logger
(text "WriteIface"<+>brackets (text iface_name))
(const ())
(writeIface logger profile iface_name iface)
if (write_interface || force_write_interface) then do
-- FIXME: with -dynamic-too, "change" is only meaningful for the
-- non-dynamic interface, not for the dynamic one. We should have another
-- flag for the dynamic interface. In the meantime:
--
-- * when we write a single full interface, we check if we are
-- currently writing the dynamic interface due to -dynamic-too, in
-- which case we ignore "change".
--
-- * when we write two simple interfaces at once because of
-- dynamic-too, we use "change" both for the non-dynamic and the
-- dynamic interfaces. Hopefully both the dynamic and the non-dynamic
-- interfaces stay in sync...
--
let change = old_iface /= Just (mi_iface_hash (mi_final_exts iface))
let dt = dynamicTooState dflags
when (logHasDumpFlag logger Opt_D_dump_if_trace) $ putMsg logger $
hang (text "Writing interface(s):") 2 $ vcat
[ text "Kind:" <+> if is_simple then text "simple" else text "full"
, text "Hash change:" <+> ppr change
, text "DynamicToo state:" <+> text (show dt)
]
if is_simple
then when change $ do -- FIXME: see 'change' comment above
write_iface dflags iface
case dt of
DT_Dont -> return ()
DT_Dyn -> panic "Unexpected DT_Dyn state when writing simple interface"
DT_OK -> write_iface (setDynamicNow dflags) iface
else case dt of
DT_Dont | change -> write_iface dflags iface
DT_OK | change -> write_iface dflags iface
-- FIXME: see change' comment above
DT_Dyn -> write_iface dflags iface
_ -> return ()
when (gopt Opt_WriteHie dflags) $ do
-- This is slightly hacky. A hie file is considered to be up to date
-- if its modification time on disk is greater than or equal to that
-- of the .hi file (since we should always write a .hi file if we are
-- writing a .hie file). However, with the way this code is
-- structured at the moment, the .hie file is often written before
-- the .hi file; by touching the file here, we ensure that it is
-- correctly considered up-to-date.
--
-- The file should exist by the time we get here, but we check for
-- existence just in case, so that we don't accidentally create empty
-- .hie files.
let hie_file = ml_hie_file mod_location
whenM (doesFileExist hie_file) $
GHC.SysTools.touch logger dflags "Touching hie file" hie_file
else
-- See Note [Strictness in ModIface]
forceModIface iface
--------------------------------------------------------------
-- NoRecomp handlers
--------------------------------------------------------------
-- | genModDetails is used to initialise 'ModDetails' at the end of compilation.
-- This has two main effects:
-- 1. Increases memory usage by unloading a lot of the TypeEnv
-- 2. Globalising certain parts (DFunIds) in the TypeEnv (which used to be achieved using UpdateIdInfos)
-- For the second part to work, it's critical that we use 'initIfaceLoadModule' here rather than
-- 'initIfaceCheck' as 'initIfaceLoadModule' removes the module from the KnotVars, otherwise name lookups
-- succeed by hitting the old TypeEnv, which missing out the critical globalisation step for DFuns.
-- After the DFunIds are globalised, it's critical to overwrite the old TypeEnv with the new
-- more compact and more correct version. This reduces memory usage whilst compiling the rest of
-- the module loop.
genModDetails :: HscEnv -> ModIface -> IO ModDetails
genModDetails hsc_env old_iface
= do
-- CRITICAL: To use initIfaceLoadModule as that removes the current module from the KnotVars and
-- hence properly globalises DFunIds.
new_details <- {-# SCC "tcRnIface" #-}
initIfaceLoadModule hsc_env (mi_module old_iface) (typecheckIface old_iface)
case lookupKnotVars (hsc_type_env_vars hsc_env) (mi_module old_iface) of
Nothing -> return ()
Just te_var -> writeIORef te_var (md_types new_details)
dumpIfaceStats hsc_env
return new_details
--------------------------------------------------------------
-- Progress displayers.
--------------------------------------------------------------
oneShotMsg :: Logger -> RecompileRequired -> IO ()
oneShotMsg logger recomp =
case recomp of
UpToDate -> compilationProgressMsg logger $ text "compilation IS NOT required"
_ -> return ()
batchMsg :: Messager
batchMsg = batchMsgWith (\_ _ _ _ -> empty)
batchMultiMsg :: Messager
batchMultiMsg = batchMsgWith (\_ _ _ node -> brackets (ppr (moduleGraphNodeUnitId node)))
batchMsgWith :: (HscEnv -> (Int, Int) -> RecompileRequired -> ModuleGraphNode -> SDoc) -> Messager
batchMsgWith extra hsc_env_start mod_index recomp node =
case recomp of
MustCompile -> showMsg (text herald) empty
UpToDate
| logVerbAtLeast logger 2 -> showMsg (text "Skipping") empty
| otherwise -> return ()
RecompBecause reason -> showMsg (text herald)
(text " [" <> pprWithUnitState state (ppr reason) <> text "]")
where
herald = case node of
LinkNode {} -> "Linking"
InstantiationNode {} -> "Instantiating"
ModuleNode {} -> "Compiling"
hsc_env = hscSetActiveUnitId (moduleGraphNodeUnitId node) hsc_env_start
dflags = hsc_dflags hsc_env
logger = hsc_logger hsc_env
state = hsc_units hsc_env
showMsg msg reason =
compilationProgressMsg logger $
(showModuleIndex mod_index <>
msg <+> showModMsg dflags (recompileRequired recomp) node)
<> extra hsc_env mod_index recomp node
<> reason
--------------------------------------------------------------
-- Safe Haskell
--------------------------------------------------------------
-- Note [Safe Haskell Trust Check]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-- Safe Haskell checks that an import is trusted according to the following
-- rules for an import of module M that resides in Package P:
--
-- * If M is recorded as Safe and all its trust dependencies are OK
-- then M is considered safe.
-- * If M is recorded as Trustworthy and P is considered trusted and
-- all M's trust dependencies are OK then M is considered safe.
--
-- By trust dependencies we mean that the check is transitive. So if
-- a module M that is Safe relies on a module N that is trustworthy,
-- importing module M will first check (according to the second case)
-- that N is trusted before checking M is trusted.
--
-- This is a minimal description, so please refer to the user guide
-- for more details. The user guide is also considered the authoritative
-- source in this matter, not the comments or code.
-- Note [Safe Haskell Inference]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-- Safe Haskell does Safe inference on modules that don't have any specific
-- safe haskell mode flag. The basic approach to this is:
-- * When deciding if we need to do a Safe language check, treat
-- an unmarked module as having -XSafe mode specified.
-- * For checks, don't throw errors but return them to the caller.
-- * Caller checks if there are errors:
-- * For modules explicitly marked -XSafe, we throw the errors.
-- * For unmarked modules (inference mode), we drop the errors
-- and mark the module as being Unsafe.
--
-- It used to be that we only did safe inference on modules that had no Safe
-- Haskell flags, but now we perform safe inference on all modules as we want
-- to allow users to set the `-Wsafe`, `-Wunsafe` and
-- `-Wtrustworthy-safe` flags on Trustworthy and Unsafe modules so that a
-- user can ensure their assumptions are correct and see reasons for why a
-- module is safe or unsafe.
--
-- This is tricky as we must be careful when we should throw an error compared
-- to just warnings. For checking safe imports we manage it as two steps. First
-- we check any imports that are required to be safe, then we check all other
-- imports to see if we can infer them to be safe.
-- | Check that the safe imports of the module being compiled are valid.
-- If not we either issue a compilation error if the module is explicitly
-- using Safe Haskell, or mark the module as unsafe if we're in safe
-- inference mode.
hscCheckSafeImports :: TcGblEnv -> Hsc TcGblEnv
hscCheckSafeImports tcg_env = do
dflags <- getDynFlags
tcg_env' <- checkSafeImports tcg_env
checkRULES dflags tcg_env'
where
checkRULES dflags tcg_env' =
let diag_opts = initDiagOpts dflags
in case safeLanguageOn dflags of
True -> do
-- XSafe: we nuke user written RULES
logDiagnostics $ fmap GhcDriverMessage $ warns diag_opts (tcg_rules tcg_env')
return tcg_env' { tcg_rules = [] }
False
-- SafeInferred: user defined RULES, so not safe
| safeInferOn dflags && not (null $ tcg_rules tcg_env')
-> markUnsafeInfer tcg_env' $ warns diag_opts (tcg_rules tcg_env')
-- Trustworthy OR SafeInferred: with no RULES
| otherwise
-> return tcg_env'
warns diag_opts rules = mkMessages $ listToBag $ map (warnRules diag_opts) rules
warnRules :: DiagOpts -> LRuleDecl GhcTc -> MsgEnvelope DriverMessage
warnRules diag_opts (L loc rule) =
mkPlainMsgEnvelope diag_opts (locA loc) $ DriverUserDefinedRuleIgnored rule
-- | Validate that safe imported modules are actually safe. For modules in the
-- HomePackage (the package the module we are compiling in resides) this just
-- involves checking its trust type is 'Safe' or 'Trustworthy'. For modules
-- that reside in another package we also must check that the external package
-- is trusted. See the Note [Safe Haskell Trust Check] above for more
-- information.
--
-- The code for this is quite tricky as the whole algorithm is done in a few
-- distinct phases in different parts of the code base. See
-- 'GHC.Rename.Names.rnImportDecl' for where package trust dependencies for a
-- module are collected and unioned. Specifically see the Note [Tracking Trust
-- Transitively] in "GHC.Rename.Names" and the Note [Trust Own Package] in
-- "GHC.Rename.Names".
checkSafeImports :: TcGblEnv -> Hsc TcGblEnv
checkSafeImports tcg_env
= do
dflags <- getDynFlags
imps <- mapM condense imports'
let (safeImps, regImps) = partition (\(_,_,s) -> s) imps
-- We want to use the warning state specifically for detecting if safe
-- inference has failed, so store and clear any existing warnings.
oldErrs <- getDiagnostics
clearDiagnostics
-- Check safe imports are correct
safePkgs <- S.fromList <$> mapMaybeM checkSafe safeImps
safeErrs <- getDiagnostics
clearDiagnostics
-- Check non-safe imports are correct if inferring safety
-- See the Note [Safe Haskell Inference]
(infErrs, infPkgs) <- case (safeInferOn dflags) of
False -> return (emptyMessages, S.empty)
True -> do infPkgs <- S.fromList <$> mapMaybeM checkSafe regImps
infErrs <- getDiagnostics
clearDiagnostics
return (infErrs, infPkgs)
-- restore old errors
logDiagnostics oldErrs
case (isEmptyMessages safeErrs) of
-- Failed safe check
False -> liftIO . throwErrors $ safeErrs
-- Passed safe check
True -> do
let infPassed = isEmptyMessages infErrs
tcg_env' <- case (not infPassed) of
True -> markUnsafeInfer tcg_env infErrs
False -> return tcg_env
when (packageTrustOn dflags) $ checkPkgTrust pkgReqs
let newTrust = pkgTrustReqs dflags safePkgs infPkgs infPassed
return tcg_env' { tcg_imports = impInfo `plusImportAvails` newTrust }
where
impInfo = tcg_imports tcg_env -- ImportAvails
imports = imp_mods impInfo -- ImportedMods
imports1 = moduleEnvToList imports -- (Module, [ImportedBy])
imports' = map (fmap importedByUser) imports1 -- (Module, [ImportedModsVal])
pkgReqs = imp_trust_pkgs impInfo -- [Unit]
condense :: (Module, [ImportedModsVal]) -> Hsc (Module, SrcSpan, IsSafeImport)
condense (_, []) = panic "GHC.Driver.Main.condense: Pattern match failure!"
condense (m, x:xs) = do imv <- foldlM cond' x xs
return (m, imv_span imv, imv_is_safe imv)
-- ImportedModsVal = (ModuleName, Bool, SrcSpan, IsSafeImport)
cond' :: ImportedModsVal -> ImportedModsVal -> Hsc ImportedModsVal
cond' v1 v2
| imv_is_safe v1 /= imv_is_safe v2
= throwOneError $
mkPlainErrorMsgEnvelope (imv_span v1) $
GhcDriverMessage $ DriverMixedSafetyImport (imv_name v1)
| otherwise
= return v1
-- easier interface to work with
checkSafe :: (Module, SrcSpan, a) -> Hsc (Maybe UnitId)
checkSafe (m, l, _) = fst `fmap` hscCheckSafe' m l
-- what pkg's to add to our trust requirements
pkgTrustReqs :: DynFlags -> Set UnitId -> Set UnitId ->
Bool -> ImportAvails
pkgTrustReqs dflags req inf infPassed | safeInferOn dflags
&& not (safeHaskellModeEnabled dflags) && infPassed
= emptyImportAvails {
imp_trust_pkgs = req `S.union` inf
}
pkgTrustReqs dflags _ _ _ | safeHaskell dflags == Sf_Unsafe
= emptyImportAvails
pkgTrustReqs _ req _ _ = emptyImportAvails { imp_trust_pkgs = req }
-- | Check that a module is safe to import.
--
-- We return True to indicate the import is safe and False otherwise
-- although in the False case an exception may be thrown first.
hscCheckSafe :: HscEnv -> Module -> SrcSpan -> IO Bool
hscCheckSafe hsc_env m l = runHsc hsc_env $ do
dflags <- getDynFlags
pkgs <- snd `fmap` hscCheckSafe' m l
when (packageTrustOn dflags) $ checkPkgTrust pkgs
errs <- getDiagnostics
return $ isEmptyMessages errs
-- | Return if a module is trusted and the pkgs it depends on to be trusted.
hscGetSafe :: HscEnv -> Module -> SrcSpan -> IO (Bool, Set UnitId)
hscGetSafe hsc_env m l = runHsc hsc_env $ do
(self, pkgs) <- hscCheckSafe' m l
good <- isEmptyMessages `fmap` getDiagnostics
clearDiagnostics -- don't want them printed...
let pkgs' | Just p <- self = S.insert p pkgs
| otherwise = pkgs
return (good, pkgs')
-- | Is a module trusted? If not, throw or log errors depending on the type.
-- Return (regardless of trusted or not) if the trust type requires the modules
-- own package be trusted and a list of other packages required to be trusted
-- (these later ones haven't been checked) but the own package trust has been.
hscCheckSafe' :: Module -> SrcSpan
-> Hsc (Maybe UnitId, Set UnitId)
hscCheckSafe' m l = do
hsc_env <- getHscEnv
let home_unit = hsc_home_unit hsc_env
(tw, pkgs) <- isModSafe home_unit m l
case tw of
False -> return (Nothing, pkgs)
True | isHomeModule home_unit m -> return (Nothing, pkgs)
-- TODO: do we also have to check the trust of the instantiation?
-- Not necessary if that is reflected in dependencies
| otherwise -> return (Just $ toUnitId (moduleUnit m), pkgs)
where
isModSafe :: HomeUnit -> Module -> SrcSpan -> Hsc (Bool, Set UnitId)
isModSafe home_unit m l = do
hsc_env <- getHscEnv
dflags <- getDynFlags
iface <- lookup' m
let diag_opts = initDiagOpts dflags
case iface of
-- can't load iface to check trust!
Nothing -> throwOneError $
mkPlainErrorMsgEnvelope l $
GhcDriverMessage $ DriverCannotLoadInterfaceFile m
-- got iface, check trust
Just iface' ->
let trust = getSafeMode $ mi_trust iface'
trust_own_pkg = mi_trust_pkg iface'
-- check module is trusted
safeM = trust `elem` [Sf_Safe, Sf_SafeInferred, Sf_Trustworthy]
-- check package is trusted
safeP = packageTrusted dflags (hsc_units hsc_env) home_unit trust trust_own_pkg m
-- pkg trust reqs
pkgRs = dep_trusted_pkgs $ mi_deps iface'
-- warn if Safe module imports Safe-Inferred module.
warns = if wopt Opt_WarnInferredSafeImports dflags
&& safeLanguageOn dflags
&& trust == Sf_SafeInferred
then inferredImportWarn diag_opts
else emptyMessages
-- General errors we throw but Safe errors we log
errs = case (safeM, safeP) of
(True, True ) -> emptyMessages
(True, False) -> pkgTrustErr
(False, _ ) -> modTrustErr
in do
logDiagnostics warns
logDiagnostics errs
return (trust == Sf_Trustworthy, pkgRs)
where
state = hsc_units hsc_env
inferredImportWarn diag_opts = singleMessage
$ mkMsgEnvelope diag_opts l (pkgQual state)
$ GhcDriverMessage $ DriverInferredSafeImport m
pkgTrustErr = singleMessage
$ mkErrorMsgEnvelope l (pkgQual state)
$ GhcDriverMessage $ DriverCannotImportFromUntrustedPackage state m
modTrustErr = singleMessage
$ mkErrorMsgEnvelope l (pkgQual state)
$ GhcDriverMessage $ DriverCannotImportUnsafeModule m
-- | Check the package a module resides in is trusted. Safe compiled
-- modules are trusted without requiring that their package is trusted. For
-- trustworthy modules, modules in the home package are trusted but
-- otherwise we check the package trust flag.
packageTrusted :: DynFlags -> UnitState -> HomeUnit -> SafeHaskellMode -> Bool -> Module -> Bool
packageTrusted dflags unit_state home_unit safe_mode trust_own_pkg mod =
case safe_mode of
Sf_None -> False -- shouldn't hit these cases
Sf_Ignore -> False -- shouldn't hit these cases
Sf_Unsafe -> False -- prefer for completeness.
_ | not (packageTrustOn dflags) -> True
Sf_Safe | not trust_own_pkg -> True
Sf_SafeInferred | not trust_own_pkg -> True
_ | isHomeModule home_unit mod -> True
_ -> unitIsTrusted $ unsafeLookupUnit unit_state (moduleUnit m)
lookup' :: Module -> Hsc (Maybe ModIface)
lookup' m = do
hsc_env <- getHscEnv
hsc_eps <- liftIO $ hscEPS hsc_env
let pkgIfaceT = eps_PIT hsc_eps
hug = hsc_HUG hsc_env
iface = lookupIfaceByModule hug pkgIfaceT m
-- the 'lookupIfaceByModule' method will always fail when calling from GHCi
-- as the compiler hasn't filled in the various module tables
-- so we need to call 'getModuleInterface' to load from disk
case iface of
Just _ -> return iface
Nothing -> snd `fmap` (liftIO $ getModuleInterface hsc_env m)
-- | Check the list of packages are trusted.
checkPkgTrust :: Set UnitId -> Hsc ()
checkPkgTrust pkgs = do
hsc_env <- getHscEnv
let errors = S.foldr go emptyBag pkgs
state = hsc_units hsc_env
go pkg acc
| unitIsTrusted $ unsafeLookupUnitId state pkg
= acc
| otherwise
= (`consBag` acc)
$ mkErrorMsgEnvelope noSrcSpan (pkgQual state)
$ GhcDriverMessage
$ DriverPackageNotTrusted state pkg
if isEmptyBag errors
then return ()
else liftIO $ throwErrors $ mkMessages errors
-- | Set module to unsafe and (potentially) wipe trust information.
--
-- Make sure to call this method to set a module to inferred unsafe, it should
-- be a central and single failure method. We only wipe the trust information
-- when we aren't in a specific Safe Haskell mode.
--
-- While we only use this for recording that a module was inferred unsafe, we
-- may call it on modules using Trustworthy or Unsafe flags so as to allow
-- warning flags for safety to function correctly. See Note [Safe Haskell
-- Inference].
markUnsafeInfer :: Diagnostic e => TcGblEnv -> Messages e -> Hsc TcGblEnv
markUnsafeInfer tcg_env whyUnsafe = do
dflags <- getDynFlags
let reason = WarningWithFlag Opt_WarnUnsafe
let diag_opts = initDiagOpts dflags
when (diag_wopt Opt_WarnUnsafe diag_opts)
(logDiagnostics $ singleMessage $
mkPlainMsgEnvelope diag_opts (warnUnsafeOnLoc dflags) $
GhcDriverMessage $ DriverUnknownMessage $
mkPlainDiagnostic reason noHints $
whyUnsafe' dflags)
liftIO $ writeIORef (tcg_safe_infer tcg_env) False
liftIO $ writeIORef (tcg_safe_infer_reasons tcg_env) emptyMessages
-- NOTE: Only wipe trust when not in an explicitly safe haskell mode. Other
-- times inference may be on but we are in Trustworthy mode -- so we want
-- to record safe-inference failed but not wipe the trust dependencies.
case not (safeHaskellModeEnabled dflags) of
True -> return $ tcg_env { tcg_imports = wiped_trust }
False -> return tcg_env
where
wiped_trust = (tcg_imports tcg_env) { imp_trust_pkgs = S.empty }
pprMod = ppr $ moduleName $ tcg_mod tcg_env
whyUnsafe' df = vcat [ quotes pprMod <+> text "has been inferred as unsafe!"
, text "Reason:"
, nest 4 $ (vcat $ badFlags df) $+$
(vcat $ pprMsgEnvelopeBagWithLoc (getMessages whyUnsafe)) $+$
(vcat $ badInsts $ tcg_insts tcg_env)
]
badFlags df = concatMap (badFlag df) unsafeFlagsForInfer
badFlag df (str,loc,on,_)
| on df = [mkLocMessage MCOutput (loc df) $
text str <+> text "is not allowed in Safe Haskell"]
| otherwise = []
badInsts insts = concatMap badInst insts
checkOverlap (NoOverlap _) = False
checkOverlap _ = True
badInst ins | checkOverlap (overlapMode (is_flag ins))
= [mkLocMessage MCOutput (nameSrcSpan $ getName $ is_dfun ins) $
ppr (overlapMode $ is_flag ins) <+>
text "overlap mode isn't allowed in Safe Haskell"]
| otherwise = []
-- | Figure out the final correct safe haskell mode
hscGetSafeMode :: TcGblEnv -> Hsc SafeHaskellMode
hscGetSafeMode tcg_env = do
dflags <- getDynFlags
liftIO $ finalSafeMode dflags tcg_env
--------------------------------------------------------------
-- Simplifiers
--------------------------------------------------------------
-- | Run Core2Core simplifier. The list of String is a list of (Core) plugin
-- module names added via TH (cf 'addCorePlugin').
hscSimplify :: HscEnv -> [String] -> ModGuts -> IO ModGuts
hscSimplify hsc_env plugins modguts =
runHsc hsc_env $ hscSimplify' plugins modguts
-- | Run Core2Core simplifier. The list of String is a list of (Core) plugin
-- module names added via TH (cf 'addCorePlugin').
hscSimplify' :: [String] -> ModGuts -> Hsc ModGuts
hscSimplify' plugins ds_result = do
hsc_env <- getHscEnv
hsc_env_with_plugins <- if null plugins -- fast path
then return hsc_env
else liftIO $ flip initializePlugins (Just $ mg_mnwib ds_result)
$ hscUpdateFlags (\dflags -> foldr addPluginModuleName dflags plugins)
hsc_env
{-# SCC "Core2Core" #-}
liftIO $ core2core hsc_env_with_plugins ds_result
--------------------------------------------------------------
-- Interface generators
--------------------------------------------------------------
-- | Generate a striped down interface file, e.g. for boot files or when ghci
-- generates interface files. See Note [simpleTidyPgm - mkBootModDetailsTc]
hscSimpleIface :: HscEnv
-> TcGblEnv
-> ModSummary
-> IO (ModIface, ModDetails)
hscSimpleIface hsc_env tc_result summary
= runHsc hsc_env $ hscSimpleIface' tc_result summary
hscSimpleIface' :: TcGblEnv
-> ModSummary
-> Hsc (ModIface, ModDetails)
hscSimpleIface' tc_result summary = do
hsc_env <- getHscEnv
logger <- getLogger
details <- liftIO $ mkBootModDetailsTc logger tc_result
safe_mode <- hscGetSafeMode tc_result
new_iface
<- {-# SCC "MkFinalIface" #-}
liftIO $
mkIfaceTc hsc_env safe_mode details summary tc_result
-- And the answer is ...
liftIO $ dumpIfaceStats hsc_env
return (new_iface, details)
--------------------------------------------------------------
-- BackEnd combinators
--------------------------------------------------------------
-- | Compile to hard-code.
hscGenHardCode :: HscEnv -> CgGuts -> ModLocation -> FilePath
-> IO (FilePath, Maybe FilePath, [(ForeignSrcLang, FilePath)], CgInfos)
-- ^ @Just f@ <=> _stub.c is f
hscGenHardCode hsc_env cgguts location output_filename = do
let CgGuts{ -- This is the last use of the ModGuts in a compilation.
-- From now on, we just use the bits we need.
cg_module = this_mod,
cg_binds = core_binds,
cg_ccs = local_ccs,
cg_tycons = tycons,
cg_foreign = foreign_stubs0,
cg_foreign_files = foreign_files,
cg_dep_pkgs = dependencies,
cg_hpc_info = hpc_info } = cgguts
dflags = hsc_dflags hsc_env
logger = hsc_logger hsc_env
hooks = hsc_hooks hsc_env
tmpfs = hsc_tmpfs hsc_env
profile = targetProfile dflags
data_tycons = filter isDataTyCon tycons
-- cg_tycons includes newtypes, for the benefit of External Core,
-- but we don't generate any code for newtypes
-------------------
-- PREPARE FOR CODE GENERATION
-- Do saturation and convert to A-normal form
(prepd_binds) <- {-# SCC "CorePrep" #-}
corePrepPgm hsc_env this_mod location
core_binds data_tycons
----------------- Convert to STG ------------------
(stg_binds, denv, (caf_ccs, caf_cc_stacks))
<- {-# SCC "CoreToStg" #-}
withTiming logger
(text "CoreToStg"<+>brackets (ppr this_mod))
(\(a, b, (c,d)) -> a `seqList` b `seq` c `seqList` d `seqList` ())
(myCoreToStg logger dflags (hsc_IC hsc_env) False this_mod location prepd_binds)
let cost_centre_info =
(local_ccs ++ caf_ccs, caf_cc_stacks)
platform = targetPlatform dflags
prof_init
| sccProfilingEnabled dflags = profilingInitCode platform this_mod cost_centre_info
| otherwise = mempty
------------------ Code generation ------------------
-- The back-end is streamed: each top-level function goes
-- from Stg all the way to asm before dealing with the next
-- top-level function, so showPass isn't very useful here.
-- Hence we have one showPass for the whole backend, the
-- next showPass after this will be "Assembler".
withTiming logger
(text "CodeGen"<+>brackets (ppr this_mod))
(const ()) $ do
cmms <- {-# SCC "StgToCmm" #-}
doCodeGen hsc_env this_mod denv data_tycons
cost_centre_info
stg_binds hpc_info
------------------ Code output -----------------------
rawcmms0 <- {-# SCC "cmmToRawCmm" #-}
case cmmToRawCmmHook hooks of
Nothing -> cmmToRawCmm logger profile cmms
Just h -> h dflags (Just this_mod) cmms
let dump a = do
unless (null a) $
putDumpFileMaybe logger Opt_D_dump_cmm_raw "Raw Cmm" FormatCMM (pdoc platform a)
return a
rawcmms1 = Stream.mapM dump rawcmms0
let foreign_stubs st = foreign_stubs0 `appendStubC` prof_init
`appendStubC` cgIPEStub st
(output_filename, (_stub_h_exists, stub_c_exists), foreign_fps, cg_infos)
<- {-# SCC "codeOutput" #-}
codeOutput logger tmpfs dflags (hsc_units hsc_env) this_mod output_filename location
foreign_stubs foreign_files dependencies rawcmms1
return (output_filename, stub_c_exists, foreign_fps, cg_infos)
hscInteractive :: HscEnv
-> CgGuts
-> ModLocation
-> IO (Maybe FilePath, CompiledByteCode, [SptEntry])
hscInteractive hsc_env cgguts location = do
let dflags = hsc_dflags hsc_env
let logger = hsc_logger hsc_env
let tmpfs = hsc_tmpfs hsc_env
let CgGuts{ -- This is the last use of the ModGuts in a compilation.
-- From now on, we just use the bits we need.
cg_module = this_mod,
cg_binds = core_binds,
cg_tycons = tycons,
cg_foreign = foreign_stubs,
cg_modBreaks = mod_breaks,
cg_spt_entries = spt_entries } = cgguts
data_tycons = filter isDataTyCon tycons
-- cg_tycons includes newtypes, for the benefit of External Core,
-- but we don't generate any code for newtypes
-------------------
-- PREPARE FOR CODE GENERATION
-- Do saturation and convert to A-normal form
prepd_binds <- {-# SCC "CorePrep" #-}
corePrepPgm hsc_env this_mod location core_binds data_tycons
(stg_binds, _infotable_prov, _caf_ccs__caf_cc_stacks)
<- {-# SCC "CoreToStg" #-}
myCoreToStg logger dflags (hsc_IC hsc_env) True this_mod location prepd_binds
----------------- Generate byte code ------------------
comp_bc <- byteCodeGen hsc_env this_mod stg_binds data_tycons mod_breaks
------------------ Create f-x-dynamic C-side stuff -----
(_istub_h_exists, istub_c_exists)
<- outputForeignStubs logger tmpfs dflags (hsc_units hsc_env) this_mod location foreign_stubs
return (istub_c_exists, comp_bc, spt_entries)
------------------------------
hscCompileCmmFile :: HscEnv -> FilePath -> FilePath -> IO (Maybe FilePath)
hscCompileCmmFile hsc_env filename output_filename = runHsc hsc_env $ do
let dflags = hsc_dflags hsc_env
logger = hsc_logger hsc_env
hooks = hsc_hooks hsc_env
tmpfs = hsc_tmpfs hsc_env
profile = targetProfile dflags
home_unit = hsc_home_unit hsc_env
platform = targetPlatform dflags
do_info_table = gopt Opt_InfoTableMap dflags
-- Make up a module name to give the NCG. We can't pass bottom here
-- lest we reproduce #11784.
mod_name = mkModuleName $ "Cmm$" ++ FilePath.takeFileName filename
cmm_mod = mkHomeModule home_unit mod_name
(cmm, ents) <- ioMsgMaybe
$ do
(warns,errs,cmm) <- withTiming logger (text "ParseCmm"<+>brackets (text filename)) (\_ -> ())
$ parseCmmFile dflags cmm_mod home_unit filename
let msgs = warns `unionMessages` errs
return (GhcPsMessage <$> msgs, cmm)
liftIO $ do
putDumpFileMaybe logger Opt_D_dump_cmm_verbose_by_proc "Parsed Cmm" FormatCMM (pdoc platform cmm)
-- Compile decls in Cmm files one decl at a time, to avoid re-ordering
-- them in SRT analysis.
--
-- Re-ordering here causes breakage when booting with C backend because
-- in C we must declare before use, but SRT algorithm is free to
-- re-order [A, B] (B refers to A) when A is not CAFFY and return [B, A]
cmmgroup <-
concatMapM (\cmm -> snd <$> cmmPipeline hsc_env (emptySRT cmm_mod) [cmm]) cmm
unless (null cmmgroup) $
putDumpFileMaybe logger Opt_D_dump_cmm "Output Cmm"
FormatCMM (pdoc platform cmmgroup)
rawCmms <- case cmmToRawCmmHook hooks of
Nothing -> cmmToRawCmm logger profile (Stream.yield cmmgroup)
Just h -> h dflags Nothing (Stream.yield cmmgroup)
let foreign_stubs _ =
let ip_init = ipInitCode do_info_table platform cmm_mod ents
in NoStubs `appendStubC` ip_init
(_output_filename, (_stub_h_exists, stub_c_exists), _foreign_fps, _caf_infos)
<- codeOutput logger tmpfs dflags (hsc_units hsc_env) cmm_mod output_filename no_loc foreign_stubs [] S.empty
rawCmms
return stub_c_exists
where
no_loc = ModLocation{ ml_hs_file = Just filename,
ml_hi_file = panic "hscCompileCmmFile: no hi file",
ml_obj_file = panic "hscCompileCmmFile: no obj file",
ml_dyn_obj_file = panic "hscCompileCmmFile: no dyn obj file",
ml_dyn_hi_file = panic "hscCompileCmmFile: no dyn obj file",
ml_hie_file = panic "hscCompileCmmFile: no hie file"}
-------------------- Stuff for new code gen ---------------------
{-
Note [Forcing of stg_binds]
~~~~~~~~~~~~~~~~~~~~~~~~~~~
The two last steps in the STG pipeline are:
* Sorting the bindings in dependency order.
* Annotating them with free variables.
We want to make sure we do not keep references to unannotated STG bindings
alive, nor references to bindings which have already been compiled to Cmm.
We explicitly force the bindings to avoid this.
This reduces residency towards the end of the CodeGen phase significantly
(5-10%).
-}
doCodeGen :: HscEnv -> Module -> InfoTableProvMap -> [TyCon]
-> CollectedCCs
-> [CgStgTopBinding] -- ^ Bindings come already annotated with fvs
-> HpcInfo
-> IO (Stream IO CmmGroupSRTs CgInfos)
-- Note we produce a 'Stream' of CmmGroups, so that the
-- backend can be run incrementally. Otherwise it generates all
-- the C-- up front, which has a significant space cost.
doCodeGen hsc_env this_mod denv data_tycons
cost_centre_info stg_binds_w_fvs hpc_info = do
let dflags = hsc_dflags hsc_env
logger = hsc_logger hsc_env
hooks = hsc_hooks hsc_env
tmpfs = hsc_tmpfs hsc_env
platform = targetPlatform dflags
putDumpFileMaybe logger Opt_D_dump_stg_final "Final STG:" FormatSTG (pprGenStgTopBindings (initStgPprOpts dflags) stg_binds_w_fvs)
let stg_to_cmm dflags mod = case stgToCmmHook hooks of
Nothing -> StgToCmm.codeGen logger tmpfs (initStgToCmmConfig dflags mod)
Just h -> h (initStgToCmmConfig dflags mod)
let cmm_stream :: Stream IO CmmGroup ModuleLFInfos
-- See Note [Forcing of stg_binds]
cmm_stream = stg_binds_w_fvs `seqList` {-# SCC "StgToCmm" #-}
stg_to_cmm dflags this_mod denv data_tycons cost_centre_info stg_binds_w_fvs hpc_info
-- codegen consumes a stream of CmmGroup, and produces a new
-- stream of CmmGroup (not necessarily synchronised: one
-- CmmGroup on input may produce many CmmGroups on output due
-- to proc-point splitting).
let dump1 a = do
unless (null a) $
putDumpFileMaybe logger Opt_D_dump_cmm_from_stg
"Cmm produced by codegen" FormatCMM (pdoc platform a)
return a
ppr_stream1 = Stream.mapM dump1 cmm_stream
pipeline_stream :: Stream IO CmmGroupSRTs (NonCaffySet, ModuleLFInfos)
pipeline_stream = do
(non_cafs, lf_infos) <-
{-# SCC "cmmPipeline" #-}
Stream.mapAccumL_ (cmmPipeline hsc_env) (emptySRT this_mod) ppr_stream1
<&> first (srtMapNonCAFs . moduleSRTMap)
return (non_cafs, lf_infos)
dump2 a = do
unless (null a) $
putDumpFileMaybe logger Opt_D_dump_cmm "Output Cmm" FormatCMM (pdoc platform a)
return a
return $ Stream.mapM dump2 $ generateCgIPEStub hsc_env this_mod denv pipeline_stream
myCoreToStgExpr :: Logger -> DynFlags -> InteractiveContext
-> Bool
-> Module -> ModLocation -> CoreExpr
-> IO ( Id
, [CgStgTopBinding]
, InfoTableProvMap
, CollectedCCs )
myCoreToStgExpr logger dflags ictxt for_bytecode this_mod ml prepd_expr = do
{- Create a temporary binding (just because myCoreToStg needs a
binding for the stg2stg step) -}
let bco_tmp_id = mkSysLocal (fsLit "BCO_toplevel")
(mkPseudoUniqueE 0)
Many
(exprType prepd_expr)
(stg_binds, prov_map, collected_ccs) <-
myCoreToStg logger
dflags
ictxt
for_bytecode
this_mod
ml
[NonRec bco_tmp_id prepd_expr]
return (bco_tmp_id, stg_binds, prov_map, collected_ccs)
myCoreToStg :: Logger -> DynFlags -> InteractiveContext
-> Bool
-> Module -> ModLocation -> CoreProgram
-> IO ( [CgStgTopBinding] -- output program
, InfoTableProvMap
, CollectedCCs ) -- CAF cost centre info (declared and used)
myCoreToStg logger dflags ictxt for_bytecode this_mod ml prepd_binds = do
let (stg_binds, denv, cost_centre_info)
= {-# SCC "Core2Stg" #-}
coreToStg dflags this_mod ml prepd_binds
stg_binds_with_fvs
<- {-# SCC "Stg2Stg" #-}
stg2stg logger ictxt (initStgPipelineOpts dflags for_bytecode)
this_mod stg_binds
return (stg_binds_with_fvs, denv, cost_centre_info)
{- **********************************************************************
%* *
\subsection{Compiling a do-statement}
%* *
%********************************************************************* -}
{-
When the UnlinkedBCOExpr is linked you get an HValue of type *IO [HValue]* When
you run it you get a list of HValues that should be the same length as the list
of names; add them to the ClosureEnv.
A naked expression returns a singleton Name [it]. The stmt is lifted into the
IO monad as explained in Note [Interactively-bound Ids in GHCi] in GHC.Runtime.Context
-}
-- | Compile a stmt all the way to an HValue, but don't run it
--
-- We return Nothing to indicate an empty statement (or comment only), not a
-- parse error.
hscStmt :: HscEnv -> String -> IO (Maybe ([Id], ForeignHValue, FixityEnv))
hscStmt hsc_env stmt = hscStmtWithLocation hsc_env stmt "<interactive>" 1
-- | Compile a stmt all the way to an HValue, but don't run it
--
-- We return Nothing to indicate an empty statement (or comment only), not a
-- parse error.
hscStmtWithLocation :: HscEnv
-> String -- ^ The statement
-> String -- ^ The source
-> Int -- ^ Starting line
-> IO ( Maybe ([Id]
, ForeignHValue {- IO [HValue] -}
, FixityEnv))
hscStmtWithLocation hsc_env0 stmt source linenumber =
runInteractiveHsc hsc_env0 $ do
maybe_stmt <- hscParseStmtWithLocation source linenumber stmt
case maybe_stmt of
Nothing -> return Nothing
Just parsed_stmt -> do
hsc_env <- getHscEnv
liftIO $ hscParsedStmt hsc_env parsed_stmt
hscParsedStmt :: HscEnv
-> GhciLStmt GhcPs -- ^ The parsed statement
-> IO ( Maybe ([Id]
, ForeignHValue {- IO [HValue] -}
, FixityEnv))
hscParsedStmt hsc_env stmt = runInteractiveHsc hsc_env $ do
-- Rename and typecheck it
(ids, tc_expr, fix_env) <- ioMsgMaybe $ hoistTcRnMessage $ tcRnStmt hsc_env stmt
-- Desugar it
ds_expr <- ioMsgMaybe $ hoistDsMessage $ deSugarExpr hsc_env tc_expr
liftIO (lintInteractiveExpr (text "desugar expression") hsc_env ds_expr)
handleWarnings
-- Then code-gen, and link it
-- It's important NOT to have package 'interactive' as thisUnitId
-- for linking, else we try to link 'main' and can't find it.
-- Whereas the linker already knows to ignore 'interactive'
let src_span = srcLocSpan interactiveSrcLoc
hval <- liftIO $ hscCompileCoreExpr hsc_env (src_span, Nothing) ds_expr
return $ Just (ids, hval, fix_env)
-- | Compile a decls
hscDecls :: HscEnv
-> String -- ^ The statement
-> IO ([TyThing], InteractiveContext)
hscDecls hsc_env str = hscDeclsWithLocation hsc_env str "<interactive>" 1
hscParseModuleWithLocation :: HscEnv -> String -> Int -> String -> IO HsModule
hscParseModuleWithLocation hsc_env source line_num str = do
L _ mod <-
runInteractiveHsc hsc_env $
hscParseThingWithLocation source line_num parseModule str
return mod
hscParseDeclsWithLocation :: HscEnv -> String -> Int -> String -> IO [LHsDecl GhcPs]
hscParseDeclsWithLocation hsc_env source line_num str = do
HsModule { hsmodDecls = decls } <- hscParseModuleWithLocation hsc_env source line_num str
return decls
-- | Compile a decls
hscDeclsWithLocation :: HscEnv
-> String -- ^ The statement
-> String -- ^ The source
-> Int -- ^ Starting line
-> IO ([TyThing], InteractiveContext)
hscDeclsWithLocation hsc_env str source linenumber = do
L _ (HsModule{ hsmodDecls = decls }) <-
runInteractiveHsc hsc_env $
hscParseThingWithLocation source linenumber parseModule str
hscParsedDecls hsc_env decls
hscParsedDecls :: HscEnv -> [LHsDecl GhcPs] -> IO ([TyThing], InteractiveContext)
hscParsedDecls hsc_env decls = runInteractiveHsc hsc_env $ do
hsc_env <- getHscEnv
let interp = hscInterp hsc_env
{- Rename and typecheck it -}
tc_gblenv <- ioMsgMaybe $ hoistTcRnMessage $ tcRnDeclsi hsc_env decls
{- Grab the new instances -}
-- We grab the whole environment because of the overlapping that may have
-- been done. See the notes at the definition of InteractiveContext
-- (ic_instances) for more details.
let defaults = tcg_default tc_gblenv
{- Desugar it -}
-- We use a basically null location for iNTERACTIVE
let iNTERACTIVELoc = ModLocation{ ml_hs_file = Nothing,
ml_hi_file = panic "hsDeclsWithLocation:ml_hi_file",
ml_obj_file = panic "hsDeclsWithLocation:ml_obj_file",
ml_dyn_obj_file = panic "hsDeclsWithLocation:ml_dyn_obj_file",
ml_dyn_hi_file = panic "hsDeclsWithLocation:ml_dyn_hi_file",
ml_hie_file = panic "hsDeclsWithLocation:ml_hie_file" }
ds_result <- hscDesugar' iNTERACTIVELoc tc_gblenv
{- Simplify -}
simpl_mg <- liftIO $ do
plugins <- readIORef (tcg_th_coreplugins tc_gblenv)
hscSimplify hsc_env plugins ds_result
{- Tidy -}
(tidy_cg, mod_details) <- liftIO $ tidyProgram hsc_env simpl_mg
let !CgGuts{ cg_module = this_mod,
cg_binds = core_binds,
cg_tycons = tycons,
cg_modBreaks = mod_breaks } = tidy_cg
!ModDetails { md_insts = cls_insts
, md_fam_insts = fam_insts } = mod_details
-- Get the *tidied* cls_insts and fam_insts
data_tycons = filter isDataTyCon tycons
{- Prepare For Code Generation -}
-- Do saturation and convert to A-normal form
prepd_binds <- {-# SCC "CorePrep" #-}
liftIO $ corePrepPgm hsc_env this_mod iNTERACTIVELoc core_binds data_tycons
(stg_binds, _infotable_prov, _caf_ccs__caf_cc_stacks)
<- {-# SCC "CoreToStg" #-}
liftIO $ myCoreToStg (hsc_logger hsc_env)
(hsc_dflags hsc_env)
(hsc_IC hsc_env)
True
this_mod
iNTERACTIVELoc
prepd_binds
{- Generate byte code -}
cbc <- liftIO $ byteCodeGen hsc_env this_mod
stg_binds data_tycons mod_breaks
let src_span = srcLocSpan interactiveSrcLoc
_ <- liftIO $ loadDecls interp hsc_env (src_span, Nothing) cbc
{- Load static pointer table entries -}
liftIO $ hscAddSptEntries hsc_env Nothing (cg_spt_entries tidy_cg)
let tcs = filterOut isImplicitTyCon (mg_tcs simpl_mg)
patsyns = mg_patsyns simpl_mg
ext_ids = [ id | id <- bindersOfBinds core_binds
, isExternalName (idName id)
, not (isDFunId id || isImplicitId id) ]
-- We only need to keep around the external bindings
-- (as decided by GHC.Iface.Tidy), since those are the only ones
-- that might later be looked up by name. But we can exclude
-- - DFunIds, which are in 'cls_insts' (see Note [ic_tythings] in GHC.Runtime.Context
-- - Implicit Ids, which are implicit in tcs
-- c.f. GHC.Tc.Module.runTcInteractive, which reconstructs the TypeEnv
new_tythings = map AnId ext_ids ++ map ATyCon tcs ++ map (AConLike . PatSynCon) patsyns
ictxt = hsc_IC hsc_env
-- See Note [Fixity declarations in GHCi]
fix_env = tcg_fix_env tc_gblenv
new_ictxt = extendInteractiveContext ictxt new_tythings cls_insts
fam_insts defaults fix_env
return (new_tythings, new_ictxt)
-- | Load the given static-pointer table entries into the interpreter.
-- See Note [Grand plan for static forms] in "GHC.Iface.Tidy.StaticPtrTable".
hscAddSptEntries :: HscEnv -> Maybe ModuleNameWithIsBoot -> [SptEntry] -> IO ()
hscAddSptEntries hsc_env mnwib entries = do
let interp = hscInterp hsc_env
let add_spt_entry :: SptEntry -> IO ()
add_spt_entry (SptEntry i fpr) = do
val <- loadName interp hsc_env mnwib (idName i)
addSptEntry interp fpr val
mapM_ add_spt_entry entries
{-
Note [Fixity declarations in GHCi]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
To support fixity declarations on types defined within GHCi (as requested
in #10018) we record the fixity environment in InteractiveContext.
When we want to evaluate something GHC.Tc.Module.runTcInteractive pulls out this
fixity environment and uses it to initialize the global typechecker environment.
After the typechecker has finished its business, an updated fixity environment
(reflecting whatever fixity declarations were present in the statements we
passed it) will be returned from hscParsedStmt. This is passed to
updateFixityEnv, which will stuff it back into InteractiveContext, to be
used in evaluating the next statement.
-}
hscImport :: HscEnv -> String -> IO (ImportDecl GhcPs)
hscImport hsc_env str = runInteractiveHsc hsc_env $ do
(L _ (HsModule{hsmodImports=is})) <-
hscParseThing parseModule str
case is of
[L _ i] -> return i
_ -> liftIO $ throwOneError $
mkPlainErrorMsgEnvelope noSrcSpan $
GhcPsMessage $ PsUnknownMessage $ mkPlainError noHints $
text "parse error in import declaration"
-- | Typecheck an expression (but don't run it)
hscTcExpr :: HscEnv
-> TcRnExprMode
-> String -- ^ The expression
-> IO Type
hscTcExpr hsc_env0 mode expr = runInteractiveHsc hsc_env0 $ do
hsc_env <- getHscEnv
parsed_expr <- hscParseExpr expr
ioMsgMaybe $ hoistTcRnMessage $ tcRnExpr hsc_env mode parsed_expr
-- | Find the kind of a type, after generalisation
hscKcType
:: HscEnv
-> Bool -- ^ Normalise the type
-> String -- ^ The type as a string
-> IO (Type, Kind) -- ^ Resulting type (possibly normalised) and kind
hscKcType hsc_env0 normalise str = runInteractiveHsc hsc_env0 $ do
hsc_env <- getHscEnv
ty <- hscParseType str
ioMsgMaybe $ hoistTcRnMessage $ tcRnType hsc_env DefaultFlexi normalise ty
hscParseExpr :: String -> Hsc (LHsExpr GhcPs)
hscParseExpr expr = do
maybe_stmt <- hscParseStmt expr
case maybe_stmt of
Just (L _ (BodyStmt _ expr _ _)) -> return expr
_ -> throwOneError $
mkPlainErrorMsgEnvelope noSrcSpan $
GhcPsMessage $ PsUnknownMessage $ mkPlainError noHints $
text "not an expression:" <+> quotes (text expr)
hscParseStmt :: String -> Hsc (Maybe (GhciLStmt GhcPs))
hscParseStmt = hscParseThing parseStmt
hscParseStmtWithLocation :: String -> Int -> String
-> Hsc (Maybe (GhciLStmt GhcPs))
hscParseStmtWithLocation source linenumber stmt =
hscParseThingWithLocation source linenumber parseStmt stmt
hscParseType :: String -> Hsc (LHsType GhcPs)
hscParseType = hscParseThing parseType
hscParseIdentifier :: HscEnv -> String -> IO (LocatedN RdrName)
hscParseIdentifier hsc_env str =
runInteractiveHsc hsc_env $ hscParseThing parseIdentifier str
hscParseThing :: (Outputable thing, Data thing)
=> Lexer.P thing -> String -> Hsc thing
hscParseThing = hscParseThingWithLocation "<interactive>" 1
hscParseThingWithLocation :: (Outputable thing, Data thing) => String -> Int
-> Lexer.P thing -> String -> Hsc thing
hscParseThingWithLocation source linenumber parser str = do
dflags <- getDynFlags
logger <- getLogger
withTiming logger
(text "Parser [source]")
(const ()) $ {-# SCC "Parser" #-} do
let buf = stringToStringBuffer str
loc = mkRealSrcLoc (fsLit source) linenumber 1
case unP parser (initParserState (initParserOpts dflags) buf loc) of
PFailed pst ->
handleWarningsThrowErrors (getPsMessages pst)
POk pst thing -> do
logWarningsReportErrors (getPsMessages pst)
liftIO $ putDumpFileMaybe logger Opt_D_dump_parsed "Parser"
FormatHaskell (ppr thing)
liftIO $ putDumpFileMaybe logger Opt_D_dump_parsed_ast "Parser AST"
FormatHaskell (showAstData NoBlankSrcSpan NoBlankEpAnnotations thing)
return thing
{- **********************************************************************
%* *
Desugar, simplify, convert to bytecode, and link an expression
%* *
%********************************************************************* -}
hscCompileCoreExpr :: HscEnv -> (SrcSpan, Maybe ModuleNameWithIsBoot) -> CoreExpr -> IO ForeignHValue
hscCompileCoreExpr hsc_env loc expr =
case hscCompileCoreExprHook (hsc_hooks hsc_env) of
Nothing -> hscCompileCoreExpr' hsc_env loc expr
Just h -> h hsc_env loc expr
hscCompileCoreExpr' :: HscEnv -> (SrcSpan, Maybe ModuleNameWithIsBoot) -> CoreExpr -> IO ForeignHValue
hscCompileCoreExpr' hsc_env srcspan ds_expr
= do { {- Simplify it -}
-- Question: should we call SimpleOpt.simpleOptExpr here instead?
-- It is, well, simpler, and does less inlining etc.
simpl_expr <- simplifyExpr hsc_env ds_expr
{- Tidy it (temporary, until coreSat does cloning) -}
; let tidy_expr = tidyExpr emptyTidyEnv simpl_expr
{- Prepare for codegen -}
; prepd_expr <- corePrepExpr hsc_env tidy_expr
{- Lint if necessary -}
; lintInteractiveExpr (text "hscCompileExpr") hsc_env prepd_expr
; let iNTERACTIVELoc = ModLocation{ ml_hs_file = Nothing,
ml_hi_file = panic "hscCompileCoreExpr':ml_hi_file",
ml_obj_file = panic "hscCompileCoreExpr':ml_obj_file",
ml_dyn_obj_file = panic "hscCompileCoreExpr': ml_obj_file",
ml_dyn_hi_file = panic "hscCompileCoreExpr': ml_dyn_hi_file",
ml_hie_file = panic "hscCompileCoreExpr':ml_hie_file" }
; let ictxt = hsc_IC hsc_env
; (binding_id, stg_expr, _, _) <-
myCoreToStgExpr (hsc_logger hsc_env)
(hsc_dflags hsc_env)
ictxt
True
(icInteractiveModule ictxt)
iNTERACTIVELoc
prepd_expr
{- Convert to BCOs -}
; bcos <- byteCodeGen hsc_env
(icInteractiveModule ictxt)
stg_expr
[] Nothing
{- load it -}
; fv_hvs <- loadDecls (hscInterp hsc_env) hsc_env srcspan bcos
{- Get the HValue for the root -}
; return (expectJust "hscCompileCoreExpr'"
$ lookup (idName binding_id) fv_hvs) }
{- **********************************************************************
%* *
Statistics on reading interfaces
%* *
%********************************************************************* -}
dumpIfaceStats :: HscEnv -> IO ()
dumpIfaceStats hsc_env = do
eps <- hscEPS hsc_env
let
logger = hsc_logger hsc_env
dump_rn_stats = logHasDumpFlag logger Opt_D_dump_rn_stats
dump_if_trace = logHasDumpFlag logger Opt_D_dump_if_trace
when (dump_if_trace || dump_rn_stats) $
logDumpMsg logger "Interface statistics" (ifaceStats eps)
{- **********************************************************************
%* *
Progress Messages: Module i of n
%* *
%********************************************************************* -}
showModuleIndex :: (Int, Int) -> SDoc
showModuleIndex (i,n) = text "[" <> pad <> int i <> text " of " <> int n <> text "] "
where
-- compute the length of x > 0 in base 10
len x = ceiling (logBase 10 (fromIntegral x+1) :: Float)
pad = text (replicate (len n - len i) ' ') -- TODO: use GHC.Utils.Ppr.RStr
writeInterfaceOnlyMode :: DynFlags -> Bool
writeInterfaceOnlyMode dflags =
gopt Opt_WriteInterface dflags &&
NoBackend == backend dflags
|