{-# LANGUAGE CPP, FlexibleInstances #-} {-# OPTIONS_GHC -fno-cse -fno-warn-orphans #-} -- -fno-cse is needed for GLOBAL_VAR's to behave properly ----------------------------------------------------------------------------- -- -- Monadery code used in InteractiveUI -- -- (c) The GHC Team 2005-2006 -- ----------------------------------------------------------------------------- module Clash.GHCi.UI.Monad ( GHCi(..), startGHCi, GHCiState(..), setGHCiState, getGHCiState, modifyGHCiState, GHCiOption(..), isOptionSet, setOption, unsetOption, Command(..), CommandResult(..), cmdSuccess, PromptFunction, BreakLocation(..), TickArray, getDynFlags, runStmt, runDecls, runDecls', resume, recordBreak, revertCAFs, ActionStats(..), runAndPrintStats, runWithStats, printStats, printForUserNeverQualify, printForUserModInfo, printForUser, printForUserPartWay, prettyLocations, compileGHCiExpr, initInterpBuffering, turnOffBuffering, turnOffBuffering_, flushInterpBuffers, mkEvalWrapper ) where #include "HsVersions.h" import Clash.GHCi.UI.Info (ModInfo) import qualified GHC import GhcMonad hiding (liftIO) import Outputable hiding (printForUser, printForUserPartWay) import qualified Outputable import OccName import DynFlags import FastString import HscTypes import SrcLoc import Module import RdrName (mkOrig) import PrelNames (gHC_GHCI_HELPERS) import GHCi import GHCi.RemoteTypes import HsSyn (ImportDecl, GhcPs, GhciLStmt, LHsDecl) import HsUtils import Util import Exception import Numeric import Data.Array import Data.IORef import Data.Time import System.Environment import System.IO import Control.Monad import Prelude hiding ((<>)) import System.Console.Haskeline (CompletionFunc, InputT) import qualified System.Console.Haskeline as Haskeline import Control.Monad.Trans.Class import Control.Monad.IO.Class import Data.Map.Strict (Map) import qualified GHC.LanguageExtensions as LangExt ----------------------------------------------------------------------------- -- GHCi monad data GHCiState = GHCiState { progname :: String, args :: [String], evalWrapper :: ForeignHValue, -- ^ of type @IO a -> IO a@ prompt :: PromptFunction, prompt_cont :: PromptFunction, editor :: String, stop :: String, options :: [GHCiOption], line_number :: !Int, -- ^ input line break_ctr :: !Int, breaks :: ![(Int, BreakLocation)], tickarrays :: ModuleEnv TickArray, -- ^ 'tickarrays' caches the 'TickArray' for loaded modules, -- so that we don't rebuild it each time the user sets -- a breakpoint. ghci_commands :: [Command], -- ^ available ghci commands ghci_macros :: [Command], -- ^ user-defined macros last_command :: Maybe Command, -- ^ @:@ at the GHCi prompt repeats the last command, so we -- remember it here cmd_wrapper :: InputT GHCi CommandResult -> InputT GHCi (Maybe Bool), -- ^ The command wrapper is run for each command or statement. -- The 'Bool' value denotes whether the command is successful and -- 'Nothing' means to exit GHCi. cmdqueue :: [String], remembered_ctx :: [InteractiveImport], -- ^ The imports that the user has asked for, via import -- declarations and :module commands. This list is -- persistent over :reloads (but any imports for modules -- that are not loaded are temporarily ignored). After a -- :load, all the home-package imports are stripped from -- this list. -- -- See bugs #2049, #1873, #1360 transient_ctx :: [InteractiveImport], -- ^ An import added automatically after a :load, usually of -- the most recently compiled module. May be empty if -- there are no modules loaded. This list is replaced by -- :load, :reload, and :add. In between it may be modified -- by :module. extra_imports :: [ImportDecl GhcPs], -- ^ These are "always-on" imports, added to the -- context regardless of what other imports we have. -- This is useful for adding imports that are required -- by setGHCiMonad. Be careful adding things here: -- you can create ambiguities if these imports overlap -- with other things in scope. -- -- NB. although this is not currently used by GHCi itself, -- it was added to support other front-ends that are based -- on the GHCi code. Potentially we could also expose -- this functionality via GHCi commands. prelude_imports :: [ImportDecl GhcPs], -- ^ These imports are added to the context when -- -XImplicitPrelude is on and we don't have a *-module -- in the context. They can also be overridden by another -- import for the same module, e.g. -- "import Prelude hiding (map)" ghc_e :: Bool, -- ^ True if this is 'ghc -e' (or runghc) short_help :: String, -- ^ help text to display to a user long_help :: String, lastErrorLocations :: IORef [(FastString, Int)], mod_infos :: !(Map ModuleName ModInfo), flushStdHandles :: ForeignHValue, -- ^ @hFlush stdout; hFlush stderr@ in the interpreter noBuffering :: ForeignHValue -- ^ @hSetBuffering NoBuffering@ for stdin/stdout/stderr } type TickArray = Array Int [(GHC.BreakIndex,RealSrcSpan)] -- | A GHCi command data Command = Command { cmdName :: String -- ^ Name of GHCi command (e.g. "exit") , cmdAction :: String -> InputT GHCi Bool -- ^ The 'Bool' value denotes whether to exit GHCi , cmdHidden :: Bool -- ^ Commands which are excluded from default completion -- and @:help@ summary. This is usually set for commands not -- useful for interactive use but rather for IDEs. , cmdCompletionFunc :: CompletionFunc GHCi -- ^ 'CompletionFunc' for arguments } data CommandResult = CommandComplete { cmdInput :: String , cmdResult :: Either SomeException (Maybe Bool) , cmdStats :: ActionStats } | CommandIncomplete -- ^ Unterminated multiline command deriving Show cmdSuccess :: Haskeline.MonadException m => CommandResult -> m (Maybe Bool) cmdSuccess CommandComplete{ cmdResult = Left e } = liftIO $ throwIO e cmdSuccess CommandComplete{ cmdResult = Right r } = return r cmdSuccess CommandIncomplete = return $ Just True type PromptFunction = [String] -> Int -> GHCi SDoc data GHCiOption = ShowTiming -- show time/allocs after evaluation | ShowType -- show the type of expressions | RevertCAFs -- revert CAFs after every evaluation | Multiline -- use multiline commands | CollectInfo -- collect and cache information about -- modules after load deriving Eq data BreakLocation = BreakLocation { breakModule :: !GHC.Module , breakLoc :: !SrcSpan , breakTick :: {-# UNPACK #-} !Int , onBreakCmd :: String } instance Eq BreakLocation where loc1 == loc2 = breakModule loc1 == breakModule loc2 && breakTick loc1 == breakTick loc2 prettyLocations :: [(Int, BreakLocation)] -> SDoc prettyLocations [] = text "No active breakpoints." prettyLocations locs = vcat $ map (\(i, loc) -> brackets (int i) <+> ppr loc) $ reverse $ locs instance Outputable BreakLocation where ppr loc = (ppr $ breakModule loc) <+> ppr (breakLoc loc) <+> if null (onBreakCmd loc) then Outputable.empty else doubleQuotes (text (onBreakCmd loc)) recordBreak :: BreakLocation -> GHCi (Bool{- was already present -}, Int) recordBreak brkLoc = do st <- getGHCiState let oldActiveBreaks = breaks st -- don't store the same break point twice case [ nm | (nm, loc) <- oldActiveBreaks, loc == brkLoc ] of (nm:_) -> return (True, nm) [] -> do let oldCounter = break_ctr st newCounter = oldCounter + 1 setGHCiState $ st { break_ctr = newCounter, breaks = (oldCounter, brkLoc) : oldActiveBreaks } return (False, oldCounter) newtype GHCi a = GHCi { unGHCi :: IORef GHCiState -> Ghc a } reflectGHCi :: (Session, IORef GHCiState) -> GHCi a -> IO a reflectGHCi (s, gs) m = unGhc (unGHCi m gs) s reifyGHCi :: ((Session, IORef GHCiState) -> IO a) -> GHCi a reifyGHCi f = GHCi f' where -- f' :: IORef GHCiState -> Ghc a f' gs = reifyGhc (f'' gs) -- f'' :: IORef GHCiState -> Session -> IO a f'' gs s = f (s, gs) startGHCi :: GHCi a -> GHCiState -> Ghc a startGHCi g state = do ref <- liftIO $ newIORef state; unGHCi g ref instance Functor GHCi where fmap = liftM instance Applicative GHCi where pure a = GHCi $ \_ -> pure a (<*>) = ap instance Monad GHCi where (GHCi m) >>= k = GHCi $ \s -> m s >>= \a -> unGHCi (k a) s class HasGhciState m where getGHCiState :: m GHCiState setGHCiState :: GHCiState -> m () modifyGHCiState :: (GHCiState -> GHCiState) -> m () instance HasGhciState GHCi where getGHCiState = GHCi $ \r -> liftIO $ readIORef r setGHCiState s = GHCi $ \r -> liftIO $ writeIORef r s modifyGHCiState f = GHCi $ \r -> liftIO $ modifyIORef r f instance (MonadTrans t, Monad m, HasGhciState m) => HasGhciState (t m) where getGHCiState = lift getGHCiState setGHCiState = lift . setGHCiState modifyGHCiState = lift . modifyGHCiState liftGhc :: Ghc a -> GHCi a liftGhc m = GHCi $ \_ -> m instance MonadIO GHCi where liftIO = liftGhc . liftIO instance HasDynFlags GHCi where getDynFlags = getSessionDynFlags instance GhcMonad GHCi where setSession s' = liftGhc $ setSession s' getSession = liftGhc $ getSession instance HasDynFlags (InputT GHCi) where getDynFlags = lift getDynFlags instance GhcMonad (InputT GHCi) where setSession = lift . setSession getSession = lift getSession instance ExceptionMonad GHCi where gcatch m h = GHCi $ \r -> unGHCi m r `gcatch` (\e -> unGHCi (h e) r) gmask f = GHCi $ \s -> gmask $ \io_restore -> let g_restore (GHCi m) = GHCi $ \s' -> io_restore (m s') in unGHCi (f g_restore) s instance Haskeline.MonadException Ghc where controlIO f = Ghc $ \s -> Haskeline.controlIO $ \(Haskeline.RunIO run) -> let run' = Haskeline.RunIO (fmap (Ghc . const) . run . flip unGhc s) in fmap (flip unGhc s) $ f run' instance Haskeline.MonadException GHCi where controlIO f = GHCi $ \s -> Haskeline.controlIO $ \(Haskeline.RunIO run) -> let run' = Haskeline.RunIO (fmap (GHCi . const) . run . flip unGHCi s) in fmap (flip unGHCi s) $ f run' instance ExceptionMonad (InputT GHCi) where gcatch = Haskeline.catch gmask f = Haskeline.liftIOOp gmask (f . Haskeline.liftIOOp_) isOptionSet :: GHCiOption -> GHCi Bool isOptionSet opt = do st <- getGHCiState return (opt `elem` options st) setOption :: GHCiOption -> GHCi () setOption opt = do st <- getGHCiState setGHCiState (st{ options = opt : filter (/= opt) (options st) }) unsetOption :: GHCiOption -> GHCi () unsetOption opt = do st <- getGHCiState setGHCiState (st{ options = filter (/= opt) (options st) }) printForUserNeverQualify :: GhcMonad m => SDoc -> m () printForUserNeverQualify doc = do dflags <- getDynFlags liftIO $ Outputable.printForUser dflags stdout neverQualify doc printForUserModInfo :: GhcMonad m => GHC.ModuleInfo -> SDoc -> m () printForUserModInfo info doc = do dflags <- getDynFlags mUnqual <- GHC.mkPrintUnqualifiedForModule info unqual <- maybe GHC.getPrintUnqual return mUnqual liftIO $ Outputable.printForUser dflags stdout unqual doc printForUser :: GhcMonad m => SDoc -> m () printForUser doc = do unqual <- GHC.getPrintUnqual dflags <- getDynFlags liftIO $ Outputable.printForUser dflags stdout unqual doc printForUserPartWay :: SDoc -> GHCi () printForUserPartWay doc = do unqual <- GHC.getPrintUnqual dflags <- getDynFlags liftIO $ Outputable.printForUserPartWay dflags stdout (pprUserLength dflags) unqual doc -- | Run a single Haskell expression runStmt :: GhciLStmt GhcPs -> String -> GHC.SingleStep -> GHCi (Maybe GHC.ExecResult) runStmt stmt stmt_text step = do st <- getGHCiState GHC.handleSourceError (\e -> do GHC.printException e; return Nothing) $ do let opts = GHC.execOptions { GHC.execSourceFile = progname st , GHC.execLineNumber = line_number st , GHC.execSingleStep = step , GHC.execWrap = \fhv -> EvalApp (EvalThis (evalWrapper st)) (EvalThis fhv) } Just <$> GHC.execStmt' stmt stmt_text opts runDecls :: String -> GHCi (Maybe [GHC.Name]) runDecls decls = do st <- getGHCiState reifyGHCi $ \x -> withProgName (progname st) $ withArgs (args st) $ reflectGHCi x $ do GHC.handleSourceError (\e -> do GHC.printException e; return Nothing) $ do r <- GHC.runDeclsWithLocation (progname st) (line_number st) decls return (Just r) runDecls' :: [LHsDecl GhcPs] -> GHCi (Maybe [GHC.Name]) runDecls' decls = do st <- getGHCiState reifyGHCi $ \x -> withProgName (progname st) $ withArgs (args st) $ reflectGHCi x $ GHC.handleSourceError (\e -> do GHC.printException e; return Nothing) (Just <$> GHC.runParsedDecls decls) resume :: (SrcSpan -> Bool) -> GHC.SingleStep -> GHCi GHC.ExecResult resume canLogSpan step = do st <- getGHCiState reifyGHCi $ \x -> withProgName (progname st) $ withArgs (args st) $ reflectGHCi x $ do GHC.resumeExec canLogSpan step -- -------------------------------------------------------------------------- -- timing & statistics data ActionStats = ActionStats { actionAllocs :: Maybe Integer , actionElapsedTime :: Double } deriving Show runAndPrintStats :: (a -> Maybe Integer) -> InputT GHCi a -> InputT GHCi (ActionStats, Either SomeException a) runAndPrintStats getAllocs action = do result <- runWithStats getAllocs action case result of (stats, Right{}) -> do showTiming <- lift $ isOptionSet ShowTiming when showTiming $ do dflags <- getDynFlags liftIO $ printStats dflags stats _ -> return () return result runWithStats :: ExceptionMonad m => (a -> Maybe Integer) -> m a -> m (ActionStats, Either SomeException a) runWithStats getAllocs action = do t0 <- liftIO getCurrentTime result <- gtry action let allocs = either (const Nothing) getAllocs result t1 <- liftIO getCurrentTime let elapsedTime = realToFrac $ t1 `diffUTCTime` t0 return (ActionStats allocs elapsedTime, result) printStats :: DynFlags -> ActionStats -> IO () printStats dflags ActionStats{actionAllocs = mallocs, actionElapsedTime = secs} = do let secs_str = showFFloat (Just 2) secs putStrLn (showSDoc dflags ( parens (text (secs_str "") <+> text "secs" <> comma <+> case mallocs of Nothing -> empty Just allocs -> text (separateThousands allocs) <+> text "bytes"))) where separateThousands n = reverse . sep . reverse . show $ n where sep n' | n' `lengthAtMost` 3 = n' | otherwise = take 3 n' ++ "," ++ sep (drop 3 n') ----------------------------------------------------------------------------- -- reverting CAFs revertCAFs :: GHCi () revertCAFs = do liftIO rts_revertCAFs s <- getGHCiState when (not (ghc_e s)) turnOffBuffering -- Have to turn off buffering again, because we just -- reverted stdout, stderr & stdin to their defaults. foreign import ccall "revertCAFs" rts_revertCAFs :: IO () -- Make it "safe", just in case ----------------------------------------------------------------------------- -- To flush buffers for the *interpreted* computation we need -- to refer to *its* stdout/stderr handles -- | Compile "hFlush stdout; hFlush stderr" once, so we can use it repeatedly initInterpBuffering :: Ghc (ForeignHValue, ForeignHValue) initInterpBuffering = do let mkHelperExpr :: OccName -> Ghc ForeignHValue mkHelperExpr occ = GHC.compileParsedExprRemote $ GHC.nlHsVar $ RdrName.mkOrig gHC_GHCI_HELPERS occ nobuf <- mkHelperExpr $ mkVarOcc "disableBuffering" flush <- mkHelperExpr $ mkVarOcc "flushAll" return (nobuf, flush) -- | Invoke "hFlush stdout; hFlush stderr" in the interpreter flushInterpBuffers :: GHCi () flushInterpBuffers = do st <- getGHCiState hsc_env <- GHC.getSession liftIO $ evalIO hsc_env (flushStdHandles st) -- | Turn off buffering for stdin, stdout, and stderr in the interpreter turnOffBuffering :: GHCi () turnOffBuffering = do st <- getGHCiState turnOffBuffering_ (noBuffering st) turnOffBuffering_ :: GhcMonad m => ForeignHValue -> m () turnOffBuffering_ fhv = do hsc_env <- getSession liftIO $ evalIO hsc_env fhv mkEvalWrapper :: GhcMonad m => String -> [String] -> m ForeignHValue mkEvalWrapper progname args = runInternal $ GHC.compileParsedExprRemote $ evalWrapper `GHC.mkHsApp` nlHsString progname `GHC.mkHsApp` nlList (map nlHsString args) where nlHsString = nlHsLit . mkHsString evalWrapper = GHC.nlHsVar $ RdrName.mkOrig gHC_GHCI_HELPERS (mkVarOcc "evalWrapper") -- | Run a 'GhcMonad' action to compile an expression for internal usage. runInternal :: GhcMonad m => m a -> m a runInternal = withTempSession mkTempSession where mkTempSession hsc_env = hsc_env { hsc_dflags = (hsc_dflags hsc_env) -- RebindableSyntax can wreak havoc with GHCi in several ways -- (see #13385 and #14342 for examples), so we take care to disable it -- for the duration of running expressions that are internal to GHCi. `xopt_unset` LangExt.RebindableSyntax -- We heavily depend on -fimplicit-import-qualified to compile expr -- with fully qualified names without imports. `gopt_set` Opt_ImplicitImportQualified } compileGHCiExpr :: GhcMonad m => String -> m ForeignHValue compileGHCiExpr expr = runInternal $ GHC.compileExprRemote expr