{-# 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 GhciMonad where #include "HsVersions.h" import qualified GHC import GhcMonad hiding (liftIO) import Outputable hiding (printForUser, printForUserPartWay) import qualified Outputable import Panic hiding (showException) import Util import DynFlags import HscTypes import SrcLoc import Module import ObjLink import Linker import StaticFlags import qualified MonadUtils import Exception import Numeric import Data.Array import Data.Int ( Int64 ) import Data.IORef import System.CPUTime import System.Environment import System.IO import Control.Monad as Monad import GHC.Exts import System.Console.Haskeline (CompletionFunc, InputT) import qualified System.Console.Haskeline as Haskeline import Control.Monad.Trans as Trans ----------------------------------------------------------------------------- -- GHCi monad type Command = (String, String -> InputT GHCi Bool, CompletionFunc GHCi) data GHCiState = GHCiState { progname :: String, args :: [String], prompt :: String, editor :: String, stop :: String, options :: [GHCiOption], prelude :: GHC.ModuleName, 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. -- ":" at the GHCi prompt repeats the last command, so we -- remember is here: last_command :: Maybe Command, cmdqueue :: [String], remembered_ctx :: [CtxtCmd], -- we remember the :module commands between :loads, so that -- on a :reload we can replay them. See bugs #2049, -- \#1873, #1360. Previously we tried to remember modules that -- were supposed to be in the context but currently had errors, -- but this was complicated. Just replaying the :module commands -- seems to be the right thing. ghc_e :: Bool -- True if this is 'ghc -e' (or runghc) } data CtxtCmd -- In each case, the first [String] are the starred modules -- and the second are the unstarred ones = SetContext [String] [String] | AddModules [String] [String] | RemModules [String] [String] | Import String type TickArray = Array Int [(BreakIndex,SrcSpan)] data GHCiOption = ShowTiming -- show time/allocs after evaluation | ShowType -- show the type of expressions | RevertCAFs -- revert CAFs after every evaluation | Multiline -- use multiline commands 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 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 Monad GHCi where (GHCi m) >>= k = GHCi $ \s -> m s >>= \a -> unGHCi (k a) s return a = GHCi $ \_ -> return a instance Functor GHCi where fmap f m = m >>= return . f ghciHandleGhcException :: (GhcException -> GHCi a) -> GHCi a -> GHCi a ghciHandleGhcException = handleGhcException getGHCiState :: GHCi GHCiState getGHCiState = GHCi $ \r -> liftIO $ readIORef r setGHCiState :: GHCiState -> GHCi () setGHCiState s = GHCi $ \r -> liftIO $ writeIORef r s liftGhc :: Ghc a -> GHCi a liftGhc m = GHCi $ \_ -> m instance MonadUtils.MonadIO GHCi where liftIO = liftGhc . MonadUtils.liftIO instance Trans.MonadIO Ghc where liftIO = MonadUtils.liftIO instance GhcMonad GHCi where setSession s' = liftGhc $ setSession s' getSession = liftGhc $ getSession instance GhcMonad (InputT GHCi) where setSession = lift . setSession getSession = lift getSession instance MonadUtils.MonadIO (InputT GHCi) where liftIO = Trans.liftIO instance ExceptionMonad GHCi where gcatch m h = GHCi $ \r -> unGHCi m r `gcatch` (\e -> unGHCi (h e) r) gblock (GHCi m) = GHCi $ \r -> gblock (m r) gunblock (GHCi m) = GHCi $ \r -> gunblock (m 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 MonadIO GHCi where liftIO = MonadUtils.liftIO instance Haskeline.MonadException GHCi where catch = gcatch block = gblock unblock = gunblock -- XXX when Haskeline's MonadException changes, we can drop our -- deprecated block/unblock methods instance ExceptionMonad (InputT GHCi) where gcatch = Haskeline.catch gmask f = Haskeline.block (f Haskeline.unblock) -- slightly wrong gblock = Haskeline.block gunblock = Haskeline.unblock -- for convenience... getPrelude :: GHCi ModuleName getPrelude = getGHCiState >>= return . prelude getDynFlags :: GhcMonad m => m DynFlags getDynFlags = do GHC.getSessionDynFlags setDynFlags :: DynFlags -> GHCi [PackageId] setDynFlags dflags = do GHC.setSessionDynFlags dflags 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) }) printForUser :: GhcMonad m => SDoc -> m () printForUser doc = do unqual <- GHC.getPrintUnqual MonadUtils.liftIO $ Outputable.printForUser stdout unqual doc printForUserPartWay :: SDoc -> GHCi () printForUserPartWay doc = do unqual <- GHC.getPrintUnqual liftIO $ Outputable.printForUserPartWay stdout opt_PprUserLength unqual doc runStmt :: String -> GHC.SingleStep -> GHCi GHC.RunResult runStmt expr step = do st <- getGHCiState reifyGHCi $ \x -> withProgName (progname st) $ withArgs (args st) $ reflectGHCi x $ do GHC.handleSourceError (\e -> do GHC.printException e return GHC.RunFailed) $ do GHC.runStmtWithLocation (progname st) (line_number st) expr step resume :: (SrcSpan -> Bool) -> GHC.SingleStep -> GHCi GHC.RunResult resume canLogSpan step = do st <- getGHCiState reifyGHCi $ \x -> withProgName (progname st) $ withArgs (args st) $ reflectGHCi x $ do GHC.resume canLogSpan step -- -------------------------------------------------------------------------- -- timing & statistics timeIt :: InputT GHCi a -> InputT GHCi a timeIt action = do b <- lift $ isOptionSet ShowTiming if not b then action else do allocs1 <- liftIO $ getAllocations time1 <- liftIO $ getCPUTime a <- action allocs2 <- liftIO $ getAllocations time2 <- liftIO $ getCPUTime liftIO $ printTimes (fromIntegral (allocs2 - allocs1)) (time2 - time1) return a foreign import ccall unsafe "getAllocations" getAllocations :: IO Int64 -- defined in ghc/rts/Stats.c printTimes :: Integer -> Integer -> IO () printTimes allocs psecs = do let secs = (fromIntegral psecs / (10^(12::Integer))) :: Float secs_str = showFFloat (Just 2) secs putStrLn (showSDoc ( parens (text (secs_str "") <+> text "secs" <> comma <+> text (show allocs) <+> text "bytes"))) ----------------------------------------------------------------------------- -- reverting CAFs revertCAFs :: GHCi () revertCAFs = do liftIO rts_revertCAFs s <- getGHCiState when (not (ghc_e s)) $ liftIO 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 GLOBAL_VAR(stdin_ptr, error "no stdin_ptr", Ptr ()) GLOBAL_VAR(stdout_ptr, error "no stdout_ptr", Ptr ()) GLOBAL_VAR(stderr_ptr, error "no stderr_ptr", Ptr ()) -- After various attempts, I believe this is the least bad way to do -- what we want. We know look up the address of the static stdin, -- stdout, and stderr closures in the loaded base package, and each -- time we need to refer to them we cast the pointer to a Handle. -- This avoids any problems with the CAF having been reverted, because -- we'll always get the current value. -- -- The previous attempt that didn't work was to compile an expression -- like "hSetBuffering stdout NoBuffering" into an expression of type -- IO () and run this expression each time we needed it, but the -- problem is that evaluating the expression might cache the contents -- of the Handle rather than referring to it from its static address -- each time. There's no safe workaround for this. initInterpBuffering :: Ghc () initInterpBuffering = do -- make sure these are linked dflags <- GHC.getSessionDynFlags liftIO $ do initDynLinker dflags -- ToDo: we should really look up these names properly, but -- it's a fiddle and not all the bits are exposed via the GHC -- interface. mb_stdin_ptr <- ObjLink.lookupSymbol "base_GHCziIOziHandleziFD_stdin_closure" mb_stdout_ptr <- ObjLink.lookupSymbol "base_GHCziIOziHandleziFD_stdout_closure" mb_stderr_ptr <- ObjLink.lookupSymbol "base_GHCziIOziHandleziFD_stderr_closure" let f ref (Just ptr) = writeIORef ref ptr f _ Nothing = panic "interactiveUI:setBuffering2" zipWithM_ f [stdin_ptr,stdout_ptr,stderr_ptr] [mb_stdin_ptr,mb_stdout_ptr,mb_stderr_ptr] flushInterpBuffers :: GHCi () flushInterpBuffers = liftIO $ do getHandle stdout_ptr >>= hFlush getHandle stderr_ptr >>= hFlush turnOffBuffering :: IO () turnOffBuffering = do hdls <- mapM getHandle [stdin_ptr,stdout_ptr,stderr_ptr] mapM_ (\h -> hSetBuffering h NoBuffering) hdls getHandle :: IORef (Ptr ()) -> IO Handle getHandle ref = do (Ptr addr) <- readIORef ref case addrToHValue# addr of (# hval #) -> return (unsafeCoerce# hval)