\begin{code}
{-# OPTIONS_GHC -XNoImplicitPrelude #-}
+{-# OPTIONS_GHC -fno-warn-missing-signatures #-}
{-# OPTIONS_HADDOCK not-home #-}
-----------------------------------------------------------------------------
-- |
, throwTo -- :: ThreadId -> Exception -> IO ()
, par -- :: a -> b -> b
, pseq -- :: a -> b -> b
+ , runSparks
, yield -- :: IO ()
, labelThread -- :: ThreadId -> String -> IO ()
, threadWaitRead -- :: Int -> IO ()
, threadWaitWrite -- :: Int -> IO ()
- -- * MVars
- , MVar(..)
- , newMVar -- :: a -> IO (MVar a)
- , newEmptyMVar -- :: IO (MVar a)
- , takeMVar -- :: MVar a -> IO a
- , putMVar -- :: MVar a -> a -> IO ()
- , tryTakeMVar -- :: MVar a -> IO (Maybe a)
- , tryPutMVar -- :: MVar a -> a -> IO Bool
- , isEmptyMVar -- :: MVar a -> IO Bool
- , addMVarFinalizer -- :: MVar a -> IO () -> IO ()
-
-- * TVars
, STM(..)
, atomically -- :: STM a -> IO a
, newTVar -- :: a -> STM (TVar a)
, newTVarIO -- :: a -> STM (TVar a)
, readTVar -- :: TVar a -> STM a
+ , readTVarIO -- :: TVar a -> IO a
, writeTVar -- :: a -> TVar a -> STM ()
, unsafeIOToSTM -- :: IO a -> STM a
-- * Miscellaneous
+ , withMVar
#ifdef mingw32_HOST_OS
, asyncRead -- :: Int -> Int -> Int -> Ptr a -> IO (Int, Int)
, asyncWrite -- :: Int -> Int -> Int -> Ptr a -> IO (Int, Int)
#endif
#ifndef mingw32_HOST_OS
- , signalHandlerLock
+ , Signal, HandlerFun, setHandler, runHandlers
#endif
, ensureIOManagerIsRunning
+#ifndef mingw32_HOST_OS
+ , syncIOManager
+#endif
#ifdef mingw32_HOST_OS
, ConsoleEvent(..)
import Foreign
import Foreign.C
+#ifdef mingw32_HOST_OS
+import Data.Typeable
+#endif
+
+#ifndef mingw32_HOST_OS
+import Data.Dynamic
+#endif
+import Control.Monad
import Data.Maybe
import GHC.Base
-import {-# SOURCE #-} GHC.Handle
-import GHC.IOBase
+#ifndef mingw32_HOST_OS
+import GHC.Debug
+#endif
+import {-# SOURCE #-} GHC.IO.Handle ( hFlush )
+import {-# SOURCE #-} GHC.IO.Handle.FD ( stdout )
+import GHC.IO
+import GHC.IO.Exception
+import GHC.Exception
+import GHC.IORef
+import GHC.MVar
import GHC.Num ( Num(..) )
-import GHC.Real ( fromIntegral, div )
+import GHC.Real ( fromIntegral )
#ifndef mingw32_HOST_OS
-import GHC.Base ( Int(..) )
+import GHC.IOArray
+import GHC.Arr ( inRange )
+#endif
+#ifdef mingw32_HOST_OS
+import GHC.Real ( div )
+import GHC.Ptr
#endif
#ifdef mingw32_HOST_OS
import GHC.Read ( Read )
import GHC.Enum ( Enum )
#endif
-import GHC.Exception ( SomeException(..), throw )
import GHC.Pack ( packCString# )
-import GHC.Ptr ( Ptr(..), plusPtr, FunPtr(..) )
-import GHC.STRef
import GHC.Show ( Show(..), showString )
-import Data.Typeable
-import GHC.Err
infixr 0 `par`, `pseq`
\end{code}
GHC note: the new thread inherits the /blocked/ state of the parent
(see 'Control.Exception.block').
+
+The newly created thread has an exception handler that discards the
+exceptions 'BlockedIndefinitelyOnMVar', 'BlockedIndefinitelyOnSTM', and
+'ThreadKilled', and passes all other exceptions to the uncaught
+exception handler (see 'setUncaughtExceptionHandler').
-}
forkIO :: IO () -> IO ThreadId
forkIO action = IO $ \ s ->
- case (fork# action_plus s) of (# s1, id #) -> (# s1, ThreadId id #)
+ case (fork# action_plus s) of (# s1, tid #) -> (# s1, ThreadId tid #)
where
action_plus = catchException action childHandler
-}
forkOnIO :: Int -> IO () -> IO ThreadId
forkOnIO (I# cpu) action = IO $ \ s ->
- case (forkOn# cpu action_plus s) of (# s1, id #) -> (# s1, ThreadId id #)
+ case (forkOn# cpu action_plus s) of (# s1, tid #) -> (# s1, ThreadId tid #)
where
action_plus = catchException action childHandler
n <- peek n_capabilities
return (fromIntegral n)
+#if defined(mingw32_HOST_OS) && defined(__PIC__)
+foreign import ccall "_imp__n_capabilities" n_capabilities :: Ptr CInt
+#else
foreign import ccall "&n_capabilities" n_capabilities :: Ptr CInt
-
+#endif
childHandler :: SomeException -> IO ()
childHandler err = catchException (real_handler err) childHandler
real_handler se@(SomeException ex) =
-- ignore thread GC and killThread exceptions:
case cast ex of
- Just BlockedOnDeadMVar -> return ()
+ Just BlockedIndefinitelyOnMVar -> return ()
_ -> case cast ex of
- Just BlockedIndefinitely -> return ()
+ Just BlockedIndefinitelyOnSTM -> return ()
_ -> case cast ex of
Just ThreadKilled -> return ()
_ -> case cast ex of
Just StackOverflow -> reportStackOverflow
_ -> reportError se
-{- | 'killThread' terminates the given thread (GHC only).
-Any work already done by the thread isn\'t
-lost: the computation is suspended until required by another thread.
-The memory used by the thread will be garbage collected if it isn\'t
-referenced from anywhere. The 'killThread' function is defined in
-terms of 'throwTo':
+{- | 'killThread' raises the 'ThreadKilled' exception in the given
+thread (GHC only).
-> killThread tid = throwTo tid (AsyncException ThreadKilled)
+> killThread tid = throwTo tid ThreadKilled
-}
killThread :: ThreadId -> IO ()
-killThread tid = throwTo tid (toException ThreadKilled)
+killThread tid = throwTo tid ThreadKilled
{- | 'throwTo' raises an arbitrary exception in the target thread (GHC only).
can kill each other, it is guaranteed that only one of the threads
will get to kill the other.
+Whatever work the target thread was doing when the exception was
+raised is not lost: the computation is suspended until required by
+another thread.
+
If the target thread is currently making a foreign call, then the
exception will not be raised (and hence 'throwTo' will not return)
until the call has completed. This is the case regardless of whether
(<http://research.microsoft.com/~simonpj/Papers/asynch-exns.htm>).
In the paper, 'throwTo' is non-blocking; but the library implementation adopts
a more synchronous design in which 'throwTo' does not return until the exception
-is received by the target thread. The trade-off is discussed in Section 8 of the paper.
-Like any blocking operation, 'throwTo' is therefore interruptible (see Section 4.3 of
-the paper).
-
-There is currently no guarantee that the exception delivered by 'throwTo' will be
-delivered at the first possible opportunity. In particular, if a thread may
-unblock and then re-block exceptions (using 'unblock' and 'block') without receiving
-a pending 'throwTo'. This is arguably undesirable behaviour.
-
- -}
--- XXX This is duplicated in Control.{Old,}Exception
-throwTo :: ThreadId -> SomeException -> IO ()
-throwTo (ThreadId id) ex = IO $ \ s ->
- case (killThread# id ex s) of s1 -> (# s1, () #)
+is received by the target thread. The trade-off is discussed in Section 9 of the paper.
+Like any blocking operation, 'throwTo' is therefore interruptible (see Section 5.3 of
+the paper). Unlike other interruptible operations, however, 'throwTo'
+is /always/ interruptible, even if it does not actually block.
+
+There is no guarantee that the exception will be delivered promptly,
+although the runtime will endeavour to ensure that arbitrary
+delays don't occur. In GHC, an exception can only be raised when a
+thread reaches a /safe point/, where a safe point is where memory
+allocation occurs. Some loops do not perform any memory allocation
+inside the loop and therefore cannot be interrupted by a 'throwTo'.
+
+Blocked 'throwTo' is fair: if multiple threads are trying to throw an
+exception to the same target thread, they will succeed in FIFO order.
+
+ -}
+throwTo :: Exception e => ThreadId -> e -> IO ()
+throwTo (ThreadId tid) ex = IO $ \ s ->
+ case (killThread# tid (toException ex) s) of s1 -> (# s1, () #)
-- | Returns the 'ThreadId' of the calling thread (GHC only).
myThreadId :: IO ThreadId
myThreadId = IO $ \s ->
- case (myThreadId# s) of (# s1, id #) -> (# s1, ThreadId id #)
+ case (myThreadId# s) of (# s1, tid #) -> (# s1, ThreadId tid #)
-- |The 'yield' action allows (forces, in a co-operative multitasking
labelThread :: ThreadId -> String -> IO ()
labelThread (ThreadId t) str = IO $ \ s ->
- let ps = packCString# str
- adr = byteArrayContents# ps in
+ let !ps = packCString# str
+ !adr = byteArrayContents# ps in
case (labelThread# t adr s) of s1 -> (# s1, () #)
-- Nota Bene: 'pseq' used to be 'seq'
par :: a -> b -> b
par x y = case (par# x) of { _ -> lazy y }
+-- | Internal function used by the RTS to run sparks.
+runSparks :: IO ()
+runSparks = IO loop
+ where loop s = case getSpark# s of
+ (# s', n, p #) ->
+ if n ==# 0# then (# s', () #)
+ else p `seq` loop s'
data BlockReason
= BlockedOnMVar
thenSTM :: STM a -> STM b -> STM b
thenSTM (STM m) k = STM ( \s ->
case m s of
- (# new_s, a #) -> unSTM k new_s
+ (# new_s, _ #) -> unSTM k new_s
)
returnSTM :: a -> STM a
returnSTM x = STM (\s -> (# s, x #))
+instance MonadPlus STM where
+ mzero = retry
+ mplus = orElse
+
-- | Unsafely performs IO in the STM monad. Beware: this is a highly
-- dangerous thing to do.
--
-- of those points then the transaction violating it is aborted
-- and the exception raised by the invariant is propagated.
alwaysSucceeds :: STM a -> STM ()
-alwaysSucceeds i = do ( do i ; retry ) `orElse` ( return () )
+alwaysSucceeds i = do ( i >> retry ) `orElse` ( return () )
checkInv i
-- | always is a variant of alwaysSucceeds in which the invariant is
case newTVar# val s1# of
(# s2#, tvar# #) -> (# s2#, TVar tvar# #)
+-- |Return the current value stored in a TVar.
+-- This is equivalent to
+--
+-- > readTVarIO = atomically . readTVar
+--
+-- but works much faster, because it doesn't perform a complete
+-- transaction, it just reads the current value of the 'TVar'.
+readTVarIO :: TVar a -> IO a
+readTVarIO (TVar tvar#) = IO $ \s# -> readTVarIO# tvar# s#
+
-- |Return the current value stored in a TVar
readTVar :: TVar a -> STM a
readTVar (TVar tvar#) = STM $ \s# -> readTVar# tvar# s#
\end{code}
-%************************************************************************
-%* *
-\subsection[mvars]{M-Structures}
-%* *
-%************************************************************************
-
-M-Vars are rendezvous points for concurrent threads. They begin
-empty, and any attempt to read an empty M-Var blocks. When an M-Var
-is written, a single blocked thread may be freed. Reading an M-Var
-toggles its state from full back to empty. Therefore, any value
-written to an M-Var may only be read once. Multiple reads and writes
-are allowed, but there must be at least one read between any two
-writes.
+MVar utilities
\begin{code}
---Defined in IOBase to avoid cycle: data MVar a = MVar (SynchVar# RealWorld a)
-
--- |Create an 'MVar' which is initially empty.
-newEmptyMVar :: IO (MVar a)
-newEmptyMVar = IO $ \ s# ->
- case newMVar# s# of
- (# s2#, svar# #) -> (# s2#, MVar svar# #)
-
--- |Create an 'MVar' which contains the supplied value.
-newMVar :: a -> IO (MVar a)
-newMVar value =
- newEmptyMVar >>= \ mvar ->
- putMVar mvar value >>
- return mvar
-
--- |Return the contents of the 'MVar'. If the 'MVar' is currently
--- empty, 'takeMVar' will wait until it is full. After a 'takeMVar',
--- the 'MVar' is left empty.
---
--- There are two further important properties of 'takeMVar':
---
--- * 'takeMVar' is single-wakeup. That is, if there are multiple
--- threads blocked in 'takeMVar', and the 'MVar' becomes full,
--- only one thread will be woken up. The runtime guarantees that
--- the woken thread completes its 'takeMVar' operation.
---
--- * When multiple threads are blocked on an 'MVar', they are
--- woken up in FIFO order. This is useful for providing
--- fairness properties of abstractions built using 'MVar's.
---
-takeMVar :: MVar a -> IO a
-takeMVar (MVar mvar#) = IO $ \ s# -> takeMVar# mvar# s#
-
--- |Put a value into an 'MVar'. If the 'MVar' is currently full,
--- 'putMVar' will wait until it becomes empty.
---
--- There are two further important properties of 'putMVar':
---
--- * 'putMVar' is single-wakeup. That is, if there are multiple
--- threads blocked in 'putMVar', and the 'MVar' becomes empty,
--- only one thread will be woken up. The runtime guarantees that
--- the woken thread completes its 'putMVar' operation.
---
--- * When multiple threads are blocked on an 'MVar', they are
--- woken up in FIFO order. This is useful for providing
--- fairness properties of abstractions built using 'MVar's.
---
-putMVar :: MVar a -> a -> IO ()
-putMVar (MVar mvar#) x = IO $ \ s# ->
- case putMVar# mvar# x s# of
- s2# -> (# s2#, () #)
-
--- |A non-blocking version of 'takeMVar'. The 'tryTakeMVar' function
--- returns immediately, with 'Nothing' if the 'MVar' was empty, or
--- @'Just' a@ if the 'MVar' was full with contents @a@. After 'tryTakeMVar',
--- the 'MVar' is left empty.
-tryTakeMVar :: MVar a -> IO (Maybe a)
-tryTakeMVar (MVar m) = IO $ \ s ->
- case tryTakeMVar# m s of
- (# s, 0#, _ #) -> (# s, Nothing #) -- MVar is empty
- (# s, _, a #) -> (# s, Just a #) -- MVar is full
-
--- |A non-blocking version of 'putMVar'. The 'tryPutMVar' function
--- attempts to put the value @a@ into the 'MVar', returning 'True' if
--- it was successful, or 'False' otherwise.
-tryPutMVar :: MVar a -> a -> IO Bool
-tryPutMVar (MVar mvar#) x = IO $ \ s# ->
- case tryPutMVar# mvar# x s# of
- (# s, 0# #) -> (# s, False #)
- (# s, _ #) -> (# s, True #)
-
--- |Check whether a given 'MVar' is empty.
---
--- Notice that the boolean value returned is just a snapshot of
--- the state of the MVar. By the time you get to react on its result,
--- the MVar may have been filled (or emptied) - so be extremely
--- careful when using this operation. Use 'tryTakeMVar' instead if possible.
-isEmptyMVar :: MVar a -> IO Bool
-isEmptyMVar (MVar mv#) = IO $ \ s# ->
- case isEmptyMVar# mv# s# of
- (# s2#, flg #) -> (# s2#, not (flg ==# 0#) #)
-
--- |Add a finalizer to an 'MVar' (GHC only). See "Foreign.ForeignPtr" and
--- "System.Mem.Weak" for more about finalizers.
-addMVarFinalizer :: MVar a -> IO () -> IO ()
-addMVarFinalizer (MVar m) finalizer =
- IO $ \s -> case mkWeak# m () finalizer s of { (# s1, w #) -> (# s1, () #) }
-
withMVar :: MVar a -> (a -> IO b) -> IO b
withMVar m io =
block $ do
(\e -> do putMVar m a; throw e)
putMVar m a
return b
-\end{code}
+modifyMVar_ :: MVar a -> (a -> IO a) -> IO ()
+modifyMVar_ m io =
+ block $ do
+ a <- takeMVar m
+ a' <- catchAny (unblock (io a))
+ (\e -> do putMVar m a; throw e)
+ putMVar m a'
+ return ()
+\end{code}
%************************************************************************
%* *
asyncRead :: Int -> Int -> Int -> Ptr a -> IO (Int, Int)
asyncRead (I# fd) (I# isSock) (I# len) (Ptr buf) =
IO $ \s -> case asyncRead# fd isSock len buf s of
- (# s, len#, err# #) -> (# s, (I# len#, I# err#) #)
+ (# s', len#, err# #) -> (# s', (I# len#, I# err#) #)
asyncWrite :: Int -> Int -> Int -> Ptr a -> IO (Int, Int)
asyncWrite (I# fd) (I# isSock) (I# len) (Ptr buf) =
IO $ \s -> case asyncWrite# fd isSock len buf s of
- (# s, len#, err# #) -> (# s, (I# len#, I# err#) #)
+ (# s', len#, err# #) -> (# s', (I# len#, I# err#) #)
asyncDoProc :: FunPtr (Ptr a -> IO Int) -> Ptr a -> IO Int
asyncDoProc (FunPtr proc) (Ptr param) =
-- the 'length' value is ignored; simplifies implementation of
-- the async*# primops to have them all return the same result.
IO $ \s -> case asyncDoProc# proc param s of
- (# s, len#, err# #) -> (# s, I# err# #)
+ (# s', _len#, err# #) -> (# s', I# err# #)
-- to aid the use of these primops by the IO Handle implementation,
-- provide the following convenience funs:
#endif
| otherwise = IO $ \s ->
case fromIntegral fd of { I# fd# ->
- case waitRead# fd# s of { s -> (# s, () #)
+ case waitRead# fd# s of { s' -> (# s', () #)
}}
-- | Block the current thread until data can be written to the
#endif
| otherwise = IO $ \s ->
case fromIntegral fd of { I# fd# ->
- case waitWrite# fd# s of { s -> (# s, () #)
+ case waitWrite# fd# s of { s' -> (# s', () #)
}}
-- | Suspends the current thread for a given number of microseconds
| threaded = waitForDelayEvent time
| otherwise = IO $ \s ->
case fromIntegral time of { I# time# ->
- case delay# time# s of { s -> (# s, () #)
+ case delay# time# s of { s' -> (# s', () #)
}}
-- around the scheduler loop. Furthermore, the scheduler can be simplified
-- by not having to check for completed IO requests.
--- Issues, possible problems:
---
--- - we might want bound threads to just do the blocking
--- operation rather than communicating with the IO manager
--- thread. This would prevent simgle-threaded programs which do
--- IO from requiring multiple OS threads. However, it would also
--- prevent bound threads waiting on IO from being killed or sent
--- exceptions.
---
--- - Apprently exec() doesn't work on Linux in a multithreaded program.
--- I couldn't repeat this.
---
--- - How do we handle signal delivery in the multithreaded RTS?
---
--- - forkProcess will kill the IO manager thread. Let's just
--- hope we don't need to do any blocking IO between fork & exec.
-
#ifndef mingw32_HOST_OS
data IOReq
= Read {-# UNPACK #-} !Fd {-# UNPACK #-} !(MVar ())
| DelaySTM {-# UNPACK #-} !USecs {-# UNPACK #-} !(TVar Bool)
#ifndef mingw32_HOST_OS
+{-# NOINLINE pendingEvents #-}
pendingEvents :: IORef [IOReq]
+pendingEvents = unsafePerformIO $ do
+ m <- newIORef []
+ sharedCAF m getOrSetGHCConcPendingEventsStore
+
+foreign import ccall unsafe "getOrSetGHCConcPendingEventsStore"
+ getOrSetGHCConcPendingEventsStore :: Ptr a -> IO (Ptr a)
#endif
-pendingDelays :: IORef [DelayReq]
- -- could use a strict list or array here
-{-# NOINLINE pendingEvents #-}
+
{-# NOINLINE pendingDelays #-}
-(pendingEvents,pendingDelays) = unsafePerformIO $ do
- startIOManagerThread
- reqs <- newIORef []
- dels <- newIORef []
- return (reqs, dels)
- -- the first time we schedule an IO request, the service thread
- -- will be created (cool, huh?)
+pendingDelays :: IORef [DelayReq]
+pendingDelays = unsafePerformIO $ do
+ m <- newIORef []
+ sharedCAF m getOrSetGHCConcPendingDelaysStore
+
+foreign import ccall unsafe "getOrSetGHCConcPendingDelaysStore"
+ getOrSetGHCConcPendingDelaysStore :: Ptr a -> IO (Ptr a)
+
+{-# NOINLINE ioManagerThread #-}
+ioManagerThread :: MVar (Maybe ThreadId)
+ioManagerThread = unsafePerformIO $ do
+ m <- newMVar Nothing
+ sharedCAF m getOrSetGHCConcIOManagerThreadStore
+
+foreign import ccall unsafe "getOrSetGHCConcIOManagerThreadStore"
+ getOrSetGHCConcIOManagerThreadStore :: Ptr a -> IO (Ptr a)
ensureIOManagerIsRunning :: IO ()
ensureIOManagerIsRunning
- | threaded = seq pendingEvents $ return ()
+ | threaded = startIOManagerThread
| otherwise = return ()
+startIOManagerThread :: IO ()
+startIOManagerThread = do
+ modifyMVar_ ioManagerThread $ \old -> do
+ let create = do t <- forkIO ioManager; return (Just t)
+ case old of
+ Nothing -> create
+ Just t -> do
+ s <- threadStatus t
+ case s of
+ ThreadFinished -> create
+ ThreadDied -> create
+ _other -> return (Just t)
+
insertDelay :: DelayReq -> [DelayReq] -> [DelayReq]
insertDelay d [] = [d]
insertDelay d1 ds@(d2 : rest)
type USecs = Word64
--- XXX: move into GHC.IOBase from Data.IORef?
-atomicModifyIORef :: IORef a -> (a -> (a,b)) -> IO b
-atomicModifyIORef (IORef (STRef r#)) f = IO $ \s -> atomicModifyMutVar# r# f s
-
foreign import ccall unsafe "getUSecOfDay"
getUSecOfDay :: IO USecs
-prodding :: IORef Bool
{-# NOINLINE prodding #-}
-prodding = unsafePerformIO (newIORef False)
+prodding :: IORef Bool
+prodding = unsafePerformIO $ do
+ r <- newIORef False
+ sharedCAF r getOrSetGHCConcProddingStore
+
+foreign import ccall unsafe "getOrSetGHCConcProddingStore"
+ getOrSetGHCConcProddingStore :: Ptr a -> IO (Ptr a)
prodServiceThread :: IO ()
prodServiceThread = do
- was_set <- atomicModifyIORef prodding (\a -> (True,a))
- if (not (was_set)) then wakeupIOManager else return ()
+ -- NB. use atomicModifyIORef here, otherwise there are race
+ -- conditions in which prodding is left at True but the server is
+ -- blocked in select().
+ was_set <- atomicModifyIORef prodding $ \b -> (True,b)
+ unless was_set wakeupIOManager
+
+-- Machinery needed to ensure that we only have one copy of certain
+-- CAFs in this module even when the base package is present twice, as
+-- it is when base is dynamically loaded into GHCi. The RTS keeps
+-- track of the single true value of the CAF, so even when the CAFs in
+-- the dynamically-loaded base package are reverted, nothing bad
+-- happens.
+--
+sharedCAF :: a -> (Ptr a -> IO (Ptr a)) -> IO a
+sharedCAF a get_or_set =
+ block $ do
+ stable_ref <- newStablePtr a
+ let ref = castPtr (castStablePtrToPtr stable_ref)
+ ref2 <- get_or_set ref
+ if ref==ref2
+ then return a
+ else do freeStablePtr stable_ref
+ deRefStablePtr (castPtrToStablePtr (castPtr ref2))
#ifdef mingw32_HOST_OS
-- ----------------------------------------------------------------------------
-- Windows IO manager thread
-startIOManagerThread :: IO ()
-startIOManagerThread = do
+ioManager :: IO ()
+ioManager = do
wakeup <- c_getIOManagerEvent
- forkIO $ service_loop wakeup []
- return ()
+ service_loop wakeup []
service_loop :: HANDLE -- read end of pipe
-> [DelayReq] -- current delay requests
case r of
0xffffffff -> do c_maperrno; throwErrno "service_loop"
0 -> do
- r <- c_readIOManagerEvent
+ r2 <- c_readIOManagerEvent
exit <-
- case r of
- _ | r == io_MANAGER_WAKEUP -> return False
- _ | r == io_MANAGER_DIE -> return True
+ case r2 of
+ _ | r2 == io_MANAGER_WAKEUP -> return False
+ _ | r2 == io_MANAGER_DIE -> return True
0 -> return False -- spurious wakeup
- r -> do start_console_handler (r `shiftR` 1); return False
- if exit
- then return ()
- else service_cont wakeup delays'
+ _ -> do start_console_handler (r2 `shiftR` 1); return False
+ unless exit $ service_cont wakeup delays'
_other -> service_cont wakeup delays' -- probably timeout
+service_cont :: HANDLE -> [DelayReq] -> IO ()
service_cont wakeup delays = do
- atomicModifyIORef prodding (\_ -> (False,False))
+ r <- atomicModifyIORef prodding (\_ -> (False,False))
+ r `seq` return () -- avoid space leak
service_loop wakeup delays
-- must agree with rts/win32/ThrIOManager.c
-io_MANAGER_WAKEUP = 0xffffffff :: Word32
-io_MANAGER_DIE = 0xfffffffe :: Word32
+io_MANAGER_WAKEUP, io_MANAGER_DIE :: Word32
+io_MANAGER_WAKEUP = 0xffffffff
+io_MANAGER_DIE = 0xfffffffe
data ConsoleEvent
= ControlC
start_console_handler r =
case toWin32ConsoleEvent r of
Just x -> withMVar win32ConsoleHandler $ \handler -> do
- forkIO (handler x)
+ _ <- forkIO (handler x)
return ()
Nothing -> return ()
+toWin32ConsoleEvent :: Num a => a -> Maybe ConsoleEvent
toWin32ConsoleEvent ev =
case ev of
0 {- CTRL_C_EVENT-} -> Just ControlC
win32ConsoleHandler :: MVar (ConsoleEvent -> IO ())
win32ConsoleHandler = unsafePerformIO (newMVar (error "win32ConsoleHandler"))
-stick :: IORef HANDLE
-{-# NOINLINE stick #-}
-stick = unsafePerformIO (newIORef nullPtr)
-
-wakeupIOManager = do
- hdl <- readIORef stick
- c_sendIOManagerEvent io_MANAGER_WAKEUP
+wakeupIOManager :: IO ()
+wakeupIOManager = c_sendIOManagerEvent io_MANAGER_WAKEUP
-- Walk the queue of pending delays, waking up any that have passed
-- and return the smallest delay to wait for. The queue of pending
-- delays is kept ordered.
getDelay :: USecs -> [DelayReq] -> IO ([DelayReq], DWORD)
-getDelay now [] = return ([], iNFINITE)
+getDelay _ [] = return ([], iNFINITE)
getDelay now all@(d : rest)
= case d of
Delay time m | now >= time -> do
type HANDLE = Ptr ()
type DWORD = Word32
-iNFINITE = 0xFFFFFFFF :: DWORD -- urgh
+iNFINITE :: DWORD
+iNFINITE = 0xFFFFFFFF -- urgh
foreign import ccall unsafe "getIOManagerEvent" -- in the RTS (ThrIOManager.c)
c_getIOManagerEvent :: IO HANDLE
-- ----------------------------------------------------------------------------
-- Unix IO manager thread, using select()
-startIOManagerThread :: IO ()
-startIOManagerThread = do
+ioManager :: IO ()
+ioManager = do
allocaArray 2 $ \fds -> do
- throwErrnoIfMinus1 "startIOManagerThread" (c_pipe fds)
+ throwErrnoIfMinus1_ "startIOManagerThread" (c_pipe fds)
rd_end <- peekElemOff fds 0
wr_end <- peekElemOff fds 1
- writeIORef stick (fromIntegral wr_end)
+ setNonBlockingFD wr_end True -- writes happen in a signal handler, we
+ -- don't want them to block.
+ setCloseOnExec rd_end
+ setCloseOnExec wr_end
c_setIOManagerPipe wr_end
- forkIO $ do
- allocaBytes sizeofFdSet $ \readfds -> do
- allocaBytes sizeofFdSet $ \writefds -> do
- allocaBytes sizeofTimeVal $ \timeval -> do
- service_loop (fromIntegral rd_end) readfds writefds timeval [] []
+ allocaBytes sizeofFdSet $ \readfds -> do
+ allocaBytes sizeofFdSet $ \writefds -> do
+ allocaBytes sizeofTimeVal $ \timeval -> do
+ service_loop (fromIntegral rd_end) readfds writefds timeval [] []
return ()
service_loop
-> IO ()
service_loop wakeup readfds writefds ptimeval old_reqs old_delays = do
+ -- reset prodding before we look at the new requests. If a new
+ -- client arrives after this point they will send a wakup which will
+ -- cause the server to loop around again, so we can be sure to not
+ -- miss any requests.
+ --
+ -- NB. it's important to do this in the *first* iteration of
+ -- service_loop, rather than after calling select(), since a client
+ -- may have set prodding to True without sending a wakeup byte down
+ -- the pipe, because the pipe wasn't set up.
+ atomicModifyIORef prodding (\_ -> (False, ()))
+
-- pick up new IO requests
new_reqs <- atomicModifyIORef pendingEvents (\a -> ([],a))
let reqs = new_reqs ++ old_reqs
-- pick up new delay requests
new_delays <- atomicModifyIORef pendingDelays (\a -> ([],a))
- let delays = foldr insertDelay old_delays new_delays
+ let delays0 = foldr insertDelay old_delays new_delays
-- build the FDSets for select()
fdZero readfds
else
return (False,delays')
- (wakeup_all,delays') <- do_select delays
+ (wakeup_all,delays') <- do_select delays0
exit <-
if wakeup_all then return False
if b == 0
then return False
else alloca $ \p -> do
- c_read (fromIntegral wakeup) p 1; return ()
+ warnErrnoIfMinus1_ "service_loop" $
+ c_read (fromIntegral wakeup) p 1
s <- peek p
case s of
_ | s == io_MANAGER_WAKEUP -> return False
_ | s == io_MANAGER_DIE -> return True
- _ -> withMVar signalHandlerLock $ \_ -> do
- handler_tbl <- peek handlers
- sp <- peekElemOff handler_tbl (fromIntegral s)
- io <- deRefStablePtr sp
- forkIO io
- return False
-
- if exit then return () else do
-
- atomicModifyIORef prodding (\_ -> (False,False))
+ _ | s == io_MANAGER_SYNC -> do
+ mvars <- readIORef sync
+ mapM_ (flip putMVar ()) mvars
+ return False
+ _ -> do
+ fp <- mallocForeignPtrBytes (fromIntegral sizeof_siginfo_t)
+ withForeignPtr fp $ \p_siginfo -> do
+ r <- c_read (fromIntegral wakeup) (castPtr p_siginfo)
+ sizeof_siginfo_t
+ when (r /= fromIntegral sizeof_siginfo_t) $
+ error "failed to read siginfo_t"
+ runHandlers' fp (fromIntegral s)
+ return False
+
+ unless exit $ do
reqs' <- if wakeup_all then do wakeupAll reqs; return []
else completeRequests reqs readfds writefds []
service_loop wakeup readfds writefds ptimeval reqs' delays'
-io_MANAGER_WAKEUP = 0xff :: CChar
-io_MANAGER_DIE = 0xfe :: CChar
+io_MANAGER_WAKEUP, io_MANAGER_DIE, io_MANAGER_SYNC :: Word8
+io_MANAGER_WAKEUP = 0xff
+io_MANAGER_DIE = 0xfe
+io_MANAGER_SYNC = 0xfd
-stick :: IORef Fd
-{-# NOINLINE stick #-}
-stick = unsafePerformIO (newIORef 0)
+{-# NOINLINE sync #-}
+sync :: IORef [MVar ()]
+sync = unsafePerformIO (newIORef [])
-wakeupIOManager :: IO ()
-wakeupIOManager = do
- fd <- readIORef stick
- with io_MANAGER_WAKEUP $ \pbuf -> do
- c_write (fromIntegral fd) pbuf 1; return ()
-
--- Lock used to protect concurrent access to signal_handlers. Symptom of
--- this race condition is #1922, although that bug was on Windows a similar
--- bug also exists on Unix.
-signalHandlerLock :: MVar ()
-signalHandlerLock = unsafePerformIO (newMVar ())
+-- waits for the IO manager to drain the pipe
+syncIOManager :: IO ()
+syncIOManager = do
+ m <- newEmptyMVar
+ atomicModifyIORef sync (\old -> (m:old,()))
+ c_ioManagerSync
+ takeMVar m
-foreign import ccall "&signal_handlers" handlers :: Ptr (Ptr (StablePtr (IO ())))
+foreign import ccall unsafe "ioManagerSync" c_ioManagerSync :: IO ()
+foreign import ccall unsafe "ioManagerWakeup" wakeupIOManager :: IO ()
+
+-- For the non-threaded RTS
+runHandlers :: Ptr Word8 -> Int -> IO ()
+runHandlers p_info sig = do
+ fp <- mallocForeignPtrBytes (fromIntegral sizeof_siginfo_t)
+ withForeignPtr fp $ \p -> do
+ copyBytes p p_info (fromIntegral sizeof_siginfo_t)
+ free p_info
+ runHandlers' fp (fromIntegral sig)
+
+runHandlers' :: ForeignPtr Word8 -> Signal -> IO ()
+runHandlers' p_info sig = do
+ let int = fromIntegral sig
+ withMVar signal_handlers $ \arr ->
+ if not (inRange (boundsIOArray arr) int)
+ then return ()
+ else do handler <- unsafeReadIOArray arr int
+ case handler of
+ Nothing -> return ()
+ Just (f,_) -> do _ <- forkIO (f p_info)
+ return ()
+
+warnErrnoIfMinus1_ :: Num a => String -> IO a -> IO ()
+warnErrnoIfMinus1_ what io
+ = do r <- io
+ when (r == -1) $ do
+ errno <- getErrno
+ str <- strerror errno >>= peekCString
+ when (r == -1) $
+ debugErrLn ("Warning: " ++ what ++ " failed: " ++ str)
+
+foreign import ccall unsafe "string.h" strerror :: Errno -> IO (Ptr CChar)
foreign import ccall "setIOManagerPipe"
c_setIOManagerPipe :: CInt -> IO ()
+foreign import ccall "__hscore_sizeof_siginfo_t"
+ sizeof_siginfo_t :: CSize
+
+type Signal = CInt
+
+maxSig = 64 :: Int
+
+type HandlerFun = ForeignPtr Word8 -> IO ()
+
+-- Lock used to protect concurrent access to signal_handlers. Symptom of
+-- this race condition is #1922, although that bug was on Windows a similar
+-- bug also exists on Unix.
+{-# NOINLINE signal_handlers #-}
+signal_handlers :: MVar (IOArray Int (Maybe (HandlerFun,Dynamic)))
+signal_handlers = unsafePerformIO $ do
+ arr <- newIOArray (0,maxSig) Nothing
+ m <- newMVar arr
+ sharedCAF m getOrSetGHCConcSignalHandlerStore
+
+foreign import ccall unsafe "getOrSetGHCConcSignalHandlerStore"
+ getOrSetGHCConcSignalHandlerStore :: Ptr a -> IO (Ptr a)
+
+setHandler :: Signal -> Maybe (HandlerFun,Dynamic) -> IO (Maybe (HandlerFun,Dynamic))
+setHandler sig handler = do
+ let int = fromIntegral sig
+ withMVar signal_handlers $ \arr ->
+ if not (inRange (boundsIOArray arr) int)
+ then error "GHC.Conc.setHandler: signal out of range"
+ else do old <- unsafeReadIOArray arr int
+ unsafeWriteIOArray arr int handler
+ return old
+
-- -----------------------------------------------------------------------------
-- IO requests
-buildFdSets maxfd readfds writefds [] = return maxfd
-buildFdSets maxfd readfds writefds (Read fd m : reqs)
+buildFdSets :: Fd -> Ptr CFdSet -> Ptr CFdSet -> [IOReq] -> IO Fd
+buildFdSets maxfd _ _ [] = return maxfd
+buildFdSets maxfd readfds writefds (Read fd _ : reqs)
| fd >= fD_SETSIZE = error "buildFdSets: file descriptor out of range"
| otherwise = do
fdSet fd readfds
buildFdSets (max maxfd fd) readfds writefds reqs
-buildFdSets maxfd readfds writefds (Write fd m : reqs)
+buildFdSets maxfd readfds writefds (Write fd _ : reqs)
| fd >= fD_SETSIZE = error "buildFdSets: file descriptor out of range"
| otherwise = do
fdSet fd writefds
buildFdSets (max maxfd fd) readfds writefds reqs
+completeRequests :: [IOReq] -> Ptr CFdSet -> Ptr CFdSet -> [IOReq]
+ -> IO [IOReq]
completeRequests [] _ _ reqs' = return reqs'
completeRequests (Read fd m : reqs) readfds writefds reqs' = do
b <- fdIsSet fd readfds
then do putMVar m (); completeRequests reqs readfds writefds reqs'
else completeRequests reqs readfds writefds (Write fd m : reqs')
+wakeupAll :: [IOReq] -> IO ()
wakeupAll [] = return ()
-wakeupAll (Read fd m : reqs) = do putMVar m (); wakeupAll reqs
-wakeupAll (Write fd m : reqs) = do putMVar m (); wakeupAll reqs
+wakeupAll (Read _ m : reqs) = do putMVar m (); wakeupAll reqs
+wakeupAll (Write _ m : reqs) = do putMVar m (); wakeupAll reqs
waitForReadEvent :: Fd -> IO ()
waitForReadEvent fd = do
-- and return the smallest delay to wait for. The queue of pending
-- delays is kept ordered.
getDelay :: USecs -> Ptr CTimeVal -> [DelayReq] -> IO ([DelayReq], Ptr CTimeVal)
-getDelay now ptimeval [] = return ([],nullPtr)
+getDelay _ _ [] = return ([],nullPtr)
getDelay now ptimeval all@(d : rest)
= case d of
Delay time m | now >= time -> do
setTimevalTicks ptimeval (delayTime d - now)
return (all,ptimeval)
-newtype CTimeVal = CTimeVal ()
+data CTimeVal
foreign import ccall unsafe "sizeofTimeVal"
sizeofTimeVal :: Int
-- ToDo: move to System.Posix.Internals?
-newtype CFdSet = CFdSet ()
+data CFdSet
-foreign import ccall safe "select"
+foreign import ccall safe "__hscore_select"
c_select :: CInt -> Ptr CFdSet -> Ptr CFdSet -> Ptr CFdSet -> Ptr CTimeVal
-> IO CInt
fD_SETSIZE :: Fd
fD_SETSIZE = fromIntegral c_fD_SETSIZE
-foreign import ccall unsafe "hsFD_CLR"
- c_fdClr :: CInt -> Ptr CFdSet -> IO ()
-
-fdClr :: Fd -> Ptr CFdSet -> IO ()
-fdClr (Fd fd) fdset = c_fdClr fd fdset
-
foreign import ccall unsafe "hsFD_ISSET"
c_fdIsSet :: CInt -> Ptr CFdSet -> IO CInt
#endif
-reportStackOverflow :: IO a
-reportStackOverflow = do callStackOverflowHook; return undefined
+reportStackOverflow :: IO ()
+reportStackOverflow = callStackOverflowHook
-reportError :: SomeException -> IO a
+reportError :: SomeException -> IO ()
reportError ex = do
handler <- getUncaughtExceptionHandler
handler ex
- return undefined
-- SUP: Are the hooks allowed to re-enter Haskell land? If so, remove
-- the unsafe below.
getUncaughtExceptionHandler :: IO (SomeException -> IO ())
getUncaughtExceptionHandler = readIORef uncaughtExceptionHandler
+
\end{code}