{-# LANGUAGE CPP #-}
{-# LANGUAGE Trustworthy #-}
{-# LANGUAGE BangPatterns, NoImplicitPrelude #-}

#include <ghcplatform.h>

module GHC.Internal.Event.Thread
#if defined(javascript_HOST_ARCH)
    ( ) where
#else
    ( getSystemEventManager
    , getSystemTimerManager
    , ensureIOManagerIsRunning
    , ioManagerCapabilitiesChanged
    , threadWaitRead
    , threadWaitWrite
    , threadWaitReadSTM
    , threadWaitWriteSTM
    , closeFdWith
    , threadDelay
    , registerDelay
    , blockedOnBadFD -- used by RTS
    ) where


-- TODO: Use new Windows I/O manager
import GHC.Internal.Control.Exception (finally, SomeException, toException)
import GHC.Internal.Data.Foldable (forM_, mapM_, sequence_)
import GHC.Internal.Data.IORef (IORef, newIORef, readIORef, writeIORef, atomicWriteIORef)
import GHC.Internal.Data.Maybe (fromMaybe)
import GHC.Internal.Data.Tuple (snd)
import GHC.Internal.Foreign.C.Error (eBADF, errnoToIOError)
import GHC.Internal.Foreign.C.Types (CInt(..), CUInt(..))
import GHC.Internal.Foreign.Ptr (Ptr)
import GHC.Internal.Base
import GHC.Internal.List (zipWith, zipWith3)
import GHC.Internal.Conc.Sync (TVar, ThreadId, ThreadStatus(..), atomically, forkIO,
                      labelThread, modifyMVar_, withMVar, newTVar, sharedCAF,
                      getNumCapabilities, threadCapability, myThreadId, forkOn,
                      threadStatus, writeTVar, newTVarIO, readTVar, retry,
                      throwSTM, STM, yield)
import GHC.Internal.IO (mask_, uninterruptibleMask_, onException)
import GHC.Internal.IO.Exception (ioError)
import GHC.Internal.IOArray (IOArray, newIOArray, readIOArray, writeIOArray,
                    boundsIOArray)
import GHC.Internal.MVar (MVar, newEmptyMVar, newMVar, putMVar, takeMVar)
import GHC.Internal.Event.Control (controlWriteFd)
import GHC.Internal.Event.Internal (eventIs, evtClose)
import GHC.Internal.Event.Manager (Event, EventManager, evtRead, evtWrite, loop,
                             new, registerFd, unregisterFd_)
import qualified GHC.Internal.Event.Manager as M
import qualified GHC.Internal.Event.TimerManager as TM
import GHC.Internal.Ix (inRange)
import GHC.Internal.Num ((-), (+))
import GHC.Internal.Real (fromIntegral)
import GHC.Internal.Show (showSignedInt)
import GHC.Internal.IO.Unsafe (unsafePerformIO)
import GHC.Internal.System.Posix.Types (Fd)

-- | Suspends the current thread for a given number of microseconds
-- (GHC only).
--
-- There is no guarantee that the thread will be rescheduled promptly
-- when the delay has expired, but the thread will never continue to
-- run /earlier/ than specified.
--
-- Be careful not to exceed @maxBound :: Int@, which on 32-bit machines is only
-- 2147483647 μs, less than 36 minutes.
--
threadDelay :: Int -> IO ()
threadDelay :: Int -> IO ()
threadDelay Int
usecs = IO () -> IO ()
forall a. IO a -> IO a
mask_ (IO () -> IO ()) -> IO () -> IO ()
forall a b. (a -> b) -> a -> b
$ do
  mgr <- IO TimerManager
getSystemTimerManager
  m <- newEmptyMVar
  reg <- TM.registerTimeout mgr usecs (putMVar m ())
  takeMVar m `onException` TM.unregisterTimeout mgr reg

-- | Set the value of returned TVar to True after a given number of
-- microseconds. The caveats associated with threadDelay also apply.
--
-- Be careful not to exceed @maxBound :: Int@, which on 32-bit machines is only
-- 2147483647 μs, less than 36 minutes.
--
registerDelay :: Int -> IO (TVar Bool)
registerDelay :: Int -> IO (TVar Bool)
registerDelay Int
usecs = do
  t <- STM (TVar Bool) -> IO (TVar Bool)
forall a. STM a -> IO a
atomically (STM (TVar Bool) -> IO (TVar Bool))
-> STM (TVar Bool) -> IO (TVar Bool)
forall a b. (a -> b) -> a -> b
$ Bool -> STM (TVar Bool)
forall a. a -> STM (TVar a)
newTVar Bool
False
  mgr <- getSystemTimerManager
  _ <- TM.registerTimeout mgr usecs . atomically $ writeTVar t True
  return t

-- | Block the current thread until data is available to read from the
-- given file descriptor.
--
-- This will throw an 'Prelude.IOError' if the file descriptor was closed
-- while this thread was blocked.  To safely close a file descriptor
-- that has been used with 'threadWaitRead', use 'closeFdWith'.
threadWaitRead :: Fd -> IO ()
threadWaitRead :: Fd -> IO ()
threadWaitRead = Event -> Fd -> IO ()
threadWait Event
evtRead
{-# INLINE threadWaitRead #-}

-- | Block the current thread until the given file descriptor can
-- accept data to write.
--
-- This will throw an 'Prelude.IOError' if the file descriptor was closed
-- while this thread was blocked.  To safely close a file descriptor
-- that has been used with 'threadWaitWrite', use 'closeFdWith'.
threadWaitWrite :: Fd -> IO ()
threadWaitWrite :: Fd -> IO ()
threadWaitWrite = Event -> Fd -> IO ()
threadWait Event
evtWrite
{-# INLINE threadWaitWrite #-}

-- | Close a file descriptor in a concurrency-safe way.
--
-- Any threads that are blocked on the file descriptor via
-- 'threadWaitRead' or 'threadWaitWrite' will be unblocked by having
-- IO exceptions thrown.
closeFdWith :: (Fd -> IO ())        -- ^ Action that performs the close.
            -> Fd                   -- ^ File descriptor to close.
            -> IO ()
closeFdWith :: (Fd -> IO ()) -> Fd -> IO ()
closeFdWith Fd -> IO ()
close Fd
fd = IO ()
close_loop
  where
    finish :: EventManager -> IntTable [FdData] -> IO b -> IO b
finish EventManager
mgr IntTable [FdData]
table IO b
cbApp = MVar (IntTable [FdData]) -> IntTable [FdData] -> IO ()
forall a. MVar a -> a -> IO ()
putMVar (EventManager -> Fd -> MVar (IntTable [FdData])
M.callbackTableVar EventManager
mgr Fd
fd) IntTable [FdData]
table IO () -> IO b -> IO b
forall a b. IO a -> IO b -> IO b
forall (m :: * -> *) a b. Monad m => m a -> m b -> m b
>> IO b
cbApp
    zipWithM :: (a -> b -> m a) -> [a] -> [b] -> m [a]
zipWithM a -> b -> m a
f [a]
xs [b]
ys = [m a] -> m [a]
forall (m :: * -> *) a. Monad m => [m a] -> m [a]
sequence ((a -> b -> m a) -> [a] -> [b] -> [m a]
forall a b c. (a -> b -> c) -> [a] -> [b] -> [c]
zipWith a -> b -> m a
f [a]
xs [b]
ys)
      -- The array inside 'eventManager' can be swapped out at any time, see
      -- 'ioManagerCapabilitiesChanged'. See #21651. We detect this case by
      -- checking the array bounds before and after. When such a swap has
      -- happened we cleanup and try again
    close_loop :: IO ()
close_loop = do
      eventManagerArray <- IORef (IOArray Int (Maybe (ThreadId, EventManager)))
-> IO (IOArray Int (Maybe (ThreadId, EventManager)))
forall a. IORef a -> IO a
readIORef IORef (IOArray Int (Maybe (ThreadId, EventManager)))
eventManager
      let ema_bounds@(low, high) = boundsIOArray eventManagerArray
      mgrs <- flip mapM [low..high] $ \Int
i -> do
        Just (_,!mgr) <- IOArray Int (Maybe (ThreadId, EventManager))
-> Int -> IO (Maybe (ThreadId, EventManager))
forall i e. Ix i => IOArray i e -> i -> IO e
readIOArray IOArray Int (Maybe (ThreadId, EventManager))
eventManagerArray Int
i
        return mgr

      -- 'takeMVar', and 'M.closeFd_' might block, although for a very short time.
      -- To make 'closeFdWith' safe in presence of asynchronous exceptions we have
      -- to use uninterruptible mask.
      join $ uninterruptibleMask_ $ do
        tables <- flip mapM mgrs $ \EventManager
mgr -> MVar (IntTable [FdData]) -> IO (IntTable [FdData])
forall a. MVar a -> IO a
takeMVar (MVar (IntTable [FdData]) -> IO (IntTable [FdData]))
-> MVar (IntTable [FdData]) -> IO (IntTable [FdData])
forall a b. (a -> b) -> a -> b
$ EventManager -> Fd -> MVar (IntTable [FdData])
M.callbackTableVar EventManager
mgr Fd
fd
        new_ema_bounds <- boundsIOArray `fmap` readIORef eventManager
        -- Here we exploit Note [The eventManager Array]
        if new_ema_bounds /= ema_bounds
          then do
            -- the array has been modified.
            -- mgrs still holds the right EventManagers, by the Note.
            -- new_ema_bounds must be larger than ema_bounds, by the note.
            -- return the MVars we took and try again
            sequence_ $ zipWith (\EventManager
mgr IntTable [FdData]
table -> EventManager -> IntTable [FdData] -> IO () -> IO ()
forall {b}. EventManager -> IntTable [FdData] -> IO b -> IO b
finish EventManager
mgr IntTable [FdData]
table (() -> IO ()
forall a. a -> IO a
forall (f :: * -> *) a. Applicative f => a -> f a
pure ())) mgrs tables
            pure close_loop
          else do
            -- We surely have taken all the appropriate MVars. Even if the array
            -- has been swapped, our mgrs is still correct.
            -- Remove the Fd from all callback tables, close the Fd, and run all
            -- callbacks.
            cbApps <- zipWithM (\EventManager
mgr IntTable [FdData]
table -> EventManager -> IntTable [FdData] -> Fd -> IO (IO ())
M.closeFd_ EventManager
mgr IntTable [FdData]
table Fd
fd) mgrs tables
            close fd `finally` sequence_ (zipWith3 finish mgrs tables cbApps)
            pure (pure ())

threadWait :: Event -> Fd -> IO ()
threadWait :: Event -> Fd -> IO ()
threadWait Event
evt Fd
fd = IO () -> IO ()
forall a. IO a -> IO a
mask_ (IO () -> IO ()) -> IO () -> IO ()
forall a b. (a -> b) -> a -> b
$ do
  m <- IO (MVar Event)
forall a. IO (MVar a)
newEmptyMVar
  mgr <- getSystemEventManager_
  reg <- registerFd mgr (\FdKey
_ Event
e -> MVar Event -> Event -> IO ()
forall a. MVar a -> a -> IO ()
putMVar MVar Event
m Event
e) fd evt M.OneShot
  evt' <- takeMVar m `onException` unregisterFd_ mgr reg
  if evt' `eventIs` evtClose
    then ioError $ errnoToIOError "threadWait" eBADF Nothing Nothing
    else return ()

-- used at least by RTS in 'select()' IO manager backend
blockedOnBadFD :: SomeException
blockedOnBadFD :: SomeException
blockedOnBadFD = IOError -> SomeException
forall e. Exception e => e -> SomeException
toException (IOError -> SomeException) -> IOError -> SomeException
forall a b. (a -> b) -> a -> b
$ String -> Errno -> Maybe Handle -> Maybe String -> IOError
errnoToIOError String
"awaitEvent" Errno
eBADF Maybe Handle
forall a. Maybe a
Nothing Maybe String
forall a. Maybe a
Nothing

threadWaitSTM :: Event -> Fd -> IO (STM (), IO ())
threadWaitSTM :: Event -> Fd -> IO (STM (), IO ())
threadWaitSTM Event
evt Fd
fd = IO (STM (), IO ()) -> IO (STM (), IO ())
forall a. IO a -> IO a
mask_ (IO (STM (), IO ()) -> IO (STM (), IO ()))
-> IO (STM (), IO ()) -> IO (STM (), IO ())
forall a b. (a -> b) -> a -> b
$ do
  m <- Maybe Event -> IO (TVar (Maybe Event))
forall a. a -> IO (TVar a)
newTVarIO Maybe Event
forall a. Maybe a
Nothing
  mgr <- getSystemEventManager_
  reg <- registerFd mgr (\FdKey
_ Event
e -> STM () -> IO ()
forall a. STM a -> IO a
atomically (TVar (Maybe Event) -> Maybe Event -> STM ()
forall a. TVar a -> a -> STM ()
writeTVar TVar (Maybe Event)
m (Event -> Maybe Event
forall a. a -> Maybe a
Just Event
e))) fd evt M.OneShot
  let waitAction =
        do mevt <- TVar (Maybe Event) -> STM (Maybe Event)
forall a. TVar a -> STM a
readTVar TVar (Maybe Event)
m
           case mevt of
             Maybe Event
Nothing -> STM ()
forall a. STM a
retry
             Just Event
evt' ->
               if Event
evt' Event -> Event -> Bool
`eventIs` Event
evtClose
               then IOError -> STM ()
forall e a. Exception e => e -> STM a
throwSTM (IOError -> STM ()) -> IOError -> STM ()
forall a b. (a -> b) -> a -> b
$ String -> Errno -> Maybe Handle -> Maybe String -> IOError
errnoToIOError String
"threadWaitSTM" Errno
eBADF Maybe Handle
forall a. Maybe a
Nothing Maybe String
forall a. Maybe a
Nothing
               else () -> STM ()
forall a. a -> STM a
forall (m :: * -> *) a. Monad m => a -> m a
return ()
  return (waitAction, unregisterFd_ mgr reg >> return ())

-- | Allows a thread to use an STM action to wait for a file descriptor to be readable.
-- The STM action will retry until the file descriptor has data ready.
-- The second element of the return value pair is an IO action that can be used
-- to deregister interest in the file descriptor.
--
-- The STM action will throw an 'Prelude.IOError' if the file descriptor was closed
-- while the STM action is being executed.  To safely close a file descriptor
-- that has been used with 'threadWaitReadSTM', use 'closeFdWith'.
threadWaitReadSTM :: Fd -> IO (STM (), IO ())
threadWaitReadSTM :: Fd -> IO (STM (), IO ())
threadWaitReadSTM = Event -> Fd -> IO (STM (), IO ())
threadWaitSTM Event
evtRead
{-# INLINE threadWaitReadSTM #-}

-- | Allows a thread to use an STM action to wait until a file descriptor can accept a write.
-- The STM action will retry while the file until the given file descriptor can accept a write.
-- The second element of the return value pair is an IO action that can be used to deregister
-- interest in the file descriptor.
--
-- The STM action will throw an 'Prelude.IOError' if the file descriptor was closed
-- while the STM action is being executed.  To safely close a file descriptor
-- that has been used with 'threadWaitWriteSTM', use 'closeFdWith'.
threadWaitWriteSTM :: Fd -> IO (STM (), IO ())
threadWaitWriteSTM :: Fd -> IO (STM (), IO ())
threadWaitWriteSTM = Event -> Fd -> IO (STM (), IO ())
threadWaitSTM Event
evtWrite
{-# INLINE threadWaitWriteSTM #-}


-- | Retrieve the system event manager for the capability on which the
-- calling thread is running.
--
-- This function always returns 'Just' the current thread's event manager
-- when using the threaded RTS and 'Nothing' otherwise.
getSystemEventManager :: IO (Maybe EventManager)
getSystemEventManager :: IO (Maybe EventManager)
getSystemEventManager = do
  t <- IO ThreadId
myThreadId
  eventManagerArray <- readIORef eventManager
  let r = IOArray Int (Maybe (ThreadId, EventManager)) -> (Int, Int)
forall i e. IOArray i e -> (i, i)
boundsIOArray IOArray Int (Maybe (ThreadId, EventManager))
eventManagerArray
  (cap, _) <- threadCapability t
  -- It is possible that we've just increased the number of capabilities and the
  -- new EventManager has not yet been constructed by
  -- 'ioManagerCapabilitiesChanged'. We expect this to happen very rarely.
  -- T21561 exercises this.
  -- Two options to proceed:
  --  1) return the EventManager for capability 0. This is guaranteed to exist,
  --     and "shouldn't" cause any correctness issues.
  --  2) Busy wait, with or without a call to 'yield'. This can't deadlock,
  --     because we must be on a brand capability and there must be a call to
  --     'ioManagerCapabilitiesChanged' pending.
  --
  -- We take the second option, with the yield, judging it the most robust.
  if not (inRange r cap)
    then yield >> getSystemEventManager
    else fmap snd `fmap` readIOArray eventManagerArray cap

getSystemEventManager_ :: IO EventManager
getSystemEventManager_ :: IO EventManager
getSystemEventManager_ = do
  Just mgr <- IO (Maybe EventManager)
getSystemEventManager
  return mgr
{-# INLINE getSystemEventManager_ #-}

foreign import ccall unsafe "getOrSetSystemEventThreadEventManagerStore"
    getOrSetSystemEventThreadEventManagerStore :: Ptr a -> IO (Ptr a)

-- Note [The eventManager Array]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-- A mutable array holding the current EventManager for each capability
-- An entry is Nothing only while the eventmanagers are initialised, see
-- 'startIOManagerThread' and 'ioManagerCapabilitiesChanged'.
-- The 'ThreadId' at array position 'cap'  will have been 'forkOn'ed capability
-- 'cap'.
-- The array will be swapped with newer arrays when the number of capabilities
-- changes(via 'setNumCapabilities'). However:
--   * the size of the arrays will never decrease; and
--   * The 'EventManager's in the array are not replaced with other
--     'EventManager' constructors.
--
-- This is a similar strategy as the rts uses for it's
-- capabilities array (n_capabilities is the size of the array,
-- enabled_capabilities' is the number of active capabilities).
eventManager :: IORef (IOArray Int (Maybe (ThreadId, EventManager)))
eventManager :: IORef (IOArray Int (Maybe (ThreadId, EventManager)))
eventManager = IO (IORef (IOArray Int (Maybe (ThreadId, EventManager))))
-> IORef (IOArray Int (Maybe (ThreadId, EventManager)))
forall a. IO a -> a
unsafePerformIO (IO (IORef (IOArray Int (Maybe (ThreadId, EventManager))))
 -> IORef (IOArray Int (Maybe (ThreadId, EventManager))))
-> IO (IORef (IOArray Int (Maybe (ThreadId, EventManager))))
-> IORef (IOArray Int (Maybe (ThreadId, EventManager)))
forall a b. (a -> b) -> a -> b
$ do
    numCaps <- IO Int
getNumCapabilities
    eventManagerArray <- newIOArray (0, numCaps - 1) Nothing
    em <- newIORef eventManagerArray
    sharedCAF em getOrSetSystemEventThreadEventManagerStore
{-# NOINLINE eventManager #-}

numEnabledEventManagers :: IORef Int
numEnabledEventManagers :: IORef Int
numEnabledEventManagers = IO (IORef Int) -> IORef Int
forall a. IO a -> a
unsafePerformIO (IO (IORef Int) -> IORef Int) -> IO (IORef Int) -> IORef Int
forall a b. (a -> b) -> a -> b
$ Int -> IO (IORef Int)
forall a. a -> IO (IORef a)
newIORef Int
0
{-# NOINLINE numEnabledEventManagers #-}

foreign import ccall unsafe "getOrSetSystemEventThreadIOManagerThreadStore"
    getOrSetSystemEventThreadIOManagerThreadStore :: Ptr a -> IO (Ptr a)

-- | The ioManagerLock protects the 'eventManager' value:
-- Only one thread at a time can start or shutdown event managers.
{-# NOINLINE ioManagerLock #-}
ioManagerLock :: MVar ()
ioManagerLock :: MVar ()
ioManagerLock = IO (MVar ()) -> MVar ()
forall a. IO a -> a
unsafePerformIO (IO (MVar ()) -> MVar ()) -> IO (MVar ()) -> MVar ()
forall a b. (a -> b) -> a -> b
$ do
   m <- () -> IO (MVar ())
forall a. a -> IO (MVar a)
newMVar ()
   sharedCAF m getOrSetSystemEventThreadIOManagerThreadStore

getSystemTimerManager :: IO TM.TimerManager
getSystemTimerManager :: IO TimerManager
getSystemTimerManager =
  TimerManager -> Maybe TimerManager -> TimerManager
forall a. a -> Maybe a -> a
fromMaybe TimerManager
forall {a}. a
err (Maybe TimerManager -> TimerManager)
-> IO (Maybe TimerManager) -> IO TimerManager
forall a b. (a -> b) -> IO a -> IO b
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
`fmap` IORef (Maybe TimerManager) -> IO (Maybe TimerManager)
forall a. IORef a -> IO a
readIORef IORef (Maybe TimerManager)
timerManager
    where
      err :: a
err = String -> a
forall a. HasCallStack => String -> a
error String
"GHC.Internal.Event.Thread.getSystemTimerManager: the TimerManager requires linking against the threaded runtime"

foreign import ccall unsafe "getOrSetSystemTimerThreadEventManagerStore"
    getOrSetSystemTimerThreadEventManagerStore :: Ptr a -> IO (Ptr a)

timerManager :: IORef (Maybe TM.TimerManager)
timerManager :: IORef (Maybe TimerManager)
timerManager = IO (IORef (Maybe TimerManager)) -> IORef (Maybe TimerManager)
forall a. IO a -> a
unsafePerformIO (IO (IORef (Maybe TimerManager)) -> IORef (Maybe TimerManager))
-> IO (IORef (Maybe TimerManager)) -> IORef (Maybe TimerManager)
forall a b. (a -> b) -> a -> b
$ do
    em <- Maybe TimerManager -> IO (IORef (Maybe TimerManager))
forall a. a -> IO (IORef a)
newIORef Maybe TimerManager
forall a. Maybe a
Nothing
    sharedCAF em getOrSetSystemTimerThreadEventManagerStore
{-# NOINLINE timerManager #-}

foreign import ccall unsafe "getOrSetSystemTimerThreadIOManagerThreadStore"
    getOrSetSystemTimerThreadIOManagerThreadStore :: Ptr a -> IO (Ptr a)

{-# NOINLINE timerManagerThreadVar #-}
timerManagerThreadVar :: MVar (Maybe ThreadId)
timerManagerThreadVar :: MVar (Maybe ThreadId)
timerManagerThreadVar = IO (MVar (Maybe ThreadId)) -> MVar (Maybe ThreadId)
forall a. IO a -> a
unsafePerformIO (IO (MVar (Maybe ThreadId)) -> MVar (Maybe ThreadId))
-> IO (MVar (Maybe ThreadId)) -> MVar (Maybe ThreadId)
forall a b. (a -> b) -> a -> b
$ do
   m <- Maybe ThreadId -> IO (MVar (Maybe ThreadId))
forall a. a -> IO (MVar a)
newMVar Maybe ThreadId
forall a. Maybe a
Nothing
   sharedCAF m getOrSetSystemTimerThreadIOManagerThreadStore

ensureIOManagerIsRunning :: IO ()
ensureIOManagerIsRunning :: IO ()
ensureIOManagerIsRunning
  | Bool -> Bool
not Bool
threaded = () -> IO ()
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return ()
  | Bool
otherwise = do
      IO ()
startIOManagerThreads
      IO ()
startTimerManagerThread

startIOManagerThreads :: IO ()
startIOManagerThreads :: IO ()
startIOManagerThreads =
  MVar () -> (() -> IO ()) -> IO ()
forall a b. MVar a -> (a -> IO b) -> IO b
withMVar MVar ()
ioManagerLock ((() -> IO ()) -> IO ()) -> (() -> IO ()) -> IO ()
forall a b. (a -> b) -> a -> b
$ \()
_ -> do
    eventManagerArray <- IORef (IOArray Int (Maybe (ThreadId, EventManager)))
-> IO (IOArray Int (Maybe (ThreadId, EventManager)))
forall a. IORef a -> IO a
readIORef IORef (IOArray Int (Maybe (ThreadId, EventManager)))
eventManager
    let (_, high) = boundsIOArray eventManagerArray
    mapM_ (startIOManagerThread eventManagerArray) [0..high]
    writeIORef numEnabledEventManagers (high+1)

show_int :: Int -> String
show_int :: Int -> String
show_int Int
i = Int -> Int -> ShowS
showSignedInt Int
0 Int
i String
""

restartPollLoop :: EventManager -> Int -> IO ThreadId
restartPollLoop :: EventManager -> Int -> IO ThreadId
restartPollLoop EventManager
mgr Int
i = do
  EventManager -> IO ()
M.release EventManager
mgr
  !t <- Int -> IO () -> IO ThreadId
forkOn Int
i (IO () -> IO ThreadId) -> IO () -> IO ThreadId
forall a b. (a -> b) -> a -> b
$ EventManager -> IO ()
loop EventManager
mgr
  labelThread t ("IOManager on cap " ++ show_int i)
  return t

startIOManagerThread :: IOArray Int (Maybe (ThreadId, EventManager))
                        -> Int
                        -> IO ()
startIOManagerThread :: IOArray Int (Maybe (ThreadId, EventManager)) -> Int -> IO ()
startIOManagerThread IOArray Int (Maybe (ThreadId, EventManager))
eventManagerArray Int
i = do
  let create :: IO ()
create = do
        !mgr <- IO EventManager
new
        !t <- forkOn i $ do
                c_setIOManagerControlFd
                  (fromIntegral i)
                  (fromIntegral $ controlWriteFd $ M.emControl mgr)
                loop mgr
        labelThread t ("IOManager on cap " ++ show_int i)
        writeIOArray eventManagerArray i (Just (t,mgr))
  old <- IOArray Int (Maybe (ThreadId, EventManager))
-> Int -> IO (Maybe (ThreadId, EventManager))
forall i e. Ix i => IOArray i e -> i -> IO e
readIOArray IOArray Int (Maybe (ThreadId, EventManager))
eventManagerArray Int
i
  case old of
    Maybe (ThreadId, EventManager)
Nothing     -> IO ()
create
    Just (ThreadId
t,EventManager
em) -> do
      s <- ThreadId -> IO ThreadStatus
threadStatus ThreadId
t
      case s of
        ThreadStatus
ThreadFinished -> IO ()
create
        ThreadStatus
ThreadDied     -> do
          -- Sanity check: if the thread has died, there is a chance
          -- that event manager is still alive. This could happened during
          -- the fork, for example. In this case we should clean up
          -- open pipes and everything else related to the event manager.
          -- See #4449
          CUInt -> CInt -> IO ()
c_setIOManagerControlFd (Int -> CUInt
forall a b. (Integral a, Num b) => a -> b
fromIntegral Int
i) (-CInt
1)
          EventManager -> IO ()
M.cleanup EventManager
em
          IO ()
create
        ThreadStatus
_other         -> () -> IO ()
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return ()

startTimerManagerThread :: IO ()
startTimerManagerThread :: IO ()
startTimerManagerThread = MVar (Maybe ThreadId)
-> (Maybe ThreadId -> IO (Maybe ThreadId)) -> IO ()
forall a. MVar a -> (a -> IO a) -> IO ()
modifyMVar_ MVar (Maybe ThreadId)
timerManagerThreadVar ((Maybe ThreadId -> IO (Maybe ThreadId)) -> IO ())
-> (Maybe ThreadId -> IO (Maybe ThreadId)) -> IO ()
forall a b. (a -> b) -> a -> b
$ \Maybe ThreadId
old -> do
  let create :: IO (Maybe ThreadId)
create = do
        !mgr <- IO TimerManager
TM.new
        c_setTimerManagerControlFd
          (fromIntegral $ controlWriteFd $ TM.emControl mgr)
        atomicWriteIORef timerManager $ Just mgr
        !t <- forkIO $ TM.loop mgr
        labelThread t "TimerManager"
        return $ Just t
  case Maybe ThreadId
old of
    Maybe ThreadId
Nothing            -> IO (Maybe ThreadId)
create
    st :: Maybe ThreadId
st@(Just ThreadId
t) -> do
      s <- ThreadId -> IO ThreadStatus
threadStatus ThreadId
t
      case s of
        ThreadStatus
ThreadFinished -> IO (Maybe ThreadId)
create
        ThreadStatus
ThreadDied     -> do
          -- Sanity check: if the thread has died, there is a chance
          -- that event manager is still alive. This could happened during
          -- the fork, for example. In this case we should clean up
          -- open pipes and everything else related to the event manager.
          -- See #4449
          mem <- IORef (Maybe TimerManager) -> IO (Maybe TimerManager)
forall a. IORef a -> IO a
readIORef IORef (Maybe TimerManager)
timerManager
          _ <- case mem of
                 Maybe TimerManager
Nothing -> () -> IO ()
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return ()
                 Just TimerManager
em -> do CInt -> IO ()
c_setTimerManagerControlFd (-CInt
1)
                               TimerManager -> IO ()
TM.cleanup TimerManager
em
          create
        ThreadStatus
_other         -> Maybe ThreadId -> IO (Maybe ThreadId)
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Maybe ThreadId
st

foreign import ccall unsafe "rtsSupportsBoundThreads" threaded :: Bool

ioManagerCapabilitiesChanged :: IO ()
ioManagerCapabilitiesChanged :: IO ()
ioManagerCapabilitiesChanged =
  MVar () -> (() -> IO ()) -> IO ()
forall a b. MVar a -> (a -> IO b) -> IO b
withMVar MVar ()
ioManagerLock ((() -> IO ()) -> IO ()) -> (() -> IO ()) -> IO ()
forall a b. (a -> b) -> a -> b
$ \()
_ -> do
    new_n_caps <- IO Int
getNumCapabilities
    numEnabled <- readIORef numEnabledEventManagers
    writeIORef numEnabledEventManagers new_n_caps
    eventManagerArray <- readIORef eventManager
    let (_, high) = boundsIOArray eventManagerArray
    let old_n_caps = Int
high Int -> Int -> Int
forall a. Num a => a -> a -> a
+ Int
1
    if new_n_caps > old_n_caps
      then do new_eventManagerArray <- newIOArray (0, new_n_caps - 1) Nothing

              -- copy the existing values into the new array:
              forM_ [0..high] $ \Int
i -> do
                Just (tid,mgr) <- IOArray Int (Maybe (ThreadId, EventManager))
-> Int -> IO (Maybe (ThreadId, EventManager))
forall i e. Ix i => IOArray i e -> i -> IO e
readIOArray IOArray Int (Maybe (ThreadId, EventManager))
eventManagerArray Int
i
                if i < numEnabled
                  then writeIOArray new_eventManagerArray i (Just (tid,mgr))
                  else do tid' <- restartPollLoop mgr i
                          writeIOArray new_eventManagerArray i (Just (tid',mgr))

              -- create new IO managers for the new caps:
              forM_ [old_n_caps..new_n_caps-1] $
                startIOManagerThread new_eventManagerArray

              -- update the event manager array reference:
              atomicWriteIORef eventManager new_eventManagerArray
              -- We need an atomic write here because 'eventManager' is accessed
              -- unsynchronized in 'getSystemEventManager' and 'closeFdWith'
      else when (new_n_caps > numEnabled) $
            forM_ [numEnabled..new_n_caps-1] $ \Int
i -> do
              Just (_,mgr) <- IOArray Int (Maybe (ThreadId, EventManager))
-> Int -> IO (Maybe (ThreadId, EventManager))
forall i e. Ix i => IOArray i e -> i -> IO e
readIOArray IOArray Int (Maybe (ThreadId, EventManager))
eventManagerArray Int
i
              tid <- restartPollLoop mgr i
              writeIOArray eventManagerArray i (Just (tid,mgr))

#if defined(wasm32_HOST_ARCH)
c_setIOManagerControlFd :: CUInt -> CInt -> IO ()
c_setIOManagerControlFd _ _ = pure ()

c_setTimerManagerControlFd :: CInt -> IO ()
c_setTimerManagerControlFd _ = pure ()
#else
-- Used to tell the RTS how it can send messages to the I/O manager.
foreign import ccall unsafe "setIOManagerControlFd"
   c_setIOManagerControlFd :: CUInt -> CInt -> IO ()

foreign import ccall unsafe "setTimerManagerControlFd"
   c_setTimerManagerControlFd :: CInt -> IO ()
#endif

#endif