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|
{-# LANGUAGE BangPatterns #-}
{-# LANGUAGE CPP #-}
{-# LANGUAGE ExistentialQuantification #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE NoImplicitPrelude #-}
{-# LANGUAGE RecordWildCards #-}
{-# LANGUAGE Trustworthy #-}
-- |
-- The event manager supports event notification on fds. Each fd may
-- have multiple callbacks registered, each listening for a different
-- set of events. Registrations may be automatically deactivated after
-- the occurrence of an event ("one-shot mode") or active until
-- explicitly unregistered.
--
-- If an fd has only one-shot registrations then we use one-shot
-- polling if available. Otherwise we use multi-shot polling.
module GHC.Event.Manager
( -- * Types
EventManager
-- * Creation
, new
, newWith
, newDefaultBackend
-- * Running
, finished
, loop
, step
, shutdown
, release
, cleanup
, wakeManager
-- * State
, callbackTableVar
, emControl
-- * Registering interest in I/O events
, Lifetime (..)
, Event
, evtRead
, evtWrite
, IOCallback
, FdKey(keyFd)
, FdData
, registerFd
, unregisterFd_
, unregisterFd
, closeFd
, closeFd_
) where
#include "EventConfig.h"
------------------------------------------------------------------------
-- Imports
import Control.Concurrent.MVar (MVar, newMVar, putMVar,
tryPutMVar, takeMVar, withMVar)
import Control.Exception (onException)
import Data.Bits ((.&.))
import Data.Foldable (forM_)
import Data.Functor (void)
import Data.IORef (IORef, atomicModifyIORef', mkWeakIORef, newIORef, readIORef,
writeIORef)
import Data.Maybe (maybe)
import Data.List (partition)
import GHC.Arr (Array, (!), listArray)
import GHC.Base
import GHC.Conc.Sync (yield)
import GHC.List (filter, replicate)
import GHC.Num (Num(..))
import GHC.Real (fromIntegral)
import GHC.Show (Show(..))
import GHC.Event.Control
import GHC.Event.IntTable (IntTable)
import GHC.Event.Internal (Backend, Event, evtClose, evtRead, evtWrite,
Lifetime(..), EventLifetime, Timeout(..))
import GHC.Event.Unique (Unique, UniqueSource, newSource, newUnique)
import System.Posix.Types (Fd)
import qualified GHC.Event.IntTable as IT
import qualified GHC.Event.Internal as I
#if defined(HAVE_KQUEUE)
import qualified GHC.Event.KQueue as KQueue
#elif defined(HAVE_EPOLL)
import qualified GHC.Event.EPoll as EPoll
#elif defined(HAVE_POLL)
import qualified GHC.Event.Poll as Poll
#else
# error not implemented for this operating system
#endif
------------------------------------------------------------------------
-- Types
data FdData = FdData {
fdKey :: {-# UNPACK #-} !FdKey
, fdEvents :: {-# UNPACK #-} !EventLifetime
, _fdCallback :: !IOCallback
}
-- | A file descriptor registration cookie.
data FdKey = FdKey {
keyFd :: {-# UNPACK #-} !Fd
, keyUnique :: {-# UNPACK #-} !Unique
} deriving ( Eq -- ^ @since 4.4.0.0
, Show -- ^ @since 4.4.0.0
)
-- | Callback invoked on I/O events.
type IOCallback = FdKey -> Event -> IO ()
data State = Created
| Running
| Dying
| Releasing
| Finished
deriving ( Eq -- ^ @since 4.4.0.0
, Show -- ^ @since 4.4.0.0
)
-- | The event manager state.
data EventManager = EventManager
{ emBackend :: !Backend
, emFds :: {-# UNPACK #-} !(Array Int (MVar (IntTable [FdData])))
, emState :: {-# UNPACK #-} !(IORef State)
, emUniqueSource :: {-# UNPACK #-} !UniqueSource
, emControl :: {-# UNPACK #-} !Control
, emLock :: {-# UNPACK #-} !(MVar ())
}
-- must be power of 2
callbackArraySize :: Int
callbackArraySize = 32
hashFd :: Fd -> Int
hashFd fd = fromIntegral fd .&. (callbackArraySize - 1)
{-# INLINE hashFd #-}
callbackTableVar :: EventManager -> Fd -> MVar (IntTable [FdData])
callbackTableVar mgr fd = emFds mgr ! hashFd fd
{-# INLINE callbackTableVar #-}
haveOneShot :: Bool
{-# INLINE haveOneShot #-}
#if defined(darwin_HOST_OS) || defined(ios_HOST_OS)
haveOneShot = False
#elif defined(HAVE_EPOLL) || defined(HAVE_KQUEUE)
haveOneShot = True
#else
haveOneShot = False
#endif
------------------------------------------------------------------------
-- Creation
handleControlEvent :: EventManager -> Fd -> Event -> IO ()
handleControlEvent mgr fd _evt = do
msg <- readControlMessage (emControl mgr) fd
case msg of
CMsgWakeup -> return ()
CMsgDie -> writeIORef (emState mgr) Finished
_ -> return ()
newDefaultBackend :: IO Backend
#if defined(HAVE_KQUEUE)
newDefaultBackend = KQueue.new
#elif defined(HAVE_EPOLL)
newDefaultBackend = EPoll.new
#elif defined(HAVE_POLL)
newDefaultBackend = Poll.new
#else
newDefaultBackend = errorWithoutStackTrace "no back end for this platform"
#endif
-- | Create a new event manager.
new :: IO EventManager
new = newWith =<< newDefaultBackend
-- | Create a new 'EventManager' with the given polling backend.
newWith :: Backend -> IO EventManager
newWith be = do
iofds <- fmap (listArray (0, callbackArraySize-1)) $
replicateM callbackArraySize (newMVar =<< IT.new 8)
ctrl <- newControl False
state <- newIORef Created
us <- newSource
_ <- mkWeakIORef state $ do
st <- atomicModifyIORef' state $ \s -> (Finished, s)
when (st /= Finished) $ do
I.delete be
closeControl ctrl
lockVar <- newMVar ()
let mgr = EventManager { emBackend = be
, emFds = iofds
, emState = state
, emUniqueSource = us
, emControl = ctrl
, emLock = lockVar
}
registerControlFd mgr (controlReadFd ctrl) evtRead
registerControlFd mgr (wakeupReadFd ctrl) evtRead
return mgr
where
replicateM n x = sequence (replicate n x)
failOnInvalidFile :: String -> Fd -> IO Bool -> IO ()
failOnInvalidFile loc fd m = do
ok <- m
when (not ok) $
let msg = "Failed while attempting to modify registration of file " ++
show fd ++ " at location " ++ loc
in errorWithoutStackTrace msg
registerControlFd :: EventManager -> Fd -> Event -> IO ()
registerControlFd mgr fd evs =
failOnInvalidFile "registerControlFd" fd $
I.modifyFd (emBackend mgr) fd mempty evs
-- | Asynchronously shuts down the event manager, if running.
shutdown :: EventManager -> IO ()
shutdown mgr = do
state <- atomicModifyIORef' (emState mgr) $ \s -> (Dying, s)
when (state == Running) $ sendDie (emControl mgr)
-- | Asynchronously tell the thread executing the event
-- manager loop to exit.
release :: EventManager -> IO ()
release EventManager{..} = do
state <- atomicModifyIORef' emState $ \s -> (Releasing, s)
when (state == Running) $ sendWakeup emControl
finished :: EventManager -> IO Bool
finished mgr = (== Finished) `liftM` readIORef (emState mgr)
cleanup :: EventManager -> IO ()
cleanup EventManager{..} = do
writeIORef emState Finished
void $ tryPutMVar emLock ()
I.delete emBackend
closeControl emControl
------------------------------------------------------------------------
-- Event loop
-- | Start handling events. This function loops until told to stop,
-- using 'shutdown'.
--
-- /Note/: This loop can only be run once per 'EventManager', as it
-- closes all of its control resources when it finishes.
loop :: EventManager -> IO ()
loop mgr@EventManager{..} = do
void $ takeMVar emLock
state <- atomicModifyIORef' emState $ \s -> case s of
Created -> (Running, s)
Releasing -> (Running, s)
_ -> (s, s)
case state of
Created -> go `onException` cleanup mgr
Releasing -> go `onException` cleanup mgr
Dying -> cleanup mgr
-- While a poll loop is never forked when the event manager is in the
-- 'Finished' state, its state could read 'Finished' once the new thread
-- actually runs. This is not an error, just an unfortunate race condition
-- in Thread.restartPollLoop. See #8235
Finished -> return ()
_ -> do cleanup mgr
errorWithoutStackTrace $ "GHC.Event.Manager.loop: state is already " ++
show state
where
go = do state <- step mgr
case state of
Running -> yield >> go
Releasing -> putMVar emLock ()
_ -> cleanup mgr
-- | To make a step, we first do a non-blocking poll, in case
-- there are already events ready to handle. This improves performance
-- because we can make an unsafe foreign C call, thereby avoiding
-- forcing the current Task to release the Capability and forcing a context switch.
-- If the poll fails to find events, we yield, putting the poll loop thread at
-- end of the Haskell run queue. When it comes back around, we do one more
-- non-blocking poll, in case we get lucky and have ready events.
-- If that also returns no events, then we do a blocking poll.
step :: EventManager -> IO State
step mgr@EventManager{..} = do
waitForIO
state <- readIORef emState
state `seq` return state
where
waitForIO = do
n1 <- I.poll emBackend Nothing (onFdEvent mgr)
when (n1 <= 0) $ do
yield
n2 <- I.poll emBackend Nothing (onFdEvent mgr)
when (n2 <= 0) $ do
_ <- I.poll emBackend (Just Forever) (onFdEvent mgr)
return ()
------------------------------------------------------------------------
-- Registering interest in I/O events
-- | Register interest in the given events, without waking the event
-- manager thread. The 'Bool' return value indicates whether the
-- event manager ought to be woken.
--
-- Note that the event manager is generally implemented in terms of the
-- platform's @select@ or @epoll@ system call, which tend to vary in
-- what sort of fds are permitted. For instance, waiting on regular files
-- is not allowed on many platforms.
registerFd_ :: EventManager -> IOCallback -> Fd -> Event -> Lifetime
-> IO (FdKey, Bool)
registerFd_ mgr@(EventManager{..}) cb fd evs lt = do
u <- newUnique emUniqueSource
let fd' = fromIntegral fd
reg = FdKey fd u
el = I.eventLifetime evs lt
!fdd = FdData reg el cb
(modify,ok) <- withMVar (callbackTableVar mgr fd) $ \tbl -> do
oldFdd <- IT.insertWith (++) fd' [fdd] tbl
let prevEvs :: EventLifetime
prevEvs = maybe mempty eventsOf oldFdd
el' :: EventLifetime
el' = prevEvs `mappend` el
case I.elLifetime el' of
-- All registrations want one-shot semantics and this is supported
OneShot | haveOneShot -> do
ok <- I.modifyFdOnce emBackend fd (I.elEvent el')
if ok
then return (False, True)
else IT.reset fd' oldFdd tbl >> return (False, False)
-- We don't want or don't support one-shot semantics
_ -> do
let modify = prevEvs /= el'
ok <- if modify
then let newEvs = I.elEvent el'
oldEvs = I.elEvent prevEvs
in I.modifyFd emBackend fd oldEvs newEvs
else return True
if ok
then return (modify, True)
else IT.reset fd' oldFdd tbl >> return (False, False)
-- this simulates behavior of old IO manager:
-- i.e. just call the callback if the registration fails.
when (not ok) (cb reg evs)
return (reg,modify)
{-# INLINE registerFd_ #-}
-- | @registerFd mgr cb fd evs lt@ registers interest in the events @evs@
-- on the file descriptor @fd@ for lifetime @lt@. @cb@ is called for
-- each event that occurs. Returns a cookie that can be handed to
-- 'unregisterFd'.
registerFd :: EventManager -> IOCallback -> Fd -> Event -> Lifetime -> IO FdKey
registerFd mgr cb fd evs lt = do
(r, wake) <- registerFd_ mgr cb fd evs lt
when wake $ wakeManager mgr
return r
{-# INLINE registerFd #-}
{-
Building GHC with parallel IO manager on Mac freezes when
compiling the dph libraries in the phase 2. As workaround, we
don't use oneshot and we wake up an IO manager on Mac every time
when we register an event.
For more information, please read:
https://gitlab.haskell.org/ghc/ghc/issues/7651
-}
-- | Wake up the event manager.
wakeManager :: EventManager -> IO ()
#if defined(darwin_HOST_OS) || defined(ios_HOST_OS)
wakeManager mgr = sendWakeup (emControl mgr)
#elif defined(HAVE_EPOLL) || defined(HAVE_KQUEUE)
wakeManager _ = return ()
#else
wakeManager mgr = sendWakeup (emControl mgr)
#endif
eventsOf :: [FdData] -> EventLifetime
eventsOf [fdd] = fdEvents fdd
eventsOf fdds = mconcat $ map fdEvents fdds
-- | Drop a previous file descriptor registration, without waking the
-- event manager thread. The return value indicates whether the event
-- manager ought to be woken.
unregisterFd_ :: EventManager -> FdKey -> IO Bool
unregisterFd_ mgr@(EventManager{..}) (FdKey fd u) =
withMVar (callbackTableVar mgr fd) $ \tbl -> do
let dropReg = nullToNothing . filter ((/= u) . keyUnique . fdKey)
fd' = fromIntegral fd
pairEvents :: [FdData] -> IO (EventLifetime, EventLifetime)
pairEvents prev = do
r <- maybe mempty eventsOf `fmap` IT.lookup fd' tbl
return (eventsOf prev, r)
(oldEls, newEls) <- IT.updateWith dropReg fd' tbl >>=
maybe (return (mempty, mempty)) pairEvents
let modify = oldEls /= newEls
when modify $ failOnInvalidFile "unregisterFd_" fd $
case I.elLifetime newEls of
OneShot | I.elEvent newEls /= mempty, haveOneShot ->
I.modifyFdOnce emBackend fd (I.elEvent newEls)
_ ->
I.modifyFd emBackend fd (I.elEvent oldEls) (I.elEvent newEls)
return modify
-- | Drop a previous file descriptor registration.
unregisterFd :: EventManager -> FdKey -> IO ()
unregisterFd mgr reg = do
wake <- unregisterFd_ mgr reg
when wake $ wakeManager mgr
-- | Close a file descriptor in a race-safe way. It might block, although for
-- a very short time; and thus it is interruptible by asynchronous exceptions.
closeFd :: EventManager -> (Fd -> IO ()) -> Fd -> IO ()
closeFd mgr close fd = do
fds <- withMVar (callbackTableVar mgr fd) $ \tbl -> do
prev <- IT.delete (fromIntegral fd) tbl
case prev of
Nothing -> close fd >> return []
Just fds -> do
let oldEls = eventsOf fds
when (I.elEvent oldEls /= mempty) $ do
_ <- I.modifyFd (emBackend mgr) fd (I.elEvent oldEls) mempty
wakeManager mgr
close fd
return fds
forM_ fds $ \(FdData reg el cb) -> cb reg (I.elEvent el `mappend` evtClose)
-- | Close a file descriptor in a race-safe way.
-- It assumes the caller will update the callback tables and that the caller
-- holds the callback table lock for the fd. It must hold this lock because
-- this command executes a backend command on the fd.
closeFd_ :: EventManager
-> IntTable [FdData]
-> Fd
-> IO (IO ())
closeFd_ mgr tbl fd = do
prev <- IT.delete (fromIntegral fd) tbl
case prev of
Nothing -> return (return ())
Just fds -> do
let oldEls = eventsOf fds
when (oldEls /= mempty) $ do
_ <- I.modifyFd (emBackend mgr) fd (I.elEvent oldEls) mempty
wakeManager mgr
return $
forM_ fds $ \(FdData reg el cb) ->
cb reg (I.elEvent el `mappend` evtClose)
------------------------------------------------------------------------
-- Utilities
-- | Call the callbacks corresponding to the given file descriptor.
onFdEvent :: EventManager -> Fd -> Event -> IO ()
onFdEvent mgr fd evs
| fd == controlReadFd (emControl mgr) || fd == wakeupReadFd (emControl mgr) =
handleControlEvent mgr fd evs
| otherwise = do
fdds <- withMVar (callbackTableVar mgr fd) $ \tbl ->
IT.delete (fromIntegral fd) tbl >>= maybe (return []) (selectCallbacks tbl)
forM_ fdds $ \(FdData reg _ cb) -> cb reg evs
where
-- | Here we look through the list of registrations for the fd of interest
-- and sort out which match the events that were triggered. We,
--
-- 1. re-arm the fd as appropriate
-- 2. reinsert registrations that weren't triggered and multishot
-- registrations
-- 3. return a list containing the callbacks that should be invoked.
selectCallbacks :: IntTable [FdData] -> [FdData] -> IO [FdData]
selectCallbacks tbl fdds = do
let -- figure out which registrations have been triggered
matches :: FdData -> Bool
matches fd' = evs `I.eventIs` I.elEvent (fdEvents fd')
(triggered, notTriggered) = partition matches fdds
-- sort out which registrations we need to retain
isMultishot :: FdData -> Bool
isMultishot fd' = I.elLifetime (fdEvents fd') == MultiShot
saved = notTriggered ++ filter isMultishot triggered
savedEls = eventsOf saved
allEls = eventsOf fdds
-- Reinsert multishot registrations.
-- We deleted the table entry for this fd above so we there isn't a preexisting entry
_ <- IT.insertWith (\_ _ -> saved) (fromIntegral fd) saved tbl
case I.elLifetime allEls of
-- we previously armed the fd for multiple shots, no need to rearm
MultiShot | allEls == savedEls ->
return ()
-- either we previously registered for one shot or the
-- events of interest have changed, we must re-arm
_ ->
case I.elLifetime savedEls of
OneShot | haveOneShot ->
-- if there are no saved events and we registered with one-shot
-- semantics then there is no need to re-arm
unless (OneShot == I.elLifetime allEls
&& mempty == I.elEvent savedEls) $
void $ I.modifyFdOnce (emBackend mgr) fd (I.elEvent savedEls)
_ ->
-- we need to re-arm with multi-shot semantics
void $ I.modifyFd (emBackend mgr) fd
(I.elEvent allEls) (I.elEvent savedEls)
return triggered
nullToNothing :: [a] -> Maybe [a]
nullToNothing [] = Nothing
nullToNothing xs@(_:_) = Just xs
unless :: Monad m => Bool -> m () -> m ()
unless p = when (not p)
|