{-# LINE 1 "src/System/Socket/Internal/Socket.hsc" #-} module System.Socket.Internal.Socket ( {-# LINE 2 "src/System/Socket/Internal/Socket.hsc" #-} Socket (..) , GetSocketOption (..) , unsafeGetSocketOption , SetSocketOption (..) , unsafeSetSocketOption , Error (..) , ReuseAddress (..) ) where import Control.Concurrent.MVar import Control.Exception import Control.Monad import Control.Applicative import Foreign.Ptr import Foreign.Storable import Foreign.C.Types import Foreign.Marshal.Alloc import System.Posix.Types import System.Socket.Internal.Platform import System.Socket.Internal.Exception {-# LINE 26 "src/System/Socket/Internal/Socket.hsc" #-} -- | A generic socket type. Also see `socket` for details. -- -- The socket is just an `Control.Concurrent.MVar.MVar`-wrapped file descriptor. -- It is exposed in order to make this library easily extensible, but it is -- usually not necessary nor advised to work directly on the file descriptor. -- If you do, the following rules must be obeyed: -- -- - Make sure not to deadlock. Use `Control.Concurrent.MVar.withMVar` or similar. -- - The lock __must not__ be held during a blocking call. This would make it impossible -- to send and receive simultaneously or to close the socket. -- - The lock __must__ be held when calling operations that use the file descriptor. -- Otherwise the socket might get closed or even reused by another -- thread/capability which might result in reading from or writing -- totally different connection. This is a security nightmare! -- - The socket is non-blocking and all the code relies on that assumption. -- You need to use GHC's eventing mechanism primitives to block until -- something happens. The former rules forbid to use `GHC.Conc.threadWaitRead` as it -- does not seperate between registering the file descriptor (for which -- the lock __must__ be held) and the actual waiting (for which you must -- __not__ hold the lock). -- Also see [this](https://mail.haskell.org/pipermail/haskell-cafe/2014-September/115823.html) -- thread and read the library code to see how the problem is currently circumvented. newtype Socket f t p = Socket (MVar Fd) class GetSocketOption o where getSocketOption :: Socket f t p -> IO o class SetSocketOption o where setSocketOption :: Socket f t p -> o -> IO () -- | @SO_ERROR@ data Error = Error SocketException deriving (Eq, Ord, Show) instance GetSocketOption Error where getSocketOption s = Error . SocketException <$> unsafeGetSocketOption s (1) (4) {-# LINE 66 "src/System/Socket/Internal/Socket.hsc" #-} -- | @SO_REUSEADDR@ data ReuseAddress = ReuseAddress Bool deriving (Eq, Ord, Show) instance GetSocketOption ReuseAddress where getSocketOption s = ReuseAddress . ((/=0) :: CInt -> Bool) <$> unsafeGetSocketOption s (1) (2) {-# LINE 75 "src/System/Socket/Internal/Socket.hsc" #-} instance SetSocketOption ReuseAddress where setSocketOption s (ReuseAddress o) = unsafeSetSocketOption s (1) (2) (if o then 1 else 0 :: CInt) {-# LINE 79 "src/System/Socket/Internal/Socket.hsc" #-} ------------------------------------------------------------------------------- -- Unsafe helpers ------------------------------------------------------------------------------- unsafeSetSocketOption :: Storable a => Socket f t p -> CInt -> CInt -> a -> IO () unsafeSetSocketOption (Socket mfd) level name value = do withMVar mfd $ \fd-> alloca $ \vPtr-> do poke vPtr value i <- c_setsockopt fd level name vPtr (fromIntegral $ sizeOf value) when (i < 0) $ do c_get_last_socket_error >>= throwIO unsafeGetSocketOption :: Storable a => Socket f t p -> CInt -> CInt -> IO a unsafeGetSocketOption (Socket mfd) level name = do u <- return undefined withMVar mfd $ \fd-> alloca $ \vPtr-> do alloca $ \lPtr-> do poke lPtr (fromIntegral $ sizeOf u) i <- c_getsockopt fd level name vPtr (lPtr :: Ptr CInt) if i < 0 then do c_get_last_socket_error >>= throwIO else do x <- peek vPtr return (x `asTypeOf` u)