{-# LANGUAGE Trustworthy #-} {-# LANGUAGE CPP , NoImplicitPrelude , BangPatterns #-} {-# OPTIONS_GHC -Wno-identities #-} -- Whether there are identities depends on the platform {-# OPTIONS_HADDOCK not-home #-} ----------------------------------------------------------------------------- -- | -- Module : GHC.IO.FD -- Copyright : (c) The University of Glasgow, 1994-2008 -- License : see libraries/base/LICENSE -- -- Maintainer : libraries@haskell.org -- Stability : internal -- Portability : non-portable -- -- Raw read/write operations on file descriptors -- ----------------------------------------------------------------------------- module GHC.IO.FD ( FD(..), openFile, mkFD, release, setNonBlockingMode, readRawBufferPtr, readRawBufferPtrNoBlock, writeRawBufferPtr, stdin, stdout, stderr ) where import GHC.Base import GHC.Num import GHC.Real import GHC.Show import GHC.Enum import GHC.IO import GHC.IO.IOMode import GHC.IO.Buffer import GHC.IO.BufferedIO import qualified GHC.IO.Device import GHC.IO.Device (SeekMode(..), IODeviceType(..)) import GHC.Conc.IO import GHC.IO.Exception #if defined(mingw32_HOST_OS) import GHC.Windows import Data.Bool import GHC.IO.SubSystem (()) #endif import Foreign import Foreign.C import qualified System.Posix.Internals import System.Posix.Internals hiding (FD, setEcho, getEcho) import System.Posix.Types #if defined(mingw32_HOST_OS) # if defined(i386_HOST_ARCH) # define WINDOWS_CCONV stdcall # elif defined(x86_64_HOST_ARCH) # define WINDOWS_CCONV ccall # else # error Unknown mingw32 arch # endif #endif c_DEBUG_DUMP :: Bool c_DEBUG_DUMP = False -- Darwin limits the length of writes to 2GB. See #17414. -- Moreover, Linux will only transfer up to 0x7ffff000 and interpreting the -- result of write/read is tricky above 2GB due to its signed type. For -- simplicity we therefore clamp on all platforms. clampWriteSize, clampReadSize :: Int -> Int clampWriteSize = min 0x7ffff000 clampReadSize = min 0x7ffff000 -- ----------------------------------------------------------------------------- -- The file-descriptor IO device data FD = FD { fdFD :: {-# UNPACK #-} !CInt, #if defined(mingw32_HOST_OS) -- On Windows, a socket file descriptor needs to be read and written -- using different functions (send/recv). fdIsSocket_ :: {-# UNPACK #-} !Int #else -- On Unix we need to know whether this FD has O_NONBLOCK set. -- If it has, then we can use more efficient routines to read/write to it. -- It is always safe for this to be off. fdIsNonBlocking :: {-# UNPACK #-} !Int #endif } #if defined(mingw32_HOST_OS) fdIsSocket :: FD -> Bool fdIsSocket fd = fdIsSocket_ fd /= 0 #endif -- | @since 4.1.0.0 instance Show FD where show fd = show (fdFD fd) {-# INLINE ifSupported #-} ifSupported :: String -> a -> a #if defined(mingw32_HOST_OS) ifSupported s a = a (error $ "FD:" ++ s ++ " not supported") #else ifSupported _ = id #endif -- | @since 4.1.0.0 instance GHC.IO.Device.RawIO FD where read = ifSupported "fdRead" fdRead readNonBlocking = ifSupported "fdReadNonBlocking" fdReadNonBlocking write = ifSupported "fdWrite" fdWrite writeNonBlocking = ifSupported "fdWriteNonBlocking" fdWriteNonBlocking -- | @since 4.1.0.0 instance GHC.IO.Device.IODevice FD where ready = ifSupported "ready" ready close = ifSupported "close" close isTerminal = ifSupported "isTerm" isTerminal isSeekable = ifSupported "isSeek" isSeekable seek = ifSupported "seek" seek tell = ifSupported "tell" tell getSize = ifSupported "getSize" getSize setSize = ifSupported "setSize" setSize setEcho = ifSupported "setEcho" setEcho getEcho = ifSupported "getEcho" getEcho setRaw = ifSupported "setRaw" setRaw devType = ifSupported "devType" devType dup = ifSupported "dup" dup dup2 = ifSupported "dup2" dup2 -- We used to use System.Posix.Internals.dEFAULT_BUFFER_SIZE, which is -- taken from the value of BUFSIZ on the current platform. This value -- varies too much though: it is 512 on Windows, 1024 on OS X and 8192 -- on Linux. So let's just use a decent size on every platform: dEFAULT_FD_BUFFER_SIZE :: Int dEFAULT_FD_BUFFER_SIZE = 8192 -- | @since 4.1.0.0 instance BufferedIO FD where newBuffer _dev state = ifSupported "newBuf" $ newByteBuffer dEFAULT_FD_BUFFER_SIZE state fillReadBuffer fd buf = ifSupported "readBuf" $ readBuf' fd buf fillReadBuffer0 fd buf = ifSupported "readBufNonBlock" $ readBufNonBlocking fd buf flushWriteBuffer fd buf = ifSupported "writeBuf" $ writeBuf' fd buf flushWriteBuffer0 fd buf = ifSupported "writeBufNonBlock" $ writeBufNonBlocking fd buf readBuf' :: FD -> Buffer Word8 -> IO (Int, Buffer Word8) readBuf' fd buf = do when c_DEBUG_DUMP $ puts ("readBuf fd=" ++ show fd ++ " " ++ summaryBuffer buf ++ "\n") (r,buf') <- readBuf fd buf when c_DEBUG_DUMP $ puts ("after: " ++ summaryBuffer buf' ++ "\n") return (r,buf') writeBuf' :: FD -> Buffer Word8 -> IO (Buffer Word8) writeBuf' fd buf = do when c_DEBUG_DUMP $ puts ("writeBuf fd=" ++ show fd ++ " " ++ summaryBuffer buf ++ "\n") writeBuf fd buf -- ----------------------------------------------------------------------------- -- opening files -- | Open a file and make an 'FD' for it. Truncates the file to zero -- size when the `IOMode` is `WriteMode`. openFile :: FilePath -- ^ file to open -> IOMode -- ^ mode in which to open the file -> Bool -- ^ open the file in non-blocking mode? -> IO (FD,IODeviceType) openFile filepath iomode non_blocking = withFilePath filepath $ \ f -> let oflags1 = case iomode of ReadMode -> read_flags WriteMode -> write_flags ReadWriteMode -> rw_flags AppendMode -> append_flags #if defined(mingw32_HOST_OS) binary_flags = o_BINARY #else binary_flags = 0 #endif oflags2 = oflags1 .|. binary_flags oflags | non_blocking = oflags2 .|. nonblock_flags | otherwise = oflags2 in do -- NB. always use a safe open(), because we don't know whether open() -- will be fast or not. It can be slow on NFS and FUSE filesystems, -- for example. fd <- throwErrnoIfMinus1Retry "openFile" $ c_safe_open f oflags 0o666 (fD,fd_type) <- mkFD fd iomode Nothing{-no stat-} False{-not a socket-} non_blocking `catchAny` \e -> do _ <- c_close fd throwIO e -- we want to truncate() if this is an open in WriteMode, but only -- if the target is a RegularFile. ftruncate() fails on special files -- like /dev/null. when (iomode == WriteMode && fd_type == RegularFile) $ setSize fD 0 return (fD,fd_type) std_flags, output_flags, read_flags, write_flags, rw_flags, append_flags, nonblock_flags :: CInt std_flags = o_NOCTTY output_flags = std_flags .|. o_CREAT read_flags = std_flags .|. o_RDONLY write_flags = output_flags .|. o_WRONLY rw_flags = output_flags .|. o_RDWR append_flags = write_flags .|. o_APPEND nonblock_flags = o_NONBLOCK -- | Make a 'FD' from an existing file descriptor. Fails if the FD -- refers to a directory. If the FD refers to a file, `mkFD` locks -- the file according to the Haskell 2010 single writer/multiple reader -- locking semantics (this is why we need the `IOMode` argument too). mkFD :: CInt -> IOMode -> Maybe (IODeviceType, CDev, CIno) -- the results of fdStat if we already know them, or we want -- to prevent fdToHandle_stat from doing its own stat. -- These are used for: -- - we fail if the FD refers to a directory -- - if the FD refers to a file, we lock it using (cdev,cino) -> Bool -- ^ is a socket (on Windows) -> Bool -- ^ is in non-blocking mode on Unix -> IO (FD,IODeviceType) mkFD fd iomode mb_stat is_socket is_nonblock = do let _ = (is_socket, is_nonblock) -- warning suppression (fd_type,dev,ino) <- case mb_stat of Nothing -> fdStat fd Just stat -> return stat let write = case iomode of ReadMode -> False _ -> True case fd_type of Directory -> ioException (IOError Nothing InappropriateType "openFile" "is a directory" Nothing Nothing) -- regular files need to be locked RegularFile -> do -- On Windows we need an additional call to get a unique device id -- and inode, since fstat just returns 0 for both. -- See also Note [RTS File locking] (unique_dev, unique_ino) <- getUniqueFileInfo fd dev ino r <- lockFile (fromIntegral fd) unique_dev unique_ino (fromBool write) when (r == -1) $ ioException (IOError Nothing ResourceBusy "openFile" "file is locked" Nothing Nothing) _other_type -> return () #if defined(mingw32_HOST_OS) when (not is_socket) $ setmode fd True >> return () #endif return (FD{ fdFD = fd, #if !defined(mingw32_HOST_OS) fdIsNonBlocking = fromEnum is_nonblock #else fdIsSocket_ = fromEnum is_socket #endif }, fd_type) getUniqueFileInfo :: CInt -> CDev -> CIno -> IO (Word64, Word64) #if !defined(mingw32_HOST_OS) getUniqueFileInfo _ dev ino = return (fromIntegral dev, fromIntegral ino) #else getUniqueFileInfo fd _ _ = do with 0 $ \devptr -> do with 0 $ \inoptr -> do c_getUniqueFileInfo fd devptr inoptr liftM2 (,) (peek devptr) (peek inoptr) #endif #if defined(mingw32_HOST_OS) foreign import ccall unsafe "__hscore_setmode" setmode :: CInt -> Bool -> IO CInt #endif -- ----------------------------------------------------------------------------- -- Standard file descriptors stdFD :: CInt -> FD stdFD fd = FD { fdFD = fd, #if defined(mingw32_HOST_OS) fdIsSocket_ = 0 #else fdIsNonBlocking = 0 -- We don't set non-blocking mode on standard handles, because it may -- confuse other applications attached to the same TTY/pipe -- see Note [nonblock] #endif } stdin, stdout, stderr :: FD stdin = stdFD 0 stdout = stdFD 1 stderr = stdFD 2 -- ----------------------------------------------------------------------------- -- Operations on file descriptors close :: FD -> IO () close fd = do let closer realFd = throwErrnoIfMinus1Retry_ "GHC.IO.FD.close" $ #if defined(mingw32_HOST_OS) if fdIsSocket fd then c_closesocket (fromIntegral realFd) else #endif c_close (fromIntegral realFd) -- release the lock *first*, because otherwise if we're preempted -- after closing but before releasing, the FD may have been reused. -- (#7646) release fd closeFdWith closer (fromIntegral (fdFD fd)) release :: FD -> IO () release fd = do _ <- unlockFile (fromIntegral $ fdFD fd) return () #if defined(mingw32_HOST_OS) foreign import WINDOWS_CCONV unsafe "HsBase.h closesocket" c_closesocket :: CInt -> IO CInt #endif isSeekable :: FD -> IO Bool isSeekable fd = do t <- devType fd return (t == RegularFile || t == RawDevice) seek :: FD -> SeekMode -> Integer -> IO Integer seek fd mode off = fromIntegral `fmap` (throwErrnoIfMinus1Retry "seek" $ c_lseek (fdFD fd) (fromIntegral off) seektype) where seektype :: CInt seektype = case mode of AbsoluteSeek -> sEEK_SET RelativeSeek -> sEEK_CUR SeekFromEnd -> sEEK_END tell :: FD -> IO Integer tell fd = fromIntegral `fmap` (throwErrnoIfMinus1Retry "hGetPosn" $ c_lseek (fdFD fd) 0 sEEK_CUR) getSize :: FD -> IO Integer getSize fd = fdFileSize (fdFD fd) setSize :: FD -> Integer -> IO () setSize fd size = do throwErrnoIf_ (/=0) "GHC.IO.FD.setSize" $ c_ftruncate (fdFD fd) (fromIntegral size) devType :: FD -> IO IODeviceType devType fd = do (ty,_,_) <- fdStat (fdFD fd); return ty dup :: FD -> IO FD dup fd = do newfd <- throwErrnoIfMinus1 "GHC.IO.FD.dup" $ c_dup (fdFD fd) return fd{ fdFD = newfd } dup2 :: FD -> FD -> IO FD dup2 fd fdto = do -- Windows' dup2 does not return the new descriptor, unlike Unix throwErrnoIfMinus1_ "GHC.IO.FD.dup2" $ c_dup2 (fdFD fd) (fdFD fdto) return fd{ fdFD = fdFD fdto } -- original FD, with the new fdFD setNonBlockingMode :: FD -> Bool -> IO FD setNonBlockingMode fd set = do setNonBlockingFD (fdFD fd) set #if defined(mingw32_HOST_OS) return fd #else return fd{ fdIsNonBlocking = fromEnum set } #endif ready :: FD -> Bool -> Int -> IO Bool ready fd write msecs = do r <- throwErrnoIfMinus1Retry "GHC.IO.FD.ready" $ fdReady (fdFD fd) (fromIntegral $ fromEnum $ write) (fromIntegral msecs) #if defined(mingw32_HOST_OS) (fromIntegral $ fromEnum $ fdIsSocket fd) #else 0 #endif return (toEnum (fromIntegral r)) foreign import ccall safe "fdReady" fdReady :: CInt -> CBool -> Int64 -> CBool -> IO CInt -- --------------------------------------------------------------------------- -- Terminal-related stuff isTerminal :: FD -> IO Bool isTerminal fd = #if defined(mingw32_HOST_OS) if fdIsSocket fd then return False else is_console (fdFD fd) >>= return.toBool #else c_isatty (fdFD fd) >>= return.toBool #endif setEcho :: FD -> Bool -> IO () setEcho fd on = System.Posix.Internals.setEcho (fdFD fd) on getEcho :: FD -> IO Bool getEcho fd = System.Posix.Internals.getEcho (fdFD fd) setRaw :: FD -> Bool -> IO () setRaw fd raw = System.Posix.Internals.setCooked (fdFD fd) (not raw) -- ----------------------------------------------------------------------------- -- Reading and Writing fdRead :: FD -> Ptr Word8 -> Word64 -> Int -> IO Int fdRead fd ptr _offset bytes = do { r <- readRawBufferPtr "GHC.IO.FD.fdRead" fd ptr 0 (fromIntegral $ clampReadSize bytes) ; return (fromIntegral r) } fdReadNonBlocking :: FD -> Ptr Word8 -> Word64 -> Int -> IO (Maybe Int) fdReadNonBlocking fd ptr _offset bytes = do r <- readRawBufferPtrNoBlock "GHC.IO.FD.fdReadNonBlocking" fd ptr 0 (fromIntegral $ clampReadSize bytes) case fromIntegral r of (-1) -> return (Nothing) n -> return (Just n) fdWrite :: FD -> Ptr Word8 -> Word64 -> Int -> IO () fdWrite fd ptr _offset bytes = do res <- writeRawBufferPtr "GHC.IO.FD.fdWrite" fd ptr 0 (fromIntegral $ clampWriteSize bytes) let res' = fromIntegral res if res' < bytes then fdWrite fd (ptr `plusPtr` res') (_offset + fromIntegral res') (bytes - res') else return () -- XXX ToDo: this isn't non-blocking fdWriteNonBlocking :: FD -> Ptr Word8 -> Word64 -> Int -> IO Int fdWriteNonBlocking fd ptr _offset bytes = do res <- writeRawBufferPtrNoBlock "GHC.IO.FD.fdWriteNonBlocking" fd ptr 0 (fromIntegral $ clampWriteSize bytes) return (fromIntegral res) -- ----------------------------------------------------------------------------- -- FD operations -- Low level routines for reading/writing to (raw)buffers: #if !defined(mingw32_HOST_OS) {- NOTE [nonblock]: Unix has broken semantics when it comes to non-blocking I/O: you can set the O_NONBLOCK flag on an FD, but it applies to the all other FDs attached to the same underlying file, pipe or TTY; there's no way to have private non-blocking behaviour for an FD. See bug #724. We fix this by only setting O_NONBLOCK on FDs that we create; FDs that come from external sources or are exposed externally are left in blocking mode. This solution has some problems though. We can't completely simulate a non-blocking read without O_NONBLOCK: several cases are wrong here. The cases that are wrong: * reading/writing to a blocking FD in non-threaded mode. In threaded mode, we just make a safe call to read(). In non-threaded mode we call select() before attempting to read, but that leaves a small race window where the data can be read from the file descriptor before we issue our blocking read(). * readRawBufferNoBlock for a blocking FD NOTE [2363]: In the threaded RTS we could just make safe calls to read()/write() for file descriptors in blocking mode without worrying about blocking other threads, but the problem with this is that the thread will be uninterruptible while it is blocked in the foreign call. See #2363. So now we always call fdReady() before reading, and if fdReady indicates that there's no data, we call threadWaitRead. -} readRawBufferPtr :: String -> FD -> Ptr Word8 -> Int -> CSize -> IO Int readRawBufferPtr loc !fd !buf !off !len | isNonBlocking fd = unsafe_read -- unsafe is ok, it can't block | otherwise = do r <- throwErrnoIfMinus1 loc (unsafe_fdReady (fdFD fd) 0 0 0) if r /= 0 then read else do threadWaitRead (fromIntegral (fdFD fd)); read where do_read call = fromIntegral `fmap` throwErrnoIfMinus1RetryMayBlock loc call (threadWaitRead (fromIntegral (fdFD fd))) read = if threaded then safe_read else unsafe_read unsafe_read = do_read (c_read (fdFD fd) (buf `plusPtr` off) len) safe_read = do_read (c_safe_read (fdFD fd) (buf `plusPtr` off) len) -- return: -1 indicates EOF, >=0 is bytes read readRawBufferPtrNoBlock :: String -> FD -> Ptr Word8 -> Int -> CSize -> IO Int readRawBufferPtrNoBlock loc !fd !buf !off !len | isNonBlocking fd = unsafe_read -- unsafe is ok, it can't block | otherwise = do r <- unsafe_fdReady (fdFD fd) 0 0 0 if r /= 0 then safe_read else return 0 -- XXX see note [nonblock] where do_read call = do r <- throwErrnoIfMinus1RetryOnBlock loc call (return (-1)) case r of (-1) -> return 0 0 -> return (-1) n -> return (fromIntegral n) unsafe_read = do_read (c_read (fdFD fd) (buf `plusPtr` off) len) safe_read = do_read (c_safe_read (fdFD fd) (buf `plusPtr` off) len) writeRawBufferPtr :: String -> FD -> Ptr Word8 -> Int -> CSize -> IO CInt writeRawBufferPtr loc !fd !buf !off !len | isNonBlocking fd = unsafe_write -- unsafe is ok, it can't block | otherwise = do r <- unsafe_fdReady (fdFD fd) 1 0 0 if r /= 0 then write else do threadWaitWrite (fromIntegral (fdFD fd)); write where do_write call = fromIntegral `fmap` throwErrnoIfMinus1RetryMayBlock loc call (threadWaitWrite (fromIntegral (fdFD fd))) write = if threaded then safe_write else unsafe_write unsafe_write = do_write (c_write (fdFD fd) (buf `plusPtr` off) len) safe_write = do_write (c_safe_write (fdFD fd) (buf `plusPtr` off) len) writeRawBufferPtrNoBlock :: String -> FD -> Ptr Word8 -> Int -> CSize -> IO CInt writeRawBufferPtrNoBlock loc !fd !buf !off !len | isNonBlocking fd = unsafe_write -- unsafe is ok, it can't block | otherwise = do r <- unsafe_fdReady (fdFD fd) 1 0 0 if r /= 0 then write else return 0 where do_write call = do r <- throwErrnoIfMinus1RetryOnBlock loc call (return (-1)) case r of (-1) -> return 0 n -> return (fromIntegral n) write = if threaded then safe_write else unsafe_write unsafe_write = do_write (c_write (fdFD fd) (buf `plusPtr` off) len) safe_write = do_write (c_safe_write (fdFD fd) (buf `plusPtr` off) len) isNonBlocking :: FD -> Bool isNonBlocking fd = fdIsNonBlocking fd /= 0 foreign import ccall unsafe "fdReady" unsafe_fdReady :: CInt -> CBool -> Int64 -> CBool -> IO CInt #else /* mingw32_HOST_OS.... */ readRawBufferPtr :: String -> FD -> Ptr Word8 -> Int -> CSize -> IO CInt readRawBufferPtr loc !fd !buf !off !len | threaded = blockingReadRawBufferPtr loc fd buf off len | otherwise = asyncReadRawBufferPtr loc fd buf off len writeRawBufferPtr :: String -> FD -> Ptr Word8 -> Int -> CSize -> IO CInt writeRawBufferPtr loc !fd !buf !off !len | threaded = blockingWriteRawBufferPtr loc fd buf off len | otherwise = asyncWriteRawBufferPtr loc fd buf off len readRawBufferPtrNoBlock :: String -> FD -> Ptr Word8 -> Int -> CSize -> IO CInt readRawBufferPtrNoBlock = readRawBufferPtr writeRawBufferPtrNoBlock :: String -> FD -> Ptr Word8 -> Int -> CSize -> IO CInt writeRawBufferPtrNoBlock = writeRawBufferPtr -- Async versions of the read/write primitives, for the non-threaded RTS asyncReadRawBufferPtr :: String -> FD -> Ptr Word8 -> Int -> CSize -> IO CInt asyncReadRawBufferPtr loc !fd !buf !off !len = do (l, rc) <- asyncRead (fromIntegral (fdFD fd)) (fdIsSocket_ fd) (fromIntegral len) (buf `plusPtr` off) if l == (-1) then let sock_errno = c_maperrno_func (fromIntegral rc) non_sock_errno = Errno (fromIntegral rc) errno = bool non_sock_errno sock_errno (fdIsSocket fd) in ioError (errnoToIOError loc errno Nothing Nothing) else return (fromIntegral l) asyncWriteRawBufferPtr :: String -> FD -> Ptr Word8 -> Int -> CSize -> IO CInt asyncWriteRawBufferPtr loc !fd !buf !off !len = do (l, rc) <- asyncWrite (fromIntegral (fdFD fd)) (fdIsSocket_ fd) (fromIntegral len) (buf `plusPtr` off) if l == (-1) then let sock_errno = c_maperrno_func (fromIntegral rc) non_sock_errno = Errno (fromIntegral rc) errno = bool non_sock_errno sock_errno (fdIsSocket fd) in ioError (errnoToIOError loc errno Nothing Nothing) else return (fromIntegral l) -- Blocking versions of the read/write primitives, for the threaded RTS blockingReadRawBufferPtr :: String -> FD -> Ptr Word8 -> Int -> CSize -> IO CInt blockingReadRawBufferPtr loc !fd !buf !off !len = throwErrnoIfMinus1Retry loc $ do let start_ptr = buf `plusPtr` off recv_ret = c_safe_recv (fdFD fd) start_ptr (fromIntegral len) 0 read_ret = c_safe_read (fdFD fd) start_ptr (fromIntegral len) r <- bool read_ret recv_ret (fdIsSocket fd) when ((fdIsSocket fd) && (r == -1)) c_maperrno return r -- We trust read() to give us the correct errno but recv(), as a -- Winsock function, doesn't do the errno conversion so if the fd -- is for a socket, we do it from GetLastError() ourselves. blockingWriteRawBufferPtr :: String -> FD -> Ptr Word8-> Int -> CSize -> IO CInt blockingWriteRawBufferPtr loc !fd !buf !off !len = throwErrnoIfMinus1Retry loc $ do let start_ptr = buf `plusPtr` off send_ret = c_safe_send (fdFD fd) start_ptr (fromIntegral len) 0 write_ret = c_safe_write (fdFD fd) start_ptr (fromIntegral len) r <- bool write_ret send_ret (fdIsSocket fd) when (r == -1) c_maperrno return r -- We don't trust write() to give us the correct errno, and -- instead do the errno conversion from GetLastError() -- ourselves. The main reason is that we treat ERROR_NO_DATA -- (pipe is closing) as EPIPE, whereas write() returns EINVAL -- for this case. We need to detect EPIPE correctly, because it -- shouldn't be reported as an error when it happens on stdout. -- As for send()'s case, Winsock functions don't do errno -- conversion in any case so we have to do it ourselves. -- That means we're doing the errno conversion no matter if the -- fd is from a socket or not. -- NOTE: "safe" versions of the read/write calls for use by the threaded RTS. -- These calls may block, but that's ok. foreign import WINDOWS_CCONV safe "recv" c_safe_recv :: CInt -> Ptr Word8 -> CInt -> CInt{-flags-} -> IO CInt foreign import WINDOWS_CCONV safe "send" c_safe_send :: CInt -> Ptr Word8 -> CInt -> CInt{-flags-} -> IO CInt #endif foreign import ccall unsafe "rtsSupportsBoundThreads" threaded :: Bool -- ----------------------------------------------------------------------------- -- utils #if !defined(mingw32_HOST_OS) throwErrnoIfMinus1RetryOnBlock :: String -> IO CSsize -> IO CSsize -> IO CSsize throwErrnoIfMinus1RetryOnBlock loc f on_block = do res <- f if (res :: CSsize) == -1 then do err <- getErrno if err == eINTR then throwErrnoIfMinus1RetryOnBlock loc f on_block else if err == eWOULDBLOCK || err == eAGAIN then do on_block else throwErrno loc else return res #endif -- ----------------------------------------------------------------------------- -- Locking/unlocking foreign import ccall unsafe "lockFile" lockFile :: Word64 -> Word64 -> Word64 -> CInt -> IO CInt foreign import ccall unsafe "unlockFile" unlockFile :: Word64 -> IO CInt #if defined(mingw32_HOST_OS) foreign import ccall unsafe "get_unique_file_info" c_getUniqueFileInfo :: CInt -> Ptr Word64 -> Ptr Word64 -> IO () #endif