{-# LANGUAGE CPP, ForeignFunctionInterface #-} #if __GLASGOW_HASKELL__ >= 709 {-# LANGUAGE Safe #-} #else {-# LANGUAGE Trustworthy #-} #endif {-# LANGUAGE InterruptibleFFI #-} ----------------------------------------------------------------------------- -- | -- Module : System.Process -- Copyright : (c) The University of Glasgow 2004-2008 -- License : BSD-style (see the file libraries/base/LICENSE) -- -- Maintainer : libraries@haskell.org -- Stability : experimental -- Portability : non-portable (requires concurrency) -- -- Operations for creating and interacting with sub-processes. -- ----------------------------------------------------------------------------- -- ToDo: -- * Flag to control whether exiting the parent also kills the child. module System.Process ( -- * Running sub-processes createProcess, createProcess_, shell, proc, CreateProcess(..), CmdSpec(..), StdStream(..), ProcessHandle, -- ** Simpler functions for common tasks callProcess, callCommand, spawnProcess, spawnCommand, readCreateProcess, readProcess, readCreateProcessWithExitCode, readProcessWithExitCode, withCreateProcess, cleanupProcess, -- ** Related utilities showCommandForUser, Pid, getPid, -- ** Control-C handling on Unix -- $ctlc-handling -- * Process completion waitForProcess, getProcessExitCode, terminateProcess, interruptProcessGroupOf, -- Interprocess communication createPipe, createPipeFd, -- * Old deprecated functions -- | These functions pre-date 'createProcess' which is much more -- flexible. runProcess, runCommand, runInteractiveProcess, runInteractiveCommand, system, rawSystem, ) where import Prelude hiding (mapM) import System.Process.Internals import Control.Concurrent import Control.DeepSeq (rnf) import Control.Exception (SomeException, mask, allowInterrupt, bracket, try, throwIO) import qualified Control.Exception as C import Control.Monad import Data.Maybe import Foreign import Foreign.C import System.Exit ( ExitCode(..) ) import System.IO import System.IO.Error (mkIOError, ioeSetErrorString) #if defined(WINDOWS) import System.Win32.Process (getProcessId, ProcessId) #else import System.Posix.Types (CPid (..)) #endif import GHC.IO.Exception ( ioException, IOErrorType(..), IOException(..) ) -- | The platform specific type for a process identifier. -- -- This is always an integral type. Width and signedness are platform specific. -- -- @since 1.6.3.0 #if defined(WINDOWS) type Pid = ProcessId #else type Pid = CPid #endif -- ---------------------------------------------------------------------------- -- createProcess -- | Construct a 'CreateProcess' record for passing to 'createProcess', -- representing a raw command with arguments. -- -- See 'RawCommand' for precise semantics of the specified @FilePath@. proc :: FilePath -> [String] -> CreateProcess proc cmd args = CreateProcess { cmdspec = RawCommand cmd args, cwd = Nothing, env = Nothing, std_in = Inherit, std_out = Inherit, std_err = Inherit, close_fds = False, create_group = False, delegate_ctlc = False, detach_console = False, create_new_console = False, new_session = False, child_group = Nothing, child_user = Nothing, use_process_jobs = False } -- | Construct a 'CreateProcess' record for passing to 'createProcess', -- representing a command to be passed to the shell. shell :: String -> CreateProcess shell str = CreateProcess { cmdspec = ShellCommand str, cwd = Nothing, env = Nothing, std_in = Inherit, std_out = Inherit, std_err = Inherit, close_fds = False, create_group = False, delegate_ctlc = False, detach_console = False, create_new_console = False, new_session = False, child_group = Nothing, child_user = Nothing, use_process_jobs = False } {- | This is the most general way to spawn an external process. The process can be a command line to be executed by a shell or a raw command with a list of arguments. The stdin, stdout, and stderr streams of the new process may individually be attached to new pipes, to existing 'Handle's, or just inherited from the parent (the default.) The details of how to create the process are passed in the 'CreateProcess' record. To make it easier to construct a 'CreateProcess', the functions 'proc' and 'shell' are supplied that fill in the fields with default values which can be overriden as needed. 'createProcess' returns @(/mb_stdin_hdl/, /mb_stdout_hdl/, /mb_stderr_hdl/, /ph/)@, where * if @'std_in' == 'CreatePipe'@, then @/mb_stdin_hdl/@ will be @Just /h/@, where @/h/@ is the write end of the pipe connected to the child process's @stdin@. * otherwise, @/mb_stdin_hdl/ == Nothing@ Similarly for @/mb_stdout_hdl/@ and @/mb_stderr_hdl/@. For example, to execute a simple @ls@ command: > r <- createProcess (proc "ls" []) To create a pipe from which to read the output of @ls@: > (_, Just hout, _, _) <- > createProcess (proc "ls" []){ std_out = CreatePipe } To also set the directory in which to run @ls@: > (_, Just hout, _, _) <- > createProcess (proc "ls" []){ cwd = Just "\home\bob", > std_out = CreatePipe } Note that @Handle@s provided for @std_in@, @std_out@, or @std_err@ via the @UseHandle@ constructor will be closed by calling this function. This is not always the desired behavior. In cases where you would like to leave the @Handle@ open after spawning the child process, please use 'createProcess_' instead. All created @Handle@s are initially in text mode; if you need them to be in binary mode then use 'hSetBinaryMode'. -} createProcess :: CreateProcess -> IO (Maybe Handle, Maybe Handle, Maybe Handle, ProcessHandle) createProcess cp = do r <- createProcess_ "createProcess" cp maybeCloseStd (std_in cp) maybeCloseStd (std_out cp) maybeCloseStd (std_err cp) return r where maybeCloseStd :: StdStream -> IO () maybeCloseStd (UseHandle hdl) | hdl /= stdin && hdl /= stdout && hdl /= stderr = hClose hdl maybeCloseStd _ = return () -- | A 'C.bracket'-style resource handler for 'createProcess'. -- -- Does automatic cleanup when the action finishes. If there is an exception -- in the body then it ensures that the process gets terminated and any -- 'CreatePipe' 'Handle's are closed. In particular this means that if the -- Haskell thread is killed (e.g. 'killThread'), that the external process is -- also terminated. -- -- e.g. -- -- > withCreateProcess (proc cmd args) { ... } $ \stdin stdout stderr ph -> do -- > ... -- -- @since 1.4.3.0 withCreateProcess :: CreateProcess -> (Maybe Handle -> Maybe Handle -> Maybe Handle -> ProcessHandle -> IO a) -> IO a withCreateProcess c action = C.bracket (createProcess c) cleanupProcess (\(m_in, m_out, m_err, ph) -> action m_in m_out m_err ph) -- wrapper so we can get exceptions with the appropriate function name. withCreateProcess_ :: String -> CreateProcess -> (Maybe Handle -> Maybe Handle -> Maybe Handle -> ProcessHandle -> IO a) -> IO a withCreateProcess_ fun c action = C.bracketOnError (createProcess_ fun c) cleanupProcess (\(m_in, m_out, m_err, ph) -> action m_in m_out m_err ph) -- | Cleans up the process. -- -- This function is meant to be invoked from any application level cleanup -- handler. It terminates the process, and closes any 'CreatePipe' 'handle's. -- -- @since 1.6.4.0 cleanupProcess :: (Maybe Handle, Maybe Handle, Maybe Handle, ProcessHandle) -> IO () cleanupProcess (mb_stdin, mb_stdout, mb_stderr, ph@(ProcessHandle _ delegating_ctlc _)) = do terminateProcess ph -- Note, it's important that other threads that might be reading/writing -- these handles also get killed off, since otherwise they might be holding -- the handle lock and prevent us from closing, leading to deadlock. maybe (return ()) (ignoreSigPipe . hClose) mb_stdin maybe (return ()) hClose mb_stdout maybe (return ()) hClose mb_stderr -- terminateProcess does not guarantee that it terminates the process. -- Indeed on Unix it's SIGTERM, which asks nicely but does not guarantee -- that it stops. If it doesn't stop, we don't want to hang, so we wait -- asynchronously using forkIO. -- However we want to end the Ctl-C handling synchronously, so we'll do -- that synchronously, and set delegating_ctlc as False for the -- waitForProcess (which would otherwise end the Ctl-C delegation itself). when delegating_ctlc stopDelegateControlC _ <- forkIO (waitForProcess (resetCtlcDelegation ph) >> return ()) return () where resetCtlcDelegation (ProcessHandle m _ l) = ProcessHandle m False l -- ---------------------------------------------------------------------------- -- spawnProcess/spawnCommand -- | Creates a new process to run the specified raw command with the given -- arguments. It does not wait for the program to finish, but returns the -- 'ProcessHandle'. -- -- @since 1.2.0.0 spawnProcess :: FilePath -> [String] -> IO ProcessHandle spawnProcess cmd args = do (_,_,_,p) <- createProcess_ "spawnProcess" (proc cmd args) return p -- | Creates a new process to run the specified shell command. -- It does not wait for the program to finish, but returns the 'ProcessHandle'. -- -- @since 1.2.0.0 spawnCommand :: String -> IO ProcessHandle spawnCommand cmd = do (_,_,_,p) <- createProcess_ "spawnCommand" (shell cmd) return p -- ---------------------------------------------------------------------------- -- callProcess/callCommand -- | Creates a new process to run the specified command with the given -- arguments, and wait for it to finish. If the command returns a non-zero -- exit code, an exception is raised. -- -- If an asynchronous exception is thrown to the thread executing -- @callProcess@, the forked process will be terminated and -- @callProcess@ will wait (block) until the process has been -- terminated. -- -- @since 1.2.0.0 callProcess :: FilePath -> [String] -> IO () callProcess cmd args = do exit_code <- withCreateProcess_ "callProcess" (proc cmd args) { delegate_ctlc = True } $ \_ _ _ p -> waitForProcess p case exit_code of ExitSuccess -> return () ExitFailure r -> processFailedException "callProcess" cmd args r -- | Creates a new process to run the specified shell command. If the -- command returns a non-zero exit code, an exception is raised. -- -- If an asynchronous exception is thrown to the thread executing -- @callCommand@, the forked process will be terminated and -- @callCommand@ will wait (block) until the process has been -- terminated. -- -- @since 1.2.0.0 callCommand :: String -> IO () callCommand cmd = do exit_code <- withCreateProcess_ "callCommand" (shell cmd) { delegate_ctlc = True } $ \_ _ _ p -> waitForProcess p case exit_code of ExitSuccess -> return () ExitFailure r -> processFailedException "callCommand" cmd [] r processFailedException :: String -> String -> [String] -> Int -> IO a processFailedException fun cmd args exit_code = ioError (mkIOError OtherError (fun ++ ": " ++ cmd ++ concatMap ((' ':) . show) args ++ " (exit " ++ show exit_code ++ ")") Nothing Nothing) -- ---------------------------------------------------------------------------- -- Control-C handling on Unix -- $ctlc-handling -- -- When running an interactive console process (such as a shell, console-based -- text editor or ghci), we typically want that process to be allowed to handle -- Ctl-C keyboard interrupts how it sees fit. For example, while most programs -- simply quit on a Ctl-C, some handle it specially. To allow this to happen, -- use the @'delegate_ctlc' = True@ option in the 'CreateProcess' options. -- -- The gory details: -- -- By default Ctl-C will generate a @SIGINT@ signal, causing a 'UserInterrupt' -- exception to be sent to the main Haskell thread of your program, which if -- not specially handled will terminate the program. Normally, this is exactly -- what is wanted: an orderly shutdown of the program in response to Ctl-C. -- -- Of course when running another interactive program in the console then we -- want to let that program handle Ctl-C. Under Unix however, Ctl-C sends -- @SIGINT@ to every process using the console. The standard solution is that -- while running an interactive program, ignore @SIGINT@ in the parent, and let -- it be handled in the child process. If that process then terminates due to -- the @SIGINT@ signal, then at that point treat it as if we had recieved the -- @SIGINT@ ourselves and begin an orderly shutdown. -- -- This behaviour is implemented by 'createProcess' (and -- 'waitForProcess' \/ 'getProcessExitCode') when the @'delegate_ctlc' = True@ -- option is set. In particular, the @SIGINT@ signal will be ignored until -- 'waitForProcess' returns (or 'getProcessExitCode' returns a non-Nothing -- result), so it becomes especially important to use 'waitForProcess' for every -- processes created. -- -- In addition, in 'delegate_ctlc' mode, 'waitForProcess' and -- 'getProcessExitCode' will throw a 'UserInterrupt' exception if the process -- terminated with @'ExitFailure' (-SIGINT)@. Typically you will not want to -- catch this exception, but let it propagate, giving a normal orderly shutdown. -- One detail to be aware of is that the 'UserInterrupt' exception is thrown -- /synchronously/ in the thread that calls 'waitForProcess', whereas normally -- @SIGINT@ causes the exception to be thrown /asynchronously/ to the main -- thread. -- -- For even more detail on this topic, see -- <http://www.cons.org/cracauer/sigint.html "Proper handling of SIGINT/SIGQUIT">. -- ----------------------------------------------------------------------------- -- | @readProcess@ forks an external process, reads its standard output -- strictly, blocking until the process terminates, and returns the output -- string. The external process inherits the standard error. -- -- If an asynchronous exception is thrown to the thread executing -- @readProcess@, the forked process will be terminated and @readProcess@ will -- wait (block) until the process has been terminated. -- -- Output is returned strictly, so this is not suitable for -- interactive applications. -- -- This function throws an 'IOError' if the process 'ExitCode' is -- anything other than 'ExitSuccess'. If instead you want to get the -- 'ExitCode' then use 'readProcessWithExitCode'. -- -- Users of this function should compile with @-threaded@ if they -- want other Haskell threads to keep running while waiting on -- the result of readProcess. -- -- > > readProcess "date" [] [] -- > "Thu Feb 7 10:03:39 PST 2008\n" -- -- The arguments are: -- -- * The command to run, which must be in the $PATH, or an absolute or relative path -- -- * A list of separate command line arguments to the program -- -- * A string to pass on standard input to the forked process. -- readProcess :: FilePath -- ^ Filename of the executable (see 'RawCommand' for details) -> [String] -- ^ any arguments -> String -- ^ standard input -> IO String -- ^ stdout readProcess cmd args = readCreateProcess $ proc cmd args -- | @readCreateProcess@ works exactly like 'readProcess' except that it -- lets you pass 'CreateProcess' giving better flexibility. -- -- > > readCreateProcess (shell "pwd" { cwd = "/etc/" }) "" -- > "/etc\n" -- -- Note that @Handle@s provided for @std_in@ or @std_out@ via the CreateProcess -- record will be ignored. -- -- @since 1.2.3.0 readCreateProcess :: CreateProcess -> String -- ^ standard input -> IO String -- ^ stdout readCreateProcess cp input = do let cp_opts = cp { std_in = CreatePipe, std_out = CreatePipe } (ex, output) <- withCreateProcess_ "readCreateProcess" cp_opts $ \(Just inh) (Just outh) _ ph -> do -- fork off a thread to start consuming the output output <- hGetContents outh withForkWait (C.evaluate $ rnf output) $ \waitOut -> do -- now write any input unless (null input) $ ignoreSigPipe $ hPutStr inh input -- hClose performs implicit hFlush, and thus may trigger a SIGPIPE ignoreSigPipe $ hClose inh -- wait on the output waitOut hClose outh -- wait on the process ex <- waitForProcess ph return (ex, output) case ex of ExitSuccess -> return output ExitFailure r -> processFailedException "readCreateProcess" cmd args r where cmd = case cp of CreateProcess { cmdspec = ShellCommand sc } -> sc CreateProcess { cmdspec = RawCommand fp _ } -> fp args = case cp of CreateProcess { cmdspec = ShellCommand _ } -> [] CreateProcess { cmdspec = RawCommand _ args' } -> args' -- | @readProcessWithExitCode@ is like @readProcess@ but with two differences: -- -- * it returns the 'ExitCode' of the process, and does not throw any -- exception if the code is not 'ExitSuccess'. -- -- * it reads and returns the output from process' standard error handle, -- rather than the process inheriting the standard error handle. -- -- On Unix systems, see 'waitForProcess' for the meaning of exit codes -- when the process died as the result of a signal. -- readProcessWithExitCode :: FilePath -- ^ Filename of the executable (see 'RawCommand' for details) -> [String] -- ^ any arguments -> String -- ^ standard input -> IO (ExitCode,String,String) -- ^ exitcode, stdout, stderr readProcessWithExitCode cmd args = readCreateProcessWithExitCode $ proc cmd args -- | @readCreateProcessWithExitCode@ works exactly like 'readProcessWithExitCode' except that it -- lets you pass 'CreateProcess' giving better flexibility. -- -- Note that @Handle@s provided for @std_in@, @std_out@, or @std_err@ via the CreateProcess -- record will be ignored. -- -- @since 1.2.3.0 readCreateProcessWithExitCode :: CreateProcess -> String -- ^ standard input -> IO (ExitCode,String,String) -- ^ exitcode, stdout, stderr readCreateProcessWithExitCode cp input = do let cp_opts = cp { std_in = CreatePipe, std_out = CreatePipe, std_err = CreatePipe } withCreateProcess_ "readCreateProcessWithExitCode" cp_opts $ \(Just inh) (Just outh) (Just errh) ph -> do out <- hGetContents outh err <- hGetContents errh -- fork off threads to start consuming stdout & stderr withForkWait (C.evaluate $ rnf out) $ \waitOut -> withForkWait (C.evaluate $ rnf err) $ \waitErr -> do -- now write any input unless (null input) $ ignoreSigPipe $ hPutStr inh input -- hClose performs implicit hFlush, and thus may trigger a SIGPIPE ignoreSigPipe $ hClose inh -- wait on the output waitOut waitErr hClose outh hClose errh -- wait on the process ex <- waitForProcess ph return (ex, out, err) -- | Fork a thread while doing something else, but kill it if there's an -- exception. -- -- This is important in the cases above because we want to kill the thread -- that is holding the Handle lock, because when we clean up the process we -- try to close that handle, which could otherwise deadlock. -- withForkWait :: IO () -> (IO () -> IO a) -> IO a withForkWait async body = do waitVar <- newEmptyMVar :: IO (MVar (Either SomeException ())) mask $ \restore -> do tid <- forkIO $ try (restore async) >>= putMVar waitVar let wait = takeMVar waitVar >>= either throwIO return restore (body wait) `C.onException` killThread tid ignoreSigPipe :: IO () -> IO () ignoreSigPipe = C.handle $ \e -> case e of IOError { ioe_type = ResourceVanished , ioe_errno = Just ioe } | Errno ioe == ePIPE -> return () _ -> throwIO e -- ---------------------------------------------------------------------------- -- showCommandForUser -- | Given a program @/p/@ and arguments @/args/@, -- @showCommandForUser /p/ /args/@ returns a string suitable for pasting -- into @\/bin\/sh@ (on Unix systems) or @CMD.EXE@ (on Windows). showCommandForUser :: FilePath -> [String] -> String showCommandForUser cmd args = unwords (map translate (cmd : args)) -- ---------------------------------------------------------------------------- -- getPid -- | Returns the PID (process ID) of a subprocess. -- -- 'Nothing' is returned if the handle was already closed. Otherwise a -- PID is returned that remains valid as long as the handle is open. -- The operating system may reuse the PID as soon as the last handle to -- the process is closed. -- -- @since 1.6.3.0 getPid :: ProcessHandle -> IO (Maybe Pid) getPid (ProcessHandle mh _ _) = do p_ <- readMVar mh case p_ of #ifdef WINDOWS OpenHandle h -> do pid <- getProcessId h return $ Just pid #else OpenHandle pid -> return $ Just pid #endif _ -> return Nothing -- ---------------------------------------------------------------------------- -- waitForProcess {- | Waits for the specified process to terminate, and returns its exit code. GHC Note: in order to call @waitForProcess@ without blocking all the other threads in the system, you must compile the program with @-threaded@. (/Since: 1.2.0.0/) On Unix systems, a negative value @'ExitFailure' -/signum/@ indicates that the child was terminated by signal @/signum/@. The signal numbers are platform-specific, so to test for a specific signal use the constants provided by "System.Posix.Signals" in the @unix@ package. Note: core dumps are not reported, use "System.Posix.Process" if you need this detail. -} waitForProcess :: ProcessHandle -> IO ExitCode waitForProcess ph@(ProcessHandle _ delegating_ctlc _) = lockWaitpid $ do p_ <- modifyProcessHandle ph $ \p_ -> return (p_,p_) case p_ of ClosedHandle e -> return e OpenHandle h -> do e <- alloca $ \pret -> do -- don't hold the MVar while we call c_waitForProcess... throwErrnoIfMinus1Retry_ "waitForProcess" (allowInterrupt >> c_waitForProcess h pret) modifyProcessHandle ph $ \p_' -> case p_' of ClosedHandle e -> return (p_', e) OpenExtHandle{} -> return (p_', ExitFailure (-1)) OpenHandle ph' -> do closePHANDLE ph' code <- peek pret let e = if (code == 0) then ExitSuccess else (ExitFailure (fromIntegral code)) return (ClosedHandle e, e) when delegating_ctlc $ endDelegateControlC e return e #if defined(WINDOWS) OpenExtHandle _ job iocp -> maybe (ExitFailure (-1)) mkExitCode `fmap` waitForJobCompletion job iocp timeout_Infinite where mkExitCode code | code == 0 = ExitSuccess | otherwise = ExitFailure $ fromIntegral code #else OpenExtHandle _ _job _iocp -> return $ ExitFailure (-1) #endif where -- If more than one thread calls `waitpid` at a time, `waitpid` will -- return the exit code to one of them and (-1) to the rest of them, -- causing an exception to be thrown. -- Cf. https://github.com/haskell/process/issues/46, and -- https://github.com/haskell/process/pull/58 for further discussion lockWaitpid m = withMVar (waitpidLock ph) $ \() -> m -- ---------------------------------------------------------------------------- -- getProcessExitCode {- | This is a non-blocking version of 'waitForProcess'. If the process is still running, 'Nothing' is returned. If the process has exited, then @'Just' e@ is returned where @e@ is the exit code of the process. On Unix systems, see 'waitForProcess' for the meaning of exit codes when the process died as the result of a signal. -} getProcessExitCode :: ProcessHandle -> IO (Maybe ExitCode) getProcessExitCode ph@(ProcessHandle _ delegating_ctlc _) = tryLockWaitpid $ do (m_e, was_open) <- modifyProcessHandle ph $ \p_ -> case p_ of ClosedHandle e -> return (p_, (Just e, False)) open -> do alloca $ \pExitCode -> do case getHandle open of Nothing -> return (p_, (Nothing, False)) Just h -> do res <- throwErrnoIfMinus1Retry "getProcessExitCode" $ c_getProcessExitCode h pExitCode code <- peek pExitCode if res == 0 then return (p_, (Nothing, False)) else do closePHANDLE h let e | code == 0 = ExitSuccess | otherwise = ExitFailure (fromIntegral code) return (ClosedHandle e, (Just e, True)) case m_e of Just e | was_open && delegating_ctlc -> endDelegateControlC e _ -> return () return m_e where getHandle :: ProcessHandle__ -> Maybe PHANDLE getHandle (OpenHandle h) = Just h getHandle (ClosedHandle _) = Nothing getHandle (OpenExtHandle h _ _) = Just h -- If somebody is currently holding the waitpid lock, we don't want to -- accidentally remove the pid from the process table. -- Try acquiring the waitpid lock. If it is held, we are done -- since that means the process is still running and we can return -- `Nothing`. If it is not held, acquire it so we can run the -- (non-blocking) call to `waitpid` without worrying about any -- other threads calling it at the same time. tryLockWaitpid :: IO (Maybe ExitCode) -> IO (Maybe ExitCode) tryLockWaitpid action = bracket acquire release between where acquire = tryTakeMVar (waitpidLock ph) release m = case m of Nothing -> return () Just () -> putMVar (waitpidLock ph) () between m = case m of Nothing -> return Nothing Just () -> action -- ---------------------------------------------------------------------------- -- terminateProcess -- | Attempts to terminate the specified process. This function should -- not be used under normal circumstances - no guarantees are given regarding -- how cleanly the process is terminated. To check whether the process -- has indeed terminated, use 'getProcessExitCode'. -- -- On Unix systems, 'terminateProcess' sends the process the SIGTERM signal. -- On Windows systems, if `use_process_jobs` is `True` then the Win32 @TerminateJobObject@ -- function is called to kill all processes associated with the job and passing the -- exit code of 1 to each of them. Otherwise if `use_process_jobs` is `False` then the -- Win32 @TerminateProcess@ function is called, passing an exit code of 1. -- -- Note: on Windows, if the process was a shell command created by -- 'createProcess' with 'shell', or created by 'runCommand' or -- 'runInteractiveCommand', then 'terminateProcess' will only -- terminate the shell, not the command itself. On Unix systems, both -- processes are in a process group and will be terminated together. terminateProcess :: ProcessHandle -> IO () terminateProcess ph = do withProcessHandle ph $ \p_ -> case p_ of ClosedHandle _ -> return () #if defined(WINDOWS) OpenExtHandle{} -> terminateJob ph 1 >> return () #else OpenExtHandle{} -> error "terminateProcess with OpenExtHandle should not happen on POSIX." #endif OpenHandle h -> do throwErrnoIfMinus1Retry_ "terminateProcess" $ c_terminateProcess h return () -- does not close the handle, we might want to try terminating it -- again, or get its exit code. -- ---------------------------------------------------------------------------- -- Interface to C bits foreign import ccall unsafe "terminateProcess" c_terminateProcess :: PHANDLE -> IO CInt foreign import ccall unsafe "getProcessExitCode" c_getProcessExitCode :: PHANDLE -> Ptr CInt -> IO CInt foreign import ccall interruptible "waitForProcess" -- NB. safe - can block c_waitForProcess :: PHANDLE -> Ptr CInt -> IO CInt -- ---------------------------------------------------------------------------- -- Old deprecated variants -- ---------------------------------------------------------------------------- -- TODO: We're not going to mark these functions as DEPRECATED immediately in -- process-1.2.0.0. That's because some of their replacements have not been -- around for all that long. But they should eventually be marked with a -- suitable DEPRECATED pragma after a release or two. -- ---------------------------------------------------------------------------- -- runCommand --TODO: in a later release {-# DEPRECATED runCommand "Use 'spawnCommand' instead" #-} {- | Runs a command using the shell. -} runCommand :: String -> IO ProcessHandle runCommand string = do (_,_,_,ph) <- createProcess_ "runCommand" (shell string) return ph -- ---------------------------------------------------------------------------- -- runProcess --TODO: in a later release {-# DEPRECATED runProcess "Use 'spawnProcess' or 'createProcess' instead" #-} {- | Runs a raw command, optionally specifying 'Handle's from which to take the @stdin@, @stdout@ and @stderr@ channels for the new process (otherwise these handles are inherited from the current process). Any 'Handle's passed to 'runProcess' are placed immediately in the closed state. Note: consider using the more general 'createProcess' instead of 'runProcess'. -} runProcess :: FilePath -- ^ Filename of the executable (see 'RawCommand' for details) -> [String] -- ^ Arguments to pass to the executable -> Maybe FilePath -- ^ Optional path to the working directory -> Maybe [(String,String)] -- ^ Optional environment (otherwise inherit) -> Maybe Handle -- ^ Handle to use for @stdin@ (Nothing => use existing @stdin@) -> Maybe Handle -- ^ Handle to use for @stdout@ (Nothing => use existing @stdout@) -> Maybe Handle -- ^ Handle to use for @stderr@ (Nothing => use existing @stderr@) -> IO ProcessHandle runProcess cmd args mb_cwd mb_env mb_stdin mb_stdout mb_stderr = do (_,_,_,ph) <- createProcess_ "runProcess" (proc cmd args){ cwd = mb_cwd, env = mb_env, std_in = mbToStd mb_stdin, std_out = mbToStd mb_stdout, std_err = mbToStd mb_stderr } maybeClose mb_stdin maybeClose mb_stdout maybeClose mb_stderr return ph where maybeClose :: Maybe Handle -> IO () maybeClose (Just hdl) | hdl /= stdin && hdl /= stdout && hdl /= stderr = hClose hdl maybeClose _ = return () mbToStd :: Maybe Handle -> StdStream mbToStd Nothing = Inherit mbToStd (Just hdl) = UseHandle hdl -- ---------------------------------------------------------------------------- -- runInteractiveCommand --TODO: in a later release {-# DEPRECATED runInteractiveCommand "Use 'createProcess' instead" #-} {- | Runs a command using the shell, and returns 'Handle's that may be used to communicate with the process via its @stdin@, @stdout@, and @stderr@ respectively. -} runInteractiveCommand :: String -> IO (Handle,Handle,Handle,ProcessHandle) runInteractiveCommand string = runInteractiveProcess1 "runInteractiveCommand" (shell string) -- ---------------------------------------------------------------------------- -- runInteractiveProcess --TODO: in a later release {-# DEPRECATED runInteractiveCommand "Use 'createProcess' instead" #-} {- | Runs a raw command, and returns 'Handle's that may be used to communicate with the process via its @stdin@, @stdout@ and @stderr@ respectively. For example, to start a process and feed a string to its stdin: > (inp,out,err,pid) <- runInteractiveProcess "..." > forkIO (hPutStr inp str) -} runInteractiveProcess :: FilePath -- ^ Filename of the executable (see 'RawCommand' for details) -> [String] -- ^ Arguments to pass to the executable -> Maybe FilePath -- ^ Optional path to the working directory -> Maybe [(String,String)] -- ^ Optional environment (otherwise inherit) -> IO (Handle,Handle,Handle,ProcessHandle) runInteractiveProcess cmd args mb_cwd mb_env = do runInteractiveProcess1 "runInteractiveProcess" (proc cmd args){ cwd = mb_cwd, env = mb_env } runInteractiveProcess1 :: String -> CreateProcess -> IO (Handle,Handle,Handle,ProcessHandle) runInteractiveProcess1 fun cmd = do (mb_in, mb_out, mb_err, p) <- createProcess_ fun cmd{ std_in = CreatePipe, std_out = CreatePipe, std_err = CreatePipe } return (fromJust mb_in, fromJust mb_out, fromJust mb_err, p) -- --------------------------------------------------------------------------- -- system & rawSystem --TODO: in a later release {-# DEPRECATED system "Use 'callCommand' (or 'spawnCommand' and 'waitForProcess') instead" #-} {-| Computation @system cmd@ returns the exit code produced when the operating system runs the shell command @cmd@. This computation may fail with one of the following 'System.IO.Error.IOErrorType' exceptions: [@PermissionDenied@] The process has insufficient privileges to perform the operation. [@ResourceExhausted@] Insufficient resources are available to perform the operation. [@UnsupportedOperation@] The implementation does not support system calls. On Windows, 'system' passes the command to the Windows command interpreter (@CMD.EXE@ or @COMMAND.COM@), hence Unixy shell tricks will not work. On Unix systems, see 'waitForProcess' for the meaning of exit codes when the process died as the result of a signal. -} system :: String -> IO ExitCode system "" = ioException (ioeSetErrorString (mkIOError InvalidArgument "system" Nothing Nothing) "null command") system str = do (_,_,_,p) <- createProcess_ "system" (shell str) { delegate_ctlc = True } waitForProcess p --TODO: in a later release {-# DEPRECATED rawSystem "Use 'callProcess' (or 'spawnProcess' and 'waitForProcess') instead" #-} {-| The computation @'rawSystem' /cmd/ /args/@ runs the operating system command @/cmd/@ in such a way that it receives as arguments the @/args/@ strings exactly as given, with no funny escaping or shell meta-syntax expansion. It will therefore behave more portably between operating systems than 'system'. The return codes and possible failures are the same as for 'system'. -} rawSystem :: String -> [String] -> IO ExitCode rawSystem cmd args = do (_,_,_,p) <- createProcess_ "rawSystem" (proc cmd args) { delegate_ctlc = True } waitForProcess p