{-# LANGUAGE ExistentialQuantification, FlexibleInstances, GeneralizedNewtypeDeriving, MultiParamTypeClasses, TypeSynonymInstances, DeriveDataTypeable #-} ----------------------------------------------------------------------------- -- | -- Module : XMonad.Core -- Copyright : (c) Spencer Janssen 2007 -- License : BSD3-style (see LICENSE) -- -- Maintainer : spencerjanssen@gmail.com -- Stability : unstable -- Portability : not portable, uses cunning newtype deriving -- -- The 'X' monad, a state monad transformer over 'IO', for the window -- manager state, and support routines. -- ----------------------------------------------------------------------------- module XMonad.Core ( X, WindowSet, WindowSpace, WorkspaceId, ScreenId(..), ScreenDetail(..), XState(..), XConf(..), XConfig(..), LayoutClass(..), Layout(..), readsLayout, Typeable, Message, SomeMessage(..), fromMessage, LayoutMessages(..), StateExtension(..), ExtensionClass(..), runX, catchX, userCode, userCodeDef, io, catchIO, installSignalHandlers, uninstallSignalHandlers, withDisplay, withWindowSet, isRoot, runOnWorkspaces, getAtom, spawn, spawnPID, xfork, recompile, trace, whenJust, whenX, getXMonadDir, getXMonadCacheDir, getXMonadDataDir, stateFileName, atom_WM_STATE, atom_WM_PROTOCOLS, atom_WM_DELETE_WINDOW, atom_WM_TAKE_FOCUS, withWindowAttributes, ManageHook, Query(..), runQuery ) where import XMonad.StackSet hiding (modify) import Prelude import Control.Exception.Extensible (fromException, try, bracket, throw, finally, SomeException(..)) import qualified Control.Exception.Extensible as E import Control.Applicative(Applicative, pure, (<$>), (<*>)) import Control.Monad.Fail import Control.Monad.State import Control.Monad.Reader import Data.Semigroup import Data.Default import System.FilePath import System.IO import System.Info import System.Posix.Env (getEnv) import System.Posix.Process (executeFile, forkProcess, getAnyProcessStatus, createSession) import System.Posix.Signals import System.Posix.IO import System.Posix.Types (ProcessID) import System.Process import System.Directory import System.Exit import Graphics.X11.Xlib import Graphics.X11.Xlib.Extras (getWindowAttributes, WindowAttributes, Event) import Data.Typeable import Data.List ((\\)) import Data.Maybe (isJust,fromMaybe) import Data.Monoid hiding ((<>)) import System.Environment (lookupEnv) import qualified Data.Map as M import qualified Data.Set as S -- | XState, the (mutable) window manager state. data XState = XState { windowset :: !WindowSet -- ^ workspace list , mapped :: !(S.Set Window) -- ^ the Set of mapped windows , waitingUnmap :: !(M.Map Window Int) -- ^ the number of expected UnmapEvents , dragging :: !(Maybe (Position -> Position -> X (), X ())) , numberlockMask :: !KeyMask -- ^ The numlock modifier , extensibleState :: !(M.Map String (Either String StateExtension)) -- ^ stores custom state information. -- -- The module "XMonad.Util.ExtensibleState" in xmonad-contrib -- provides additional information and a simple interface for using this. } -- | XConf, the (read-only) window manager configuration. data XConf = XConf { display :: Display -- ^ the X11 display , config :: !(XConfig Layout) -- ^ initial user configuration , theRoot :: !Window -- ^ the root window , normalBorder :: !Pixel -- ^ border color of unfocused windows , focusedBorder :: !Pixel -- ^ border color of the focused window , keyActions :: !(M.Map (KeyMask, KeySym) (X ())) -- ^ a mapping of key presses to actions , buttonActions :: !(M.Map (KeyMask, Button) (Window -> X ())) -- ^ a mapping of button presses to actions , mouseFocused :: !Bool -- ^ was refocus caused by mouse action? , mousePosition :: !(Maybe (Position, Position)) -- ^ position of the mouse according to -- the event currently being processed , currentEvent :: !(Maybe Event) -- ^ event currently being processed } -- todo, better name data XConfig l = XConfig { normalBorderColor :: !String -- ^ Non focused windows border color. Default: \"#dddddd\" , focusedBorderColor :: !String -- ^ Focused windows border color. Default: \"#ff0000\" , terminal :: !String -- ^ The preferred terminal application. Default: \"xterm\" , layoutHook :: !(l Window) -- ^ The available layouts , manageHook :: !ManageHook -- ^ The action to run when a new window is opened , handleEventHook :: !(Event -> X All) -- ^ Handle an X event, returns (All True) if the default handler -- should also be run afterwards. mappend should be used for combining -- event hooks in most cases. , workspaces :: ![String] -- ^ The list of workspaces' names , modMask :: !KeyMask -- ^ the mod modifier , keys :: !(XConfig Layout -> M.Map (ButtonMask,KeySym) (X ())) -- ^ The key binding: a map from key presses and actions , mouseBindings :: !(XConfig Layout -> M.Map (ButtonMask, Button) (Window -> X ())) -- ^ The mouse bindings , borderWidth :: !Dimension -- ^ The border width , logHook :: !(X ()) -- ^ The action to perform when the windows set is changed , startupHook :: !(X ()) -- ^ The action to perform on startup , focusFollowsMouse :: !Bool -- ^ Whether window entry events can change focus , clickJustFocuses :: !Bool -- ^ False to make a click which changes focus to be additionally passed to the window , clientMask :: !EventMask -- ^ The client events that xmonad is interested in , rootMask :: !EventMask -- ^ The root events that xmonad is interested in , handleExtraArgs :: !([String] -> XConfig Layout -> IO (XConfig Layout)) -- ^ Modify the configuration, complain about extra arguments etc. with arguments that are not handled by default } type WindowSet = StackSet WorkspaceId (Layout Window) Window ScreenId ScreenDetail type WindowSpace = Workspace WorkspaceId (Layout Window) Window -- | Virtual workspace indices type WorkspaceId = String -- | Physical screen indices newtype ScreenId = S Int deriving (Eq,Ord,Show,Read,Enum,Num,Integral,Real) -- | The 'Rectangle' with screen dimensions data ScreenDetail = SD { screenRect :: !Rectangle } deriving (Eq,Show, Read) ------------------------------------------------------------------------ -- | The X monad, 'ReaderT' and 'StateT' transformers over 'IO' -- encapsulating the window manager configuration and state, -- respectively. -- -- Dynamic components may be retrieved with 'get', static components -- with 'ask'. With newtype deriving we get readers and state monads -- instantiated on 'XConf' and 'XState' automatically. -- newtype X a = X (ReaderT XConf (StateT XState IO) a) deriving (Functor, Monad, MonadFail, MonadIO, MonadState XState, MonadReader XConf, Typeable) instance Applicative X where pure = return (<*>) = ap instance Semigroup a => Semigroup (X a) where (<>) = liftM2 (<>) instance (Monoid a) => Monoid (X a) where mempty = return mempty mappend = liftM2 mappend instance Default a => Default (X a) where def = return def type ManageHook = Query (Endo WindowSet) newtype Query a = Query (ReaderT Window X a) deriving (Functor, Applicative, Monad, MonadReader Window, MonadIO) runQuery :: Query a -> Window -> X a runQuery (Query m) w = runReaderT m w instance Semigroup a => Semigroup (Query a) where (<>) = liftM2 (<>) instance Monoid a => Monoid (Query a) where mempty = return mempty mappend = liftM2 mappend instance Default a => Default (Query a) where def = return def -- | Run the 'X' monad, given a chunk of 'X' monad code, and an initial state -- Return the result, and final state runX :: XConf -> XState -> X a -> IO (a, XState) runX c st (X a) = runStateT (runReaderT a c) st -- | Run in the 'X' monad, and in case of exception, and catch it and log it -- to stderr, and run the error case. catchX :: X a -> X a -> X a catchX job errcase = do st <- get c <- ask (a, s') <- io $ runX c st job `E.catch` \e -> case fromException e of Just x -> throw e `const` (x `asTypeOf` ExitSuccess) _ -> do hPrint stderr e; runX c st errcase put s' return a -- | Execute the argument, catching all exceptions. Either this function or -- 'catchX' should be used at all callsites of user customized code. userCode :: X a -> X (Maybe a) userCode a = catchX (Just `liftM` a) (return Nothing) -- | Same as userCode but with a default argument to return instead of using -- Maybe, provided for convenience. userCodeDef :: a -> X a -> X a userCodeDef defValue a = fromMaybe defValue `liftM` userCode a -- --------------------------------------------------------------------- -- Convenient wrappers to state -- | Run a monad action with the current display settings withDisplay :: (Display -> X a) -> X a withDisplay f = asks display >>= f -- | Run a monadic action with the current stack set withWindowSet :: (WindowSet -> X a) -> X a withWindowSet f = gets windowset >>= f -- | Safely access window attributes. withWindowAttributes :: Display -> Window -> (WindowAttributes -> X ()) -> X () withWindowAttributes dpy win f = do wa <- userCode (io $ getWindowAttributes dpy win) catchX (whenJust wa f) (return ()) -- | True if the given window is the root window isRoot :: Window -> X Bool isRoot w = (w==) <$> asks theRoot -- | Wrapper for the common case of atom internment getAtom :: String -> X Atom getAtom str = withDisplay $ \dpy -> io $ internAtom dpy str False -- | Common non-predefined atoms atom_WM_PROTOCOLS, atom_WM_DELETE_WINDOW, atom_WM_STATE, atom_WM_TAKE_FOCUS :: X Atom atom_WM_PROTOCOLS = getAtom "WM_PROTOCOLS" atom_WM_DELETE_WINDOW = getAtom "WM_DELETE_WINDOW" atom_WM_STATE = getAtom "WM_STATE" atom_WM_TAKE_FOCUS = getAtom "WM_TAKE_FOCUS" ------------------------------------------------------------------------ -- LayoutClass handling. See particular instances in Operations.hs -- | An existential type that can hold any object that is in 'Read' -- and 'LayoutClass'. data Layout a = forall l. (LayoutClass l a, Read (l a)) => Layout (l a) -- | Using the 'Layout' as a witness, parse existentially wrapped windows -- from a 'String'. readsLayout :: Layout a -> String -> [(Layout a, String)] readsLayout (Layout l) s = [(Layout (asTypeOf x l), rs) | (x, rs) <- reads s] -- | Every layout must be an instance of 'LayoutClass', which defines -- the basic layout operations along with a sensible default for each. -- -- Minimal complete definition: -- -- * 'runLayout' || (('doLayout' || 'pureLayout') && 'emptyLayout'), and -- -- * 'handleMessage' || 'pureMessage' -- -- You should also strongly consider implementing 'description', -- although it is not required. -- -- Note that any code which /uses/ 'LayoutClass' methods should only -- ever call 'runLayout', 'handleMessage', and 'description'! In -- other words, the only calls to 'doLayout', 'pureMessage', and other -- such methods should be from the default implementations of -- 'runLayout', 'handleMessage', and so on. This ensures that the -- proper methods will be used, regardless of the particular methods -- that any 'LayoutClass' instance chooses to define. class Show (layout a) => LayoutClass layout a where -- | By default, 'runLayout' calls 'doLayout' if there are any -- windows to be laid out, and 'emptyLayout' otherwise. Most -- instances of 'LayoutClass' probably do not need to implement -- 'runLayout'; it is only useful for layouts which wish to make -- use of more of the 'Workspace' information (for example, -- "XMonad.Layout.PerWorkspace"). runLayout :: Workspace WorkspaceId (layout a) a -> Rectangle -> X ([(a, Rectangle)], Maybe (layout a)) runLayout (Workspace _ l ms) r = maybe (emptyLayout l r) (doLayout l r) ms -- | Given a 'Rectangle' in which to place the windows, and a 'Stack' -- of windows, return a list of windows and their corresponding -- Rectangles. If an element is not given a Rectangle by -- 'doLayout', then it is not shown on screen. The order of -- windows in this list should be the desired stacking order. -- -- Also possibly return a modified layout (by returning @Just -- newLayout@), if this layout needs to be modified (e.g. if it -- keeps track of some sort of state). Return @Nothing@ if the -- layout does not need to be modified. -- -- Layouts which do not need access to the 'X' monad ('IO', window -- manager state, or configuration) and do not keep track of their -- own state should implement 'pureLayout' instead of 'doLayout'. doLayout :: layout a -> Rectangle -> Stack a -> X ([(a, Rectangle)], Maybe (layout a)) doLayout l r s = return (pureLayout l r s, Nothing) -- | This is a pure version of 'doLayout', for cases where we -- don't need access to the 'X' monad to determine how to lay out -- the windows, and we don't need to modify the layout itself. pureLayout :: layout a -> Rectangle -> Stack a -> [(a, Rectangle)] pureLayout _ r s = [(focus s, r)] -- | 'emptyLayout' is called when there are no windows. emptyLayout :: layout a -> Rectangle -> X ([(a, Rectangle)], Maybe (layout a)) emptyLayout _ _ = return ([], Nothing) -- | 'handleMessage' performs message handling. If -- 'handleMessage' returns @Nothing@, then the layout did not -- respond to the message and the screen is not refreshed. -- Otherwise, 'handleMessage' returns an updated layout and the -- screen is refreshed. -- -- Layouts which do not need access to the 'X' monad to decide how -- to handle messages should implement 'pureMessage' instead of -- 'handleMessage' (this restricts the risk of error, and makes -- testing much easier). handleMessage :: layout a -> SomeMessage -> X (Maybe (layout a)) handleMessage l = return . pureMessage l -- | Respond to a message by (possibly) changing our layout, but -- taking no other action. If the layout changes, the screen will -- be refreshed. pureMessage :: layout a -> SomeMessage -> Maybe (layout a) pureMessage _ _ = Nothing -- | This should be a human-readable string that is used when -- selecting layouts by name. The default implementation is -- 'show', which is in some cases a poor default. description :: layout a -> String description = show instance LayoutClass Layout Window where runLayout (Workspace i (Layout l) ms) r = fmap (fmap Layout) `fmap` runLayout (Workspace i l ms) r doLayout (Layout l) r s = fmap (fmap Layout) `fmap` doLayout l r s emptyLayout (Layout l) r = fmap (fmap Layout) `fmap` emptyLayout l r handleMessage (Layout l) = fmap (fmap Layout) . handleMessage l description (Layout l) = description l instance Show (Layout a) where show (Layout l) = show l -- | Based on ideas in /An Extensible Dynamically-Typed Hierarchy of -- Exceptions/, Simon Marlow, 2006. Use extensible messages to the -- 'handleMessage' handler. -- -- User-extensible messages must be a member of this class. -- class Typeable a => Message a -- | -- A wrapped value of some type in the 'Message' class. -- data SomeMessage = forall a. Message a => SomeMessage a -- | -- And now, unwrap a given, unknown 'Message' type, performing a (dynamic) -- type check on the result. -- fromMessage :: Message m => SomeMessage -> Maybe m fromMessage (SomeMessage m) = cast m -- X Events are valid Messages. instance Message Event -- | 'LayoutMessages' are core messages that all layouts (especially stateful -- layouts) should consider handling. data LayoutMessages = Hide -- ^ sent when a layout becomes non-visible | ReleaseResources -- ^ sent when xmonad is exiting or restarting deriving (Typeable, Eq) instance Message LayoutMessages -- --------------------------------------------------------------------- -- Extensible state -- -- | Every module must make the data it wants to store -- an instance of this class. -- -- Minimal complete definition: initialValue class Typeable a => ExtensionClass a where -- | Defines an initial value for the state extension initialValue :: a -- | Specifies whether the state extension should be -- persistent. Setting this method to 'PersistentExtension' -- will make the stored data survive restarts, but -- requires a to be an instance of Read and Show. -- -- It defaults to 'StateExtension', i.e. no persistence. extensionType :: a -> StateExtension extensionType = StateExtension -- | Existential type to store a state extension. data StateExtension = forall a. ExtensionClass a => StateExtension a -- ^ Non-persistent state extension | forall a. (Read a, Show a, ExtensionClass a) => PersistentExtension a -- ^ Persistent extension -- --------------------------------------------------------------------- -- | General utilities -- -- Lift an 'IO' action into the 'X' monad io :: MonadIO m => IO a -> m a io = liftIO -- | Lift an 'IO' action into the 'X' monad. If the action results in an 'IO' -- exception, log the exception to stderr and continue normal execution. catchIO :: MonadIO m => IO () -> m () catchIO f = io (f `E.catch` \(SomeException e) -> hPrint stderr e >> hFlush stderr) -- | spawn. Launch an external application. Specifically, it double-forks and -- runs the 'String' you pass as a command to \/bin\/sh. -- -- Note this function assumes your locale uses utf8. spawn :: MonadIO m => String -> m () spawn x = spawnPID x >> return () -- | Like 'spawn', but returns the 'ProcessID' of the launched application spawnPID :: MonadIO m => String -> m ProcessID spawnPID x = xfork $ executeFile "/bin/sh" False ["-c", x] Nothing -- | A replacement for 'forkProcess' which resets default signal handlers. xfork :: MonadIO m => IO () -> m ProcessID xfork x = io . forkProcess . finally nullStdin $ do uninstallSignalHandlers createSession x where nullStdin = do fd <- openFd "/dev/null" ReadOnly Nothing defaultFileFlags dupTo fd stdInput closeFd fd -- | This is basically a map function, running a function in the 'X' monad on -- each workspace with the output of that function being the modified workspace. runOnWorkspaces :: (WindowSpace -> X WindowSpace) -> X () runOnWorkspaces job = do ws <- gets windowset h <- mapM job $ hidden ws c:v <- mapM (\s -> (\w -> s { workspace = w}) <$> job (workspace s)) $ current ws : visible ws modify $ \s -> s { windowset = ws { current = c, visible = v, hidden = h } } -- | Return the path to the xmonad configuration directory. This -- directory is where user configuration files are stored (e.g, the -- xmonad.hs file). You may also create a @lib@ subdirectory in the -- configuration directory and the default recompile command will add -- it to the GHC include path. -- -- Several directories are considered. In order of -- preference: -- -- 1. The directory specified in the @XMONAD_CONFIG_DIR@ environment variable. -- 2. The @~\/.xmonad@ directory. -- 3. The @XDG_CONFIG_HOME/xmonad@ directory. -- -- The first directory that exists will be used. If none of the -- directories exist then (1) will be used if it is set, otherwise (2) -- will be used. Either way, a directory will be created if necessary. getXMonadDir :: MonadIO m => m String getXMonadDir = findFirstDirWithEnv "XMONAD_CONFIG_DIR" [ getAppUserDataDirectory "xmonad" , getXDGDirectory XDGConfig "xmonad" ] -- | Return the path to the xmonad cache directory. This directory is -- used to store temporary files that can easily be recreated. For -- example, the XPrompt history file. -- -- Several directories are considered. In order of preference: -- -- 1. The directory specified in the @XMONAD_CACHE_DIR@ environment variable. -- 2. The @~\/.xmonad@ directory. -- 3. The @XDG_CACHE_HOME/xmonad@ directory. -- -- The first directory that exists will be used. If none of the -- directories exist then (1) will be used if it is set, otherwise (2) -- will be used. Either way, a directory will be created if necessary. getXMonadCacheDir :: MonadIO m => m String getXMonadCacheDir = findFirstDirWithEnv "XMONAD_CACHE_DIR" [ getAppUserDataDirectory "xmonad" , getXDGDirectory XDGCache "xmonad" ] -- | Return the path to the xmonad data directory. This directory is -- used by XMonad to store data files such as the run-time state file -- and the configuration binary generated by GHC. -- -- Several directories are considered. In order of preference: -- -- 1. The directory specified in the @XMONAD_DATA_DIR@ environment variable. -- 2. The @~\/.xmonad@ directory. -- 3. The @XDG_DATA_HOME/xmonad@ directory. -- -- The first directory that exists will be used. If none of the -- directories exist then (1) will be used if it is set, otherwise (2) -- will be used. Either way, a directory will be created if necessary. getXMonadDataDir :: MonadIO m => m String getXMonadDataDir = findFirstDirWithEnv "XMONAD_DATA_DIR" [ getAppUserDataDirectory "xmonad" , getXDGDirectory XDGData "xmonad" ] -- | Helper function that will find the first existing directory and -- return its path. If none of the directories can be found, create -- and return the first from the list. If the list is empty this -- function returns the historical @~\/.xmonad@ directory. findFirstDirOf :: MonadIO m => [IO FilePath] -> m FilePath findFirstDirOf [] = findFirstDirOf [getAppUserDataDirectory "xmonad"] findFirstDirOf possibles = do found <- go possibles case found of Just path -> return path Nothing -> do primary <- io (head possibles) io (createDirectoryIfMissing True primary) return primary where go [] = return Nothing go (x:xs) = do dir <- io x exists <- io (doesDirectoryExist dir) if exists then return (Just dir) else go xs -- | Simple wrapper around @findFirstDirOf@ that allows the primary -- path to be specified by an environment variable. findFirstDirWithEnv :: MonadIO m => String -> [IO FilePath] -> m FilePath findFirstDirWithEnv envName paths = do envPath' <- io (getEnv envName) case envPath' of Nothing -> findFirstDirOf paths Just envPath -> findFirstDirOf (return envPath:paths) -- | Helper function to retrieve the various XDG directories. -- This has been based on the implementation shipped with GHC version 8.0.1 or -- higher. Put here to preserve compatibility with older GHC versions. getXDGDirectory :: XDGDirectory -> FilePath -> IO FilePath getXDGDirectory xdgDir suffix = normalise . ( suffix) <$> case xdgDir of XDGData -> get "XDG_DATA_HOME" ".local/share" XDGConfig -> get "XDG_CONFIG_HOME" ".config" XDGCache -> get "XDG_CACHE_HOME" ".cache" where get name fallback = do env <- lookupEnv name case env of Nothing -> fallback' Just path | isRelative path -> fallback' | otherwise -> return path where fallback' = ( fallback) <$> getHomeDirectory data XDGDirectory = XDGData | XDGConfig | XDGCache -- | Get the name of the file used to store the xmonad window state. stateFileName :: (Functor m, MonadIO m) => m FilePath stateFileName = ( "xmonad.state") <$> getXMonadDataDir -- | 'recompile force', recompile the xmonad configuration file when -- any of the following apply: -- -- * force is 'True' -- -- * the xmonad executable does not exist -- -- * the xmonad executable is older than xmonad.hs or any file in -- the @lib@ directory (under the configuration directory). -- -- The -i flag is used to restrict recompilation to the xmonad.hs file only, -- and any files in the aforementioned @lib@ directory. -- -- Compilation errors (if any) are logged to the @xmonad.errors@ file -- in the xmonad data directory. If GHC indicates failure with a -- non-zero exit code, an xmessage displaying that file is spawned. -- -- 'False' is returned if there are compilation errors. -- recompile :: MonadIO m => Bool -> m Bool recompile force = io $ do cfgdir <- getXMonadDir datadir <- getXMonadDataDir let binn = "xmonad-"++arch++"-"++os bin = datadir binn err = datadir "xmonad.errors" src = cfgdir "xmonad.hs" lib = cfgdir "lib" buildscript = cfgdir "build" libTs <- mapM getModTime . Prelude.filter isSource =<< allFiles lib srcT <- getModTime src binT <- getModTime bin useBuildscript <- do exists <- doesFileExist buildscript if exists then do isExe <- isExecutable buildscript if isExe then do trace $ "XMonad will use build script at " ++ show buildscript ++ " to recompile." return True else do trace $ unlines [ "XMonad will not use build script, because " ++ show buildscript ++ " is not executable." , "Suggested resolution to use it: chmod u+x " ++ show buildscript ] return False else do trace $ "XMonad will use ghc to recompile, because " ++ show buildscript ++ " does not exist." return False shouldRecompile <- if useBuildscript || force then return True else if any (binT <) (srcT : libTs) then do trace "XMonad doing recompile because some files have changed." return True else do trace "XMonad skipping recompile because it is not forced (e.g. via --recompile), and neither xmonad.hs nor any *.hs / *.lhs / *.hsc files in lib/ have been changed." return False if shouldRecompile then do -- temporarily disable SIGCHLD ignoring: uninstallSignalHandlers status <- bracket (openFile err WriteMode) hClose $ \errHandle -> waitForProcess =<< if useBuildscript then compileScript bin cfgdir buildscript errHandle else compileGHC bin cfgdir errHandle -- re-enable SIGCHLD: installSignalHandlers -- now, if it fails, run xmessage to let the user know: if status == ExitSuccess then trace "XMonad recompilation process exited with success!" else do ghcErr <- readFile err let msg = unlines $ ["Error detected while loading xmonad configuration file: " ++ src] ++ lines (if null ghcErr then show status else ghcErr) ++ ["","Please check the file for errors."] -- nb, the ordering of printing, then forking, is crucial due to -- lazy evaluation hPutStrLn stderr msg forkProcess $ executeFile "xmessage" True ["-default", "okay", replaceUnicode msg] Nothing return () return (status == ExitSuccess) else return True where getModTime f = E.catch (Just <$> getModificationTime f) (\(SomeException _) -> return Nothing) isSource = flip elem [".hs",".lhs",".hsc"] . takeExtension isExecutable f = E.catch (executable <$> getPermissions f) (\(SomeException _) -> return False) allFiles t = do let prep = map (t) . Prelude.filter (`notElem` [".",".."]) cs <- prep <$> E.catch (getDirectoryContents t) (\(SomeException _) -> return []) ds <- filterM doesDirectoryExist cs concat . ((cs \\ ds):) <$> mapM allFiles ds -- Replace some of the unicode symbols GHC uses in its output replaceUnicode = map $ \c -> case c of '\8226' -> '*' -- • '\8216' -> '`' -- ‘ '\8217' -> '`' -- ’ _ -> c compileGHC bin dir errHandle = runProcess "ghc" ["--make" , "xmonad.hs" , "-i" , "-ilib" , "-fforce-recomp" , "-main-is", "main" , "-v0" , "-o", bin ] (Just dir) Nothing Nothing Nothing (Just errHandle) compileScript bin dir script errHandle = runProcess script [bin] (Just dir) Nothing Nothing Nothing (Just errHandle) -- | Conditionally run an action, using a @Maybe a@ to decide. whenJust :: Monad m => Maybe a -> (a -> m ()) -> m () whenJust mg f = maybe (return ()) f mg -- | Conditionally run an action, using a 'X' event to decide whenX :: X Bool -> X () -> X () whenX a f = a >>= \b -> when b f -- | A 'trace' for the 'X' monad. Logs a string to stderr. The result may -- be found in your .xsession-errors file trace :: MonadIO m => String -> m () trace = io . hPutStrLn stderr -- | Ignore SIGPIPE to avoid termination when a pipe is full, and SIGCHLD to -- avoid zombie processes, and clean up any extant zombie processes. installSignalHandlers :: MonadIO m => m () installSignalHandlers = io $ do installHandler openEndedPipe Ignore Nothing installHandler sigCHLD Ignore Nothing (try :: IO a -> IO (Either SomeException a)) $ fix $ \more -> do x <- getAnyProcessStatus False False when (isJust x) more return () uninstallSignalHandlers :: MonadIO m => m () uninstallSignalHandlers = io $ do installHandler openEndedPipe Default Nothing installHandler sigCHLD Default Nothing return ()