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{-# LANGUAGE ExistentialQuantification, FlexibleInstances, GeneralizedNewtypeDeriving,
MultiParamTypeClasses, TypeSynonymInstances #-}
-- required for deriving Typeable
{-# OPTIONS_GHC -fglasgow-exts #-}
-----------------------------------------------------------------------------
-- |
-- Module : XMonad.Core
-- Copyright : (c) Spencer Janssen 2007
-- License : BSD3-style (see LICENSE)
--
-- Maintainer : sjanssen@cse.unl.edu
-- 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, runLayout, LayoutMessages(..),
runX, catchX, userCode, io, catchIO,
withDisplay, withWindowSet, isRoot, runOnWorkspaces, broadcastMessage,
getAtom, spawn, restart, getXMonadDir, recompile, trace, whenJust, whenX,
atom_WM_STATE, atom_WM_PROTOCOLS, atom_WM_DELETE_WINDOW, ManageHook, Query(..), runManageHook
) where
import XMonad.StackSet hiding (modify)
import Prelude hiding ( catch )
import Control.Exception (catch, bracket, throw, Exception(ExitException))
import Control.Applicative
import Control.Monad.State
import Control.Monad.Reader
import System.IO
import System.Info
import System.Posix.Process (executeFile, forkProcess, getProcessStatus, createSession)
import System.Process
import System.Directory
import System.Exit
import Graphics.X11.Xlib
import Graphics.X11.Xlib.Extras (Event)
import Data.Typeable
import Data.Monoid
import qualified Data.Map as M
import qualified Data.Set as S
-- | XState, the window manager state.
-- Just the display, width, height and a window list
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 ())) }
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
}
-- 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 avaiable layouts
, manageHook :: !ManageHook
-- ^ The action to run when a new window is opened
, workspaces :: [String] -- ^ The list of workspaces' names
, defaultGaps :: [(Int,Int,Int,Int)] -- ^ The list of gaps, per screen
, numlockMask :: !KeyMask -- ^ The numlock modifier
, 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
}
type WindowSet = StackSet WorkspaceId (Layout Window) Window ScreenId ScreenDetail
type WindowSpace = Workspace WorkspaceId (Layout Window) Window
-- | Virtual workspace indicies
type WorkspaceId = String
-- | Physical screen indicies
newtype ScreenId = S Int deriving (Eq,Ord,Show,Read,Enum,Num,Integral,Real)
-- | The 'Rectangle' with screen dimensions and the list of gaps
data ScreenDetail = SD { screenRect :: !Rectangle
, statusGap :: !(Int,Int,Int,Int) -- ^ width of status bar on the screen
} deriving (Eq,Show, Read)
------------------------------------------------------------------------
-- | The X monad, a StateT transformer over IO encapsulating the window
-- manager state
--
-- 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)
#ifndef __HADDOCK__
deriving (Functor, Monad, MonadIO, MonadState XState, MonadReader XConf)
#endif
instance (Monoid a) => Monoid (X a) where
mempty = return mempty
mappend = liftM2 mappend
type ManageHook = Query (Endo WindowSet)
newtype Query a = Query (ReaderT Window X a)
#ifndef __HADDOCK__
deriving (Functor, Monad, MonadReader Window, MonadIO)
#endif
runManageHook :: ManageHook -> Window -> X (WindowSet -> WindowSet)
runManageHook (Query m) w = appEndo <$> runReaderT m w
instance Monoid a => Monoid (Query a) where
mempty = return mempty
mappend = liftM2 mappend
-- | 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 `catch` \e -> case e of
ExitException {} -> throw e
_ -> 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 () -> X ()
userCode a = catchX (a >> return ()) (return ())
-- ---------------------------------------------------------------------
-- 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
-- | 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 :: X Atom
atom_WM_PROTOCOLS = getAtom "WM_PROTOCOLS"
atom_WM_DELETE_WINDOW = getAtom "WM_DELETE_WINDOW"
atom_WM_STATE = getAtom "WM_STATE"
------------------------------------------------------------------------
-- | 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]
-- | The different layout modes
--
-- 'doLayout': given a Rectangle and a Stack, layout the stack elements
-- inside the given Rectangle. If an element is not given a Rectangle
-- by 'doLayout', then it is not shown on screen. Windows are restacked
-- according to the order they are returned by 'doLayout'.
--
class Show (layout a) => LayoutClass layout a where
-- | Given a Rectangle in which to place the windows, and a Stack of
-- windows, return a list of windows and their corresponding Rectangles.
-- The order of windows in this list should be the desired stacking order.
-- Also return a modified layout, if this layout needs to be modified
-- (e.g. if we keep track of the windows we have displayed).
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 layout the windows, and
-- we don't need to modify our layout itself.
pureLayout :: layout a -> Rectangle -> Stack a -> [(a, Rectangle)]
pureLayout _ r s = [(focus s, r)]
-- | 'handleMessage' performs message handling for that layout. If
-- 'handleMessage' returns Nothing, then the layout did not respond to
-- that message and the screen is not refreshed. Otherwise, 'handleMessage'
-- returns an updated 'Layout' and the screen is refreshed.
--
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.
description :: layout a -> String
description = show
instance LayoutClass Layout Window where
doLayout (Layout l) r s = fmap (fmap Layout) `fmap` doLayout l r s
handleMessage (Layout l) = fmap (fmap Layout) . handleMessage l
description (Layout l) = description l
instance Show (Layout a) where show (Layout l) = show l
-- | This calls doLayout if there are any windows to be laid out.
runLayout :: LayoutClass l a => l a -> Rectangle -> Maybe (Stack a) -> X ([(a, Rectangle)], Maybe (l a))
runLayout l r = maybe (return ([], Nothing)) (doLayout l r)
-- | 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
-- ---------------------------------------------------------------------
-- | 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 :: IO () -> X ()
catchIO f = io (f `catch` \e -> hPrint stderr e >> hFlush stderr)
-- | spawn. Launch an external application
spawn :: MonadIO m => String -> m ()
spawn x = doubleFork $ executeFile "/bin/sh" False ["-c", x] Nothing
-- | Double fork and execute an IO action (usually one of the exec family of
-- functions)
doubleFork :: MonadIO m => IO () -> m ()
doubleFork m = io $ do
pid <- forkProcess $ do
forkProcess (createSession >> m)
exitWith ExitSuccess
getProcessStatus True False pid
return ()
-- | Send a message to all visible layouts, without necessarily refreshing.
-- This is how we implement the hooks, such as UnDoLayout.
broadcastMessage :: Message a => a -> X ()
broadcastMessage a = runOnWorkspaces $ \w -> do
ml' <- handleMessage (layout w) (SomeMessage a) `catchX` return Nothing
return $ w { layout = maybe (layout w) id ml' }
-- | 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 } }
-- | @restart name resume@. Attempt to restart xmonad by executing the program
-- @name@. If @resume@ is 'True', restart with the current window state.
-- When executing another window manager, @resume@ should be 'False'.
--
restart :: String -> Bool -> X ()
restart prog resume = do
broadcastMessage ReleaseResources
io . flush =<< asks display
args <- if resume then gets (("--resume":) . return . showWs . windowset) else return []
catchIO (executeFile prog True args Nothing)
where showWs = show . mapLayout show
-- | Return the path to @~\/.xmonad@.
getXMonadDir :: MonadIO m => m String
getXMonadDir = io $ getAppUserDataDirectory "xmonad"
-- | 'recompile force', recompile ~\/.xmonad\/xmonad.hs when any of the
-- following apply:
-- * force is True
-- * the xmonad executable does not exist
-- * the xmonad executable is older than xmonad.hs
--
-- The -i flag is used to restrict recompilation to the xmonad.hs file only.
--
-- Compilation errors (if any) are logged to ~\/.xmonad\/xmonad.errors. If
-- GHC indicates failure with a non-zero exit code, an xmessage containing
-- GHC's is spawned.
--
recompile :: MonadIO m => Bool -> m ()
recompile force = io $ do
dir <- getXMonadDir
let binn = "xmonad-"++arch++"-"++os
bin = dir ++ "/" ++ binn
base = dir ++ "/" ++ "xmonad"
err = base ++ ".errors"
src = base ++ ".hs"
srcT <- getModTime src
binT <- getModTime bin
when (force || srcT > binT) $ do
status <- bracket (openFile err WriteMode) hClose $ \h -> do
waitForProcess =<< runProcess "ghc" ["--make", "xmonad.hs", "-i", "-no-recomp", "-v0", "-o",binn] (Just dir)
Nothing Nothing Nothing (Just h)
-- now, if it fails, run xmessage to let the user know:
when (status /= ExitSuccess) $ do
ghcErr <- readFile err
let msg = unlines $
["Error detected while loading xmonad configuration file: " ++ src]
++ lines ghcErr ++ ["","Please check the file for errors."]
doubleFork $ executeFile "xmessage" True [msg] Nothing
where getModTime f = catch (Just <$> getModificationTime f) (const $ return Nothing)
-- | Run a side effecting action with the current workspace. Like 'when' but
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
|