{- | Dyre is a library for configuring your Haskell programs. Like Xmonad, programs configured with Dyre will look for a configuration file written in Haskell, which essentially defines a custom program configured exactly as the user wishes it to be. And since the configuration is written in Haskell, the user is free to do anything they might wish in the context of configuring the program. Dyre places emphasis on elegance of operation and ease of integration with existing applications. The 'wrapMain' function is the sole entry point for Dyre. When partially applied with a parameter structure, it wraps around the 'realMain' value from that structure, yielding an almost identical function which has been augmented with dynamic recompilation functionality. The 'Config.Dyre.Relaunch' module provides the ability to restart the program (recompiling if applicable), and persist state across restarts, but it has no impact whatsoever on the rest of the library whether it is used or not. A full example of using most of Dyre's major features is as follows: > -- DyreExample.hs -- > module DyreExample where > > import qualified Config.Dyre as Dyre > import Config.Dyre.Relaunch > > import System.IO > > data Config = Config { message :: String, errorMsg :: Maybe String } > data State = State { bufferLines :: [String] } deriving (Read, Show) > > defaultConfig :: Config > defaultConfig = Config "Dyre Example v0.1" Nothing > > showError :: Config -> String -> Config > showError cfg msg = cfg { errorMsg = Just msg } > > realMain Config{message = message, errorMsg = errorMsg } = do > (State buffer) <- restoreTextState $ State [] > case errorMsg of > Nothing -> return () > Just em -> putStrLn $ "Error: " ++ em > putStrLn message > mapM putStrLn . reverse $ buffer > putStr "> " >> hFlush stdout > input <- getLine > case input of > "exit" -> return () > "quit" -> return () > other -> relaunchWithTextState (State $ other:buffer) Nothing > > dyreExample = Dyre.wrapMain $ Dyre.defaultParams > { Dyre.projectName = "dyreExample" > , Dyre.realMain = realMain > , Dyre.showError = showError > } Notice that all of the program logic is contained in the 'DyreExample' module. The main module of the program is absolutely trivial, being essentially just the default configuration for the program: > -- Main.hs -- > import DyreExample > main = dyreExample defaultConfig The user can then create a custom configuration file, which overrides some or all of the default configuration: > -- ~/.config/dyreExample/dyreExample.hs -- > import DyreExample > main = dyreExample $ defaultConfig { message = "Dyre Example v0.1 (Modified)" } When reading the above program, notice that the majority of the code is simply *program logic*. Dyre is designed to intelligently handle recompilation with a minimum of programmer work. Some mention should be made of Dyre's defaults. The 'defaultParams' structure used in the example defines reasonable default values for most configuration items. The three elements defined above are the only elements that must be overridden. For documentation of the parameters, consult the 'Config.Dyre.Params' module. In the absence of any customization, Dyre will search for configuration files in '$XDG_CONFIG_HOME/<appName>/<appName>.hs', and will store cache files in '$XDG_CACHE_HOME/<appName>/' directory. The module 'System.Environment.XDG' is used for this purpose, which also provides analogous behaviour on Windows. The above example can be tested by running Main.hs with 'runhaskell', and will detect custom configurations and recompile correctly even when the library isn't installed, so long as it is in the current directory when run. -} module Config.Dyre ( wrapMain, Params(..), defaultParams ) where import System.IO ( hPutStrLn, stderr ) import System.Directory ( doesFileExist, removeFile, canonicalizePath , getDirectoryContents, doesDirectoryExist ) import System.FilePath ( (</>) ) import System.Environment (getArgs) import GHC.Environment (getFullArgs) import Control.Exception (assert) import Control.Monad ( when, filterM ) import Config.Dyre.Params ( Params(..), RTSOptionHandling(..) ) import Config.Dyre.Compile ( customCompile, getErrorPath, getErrorString ) import Config.Dyre.Compat ( customExec ) import Config.Dyre.Options ( getForceReconf, getDenyReconf, getDebug , withDyreOptions ) import Config.Dyre.Paths ( getPaths, maybeModTime ) -- | A set of reasonable defaults for configuring Dyre. The fields that -- have to be filled are 'projectName', 'realMain', and 'showError'. defaultParams :: Params cfgType defaultParams = Params { projectName = undefined , configCheck = True , configDir = Nothing , cacheDir = Nothing , realMain = undefined , showError = undefined , hidePackages = [] , ghcOpts = [] , forceRecomp = True , statusOut = hPutStrLn stderr , rtsOptsHandling = RTSAppend [] , includeCurrentDirectory = True } -- | 'wrapMain' is how Dyre recieves control of the program. It is expected -- that it will be partially applied with its parameters to yield a 'main' -- entry point, which will then be called by the 'main' function, as well -- as by any custom configurations. wrapMain :: Params cfgType -> cfgType -> IO () wrapMain params@Params{projectName = pName} cfg = withDyreOptions params $ -- Allow the 'configCheck' parameter to disable all of Dyre's recompilation -- checks, in favor of simply proceeding ahead to the 'realMain' function. if not $ configCheck params then realMain params cfg else do -- Get the important paths (thisBinary,tempBinary,configFile,cacheDir,libsDir) <- getPaths params libFiles <- recFiles libsDir libTimes <- mapM maybeModTime libFiles -- Check their modification times thisTime <- maybeModTime thisBinary tempTime <- maybeModTime tempBinary confTime <- maybeModTime configFile let confExists = confTime /= Nothing denyReconf <- getDenyReconf forceReconf <- getForceReconf -- Either the user or timestamps indicate we need to recompile let needReconf = or [ tempTime < confTime , tempTime < thisTime , or . map (tempTime <) $ libTimes , forceReconf ] -- If we're allowed to reconfigure, a configuration exists, and -- we detect a need to recompile it, then go ahead and compile. when (not denyReconf && confExists && needReconf) (customCompile params) -- If there's a custom binary and we're not it, run it. Otherwise -- just launch the main function, reporting errors if appropriate. -- Also we don't want to use a custom binary if the conf file is -- gone. errorData <- getErrorString params customExists <- doesFileExist tempBinary if confExists && customExists then do -- Canonicalize the paths for comparison to avoid symlinks -- throwing us off. We do it here instead of earlier because -- canonicalizePath throws an exception when the file is -- nonexistent. thisBinary' <- canonicalizePath thisBinary tempBinary' <- canonicalizePath tempBinary if thisBinary' /= tempBinary' then launchSub errorData tempBinary else enterMain errorData else enterMain errorData where launchSub errorData tempBinary = do statusOut params $ "Launching custom binary " ++ tempBinary ++ "\n" givenArgs <- handleRTSOptions $ rtsOptsHandling params -- Deny reconfiguration if a compile already failed. let arguments = case errorData of Nothing -> givenArgs Just _ -> "--deny-reconf":givenArgs -- Execute customExec tempBinary $ Just arguments enterMain errorData = do -- Show the error data if necessary let mainConfig = case errorData of Nothing -> cfg Just ed -> showError params cfg ed -- Enter the main program realMain params mainConfig recFiles :: FilePath -> IO [FilePath] recFiles d = do exists <- doesDirectoryExist d if exists then do nodes <- getDirectoryContents d let nodes' = map (d </>) . filter (`notElem` [".", ".."]) $ nodes files <- filterM doesFileExist nodes' dirs <- filterM doesDirectoryExist nodes' subfiles <- concat `fmap` mapM recFiles dirs return $ files ++ subfiles else return [] assertM b = assert b $ return () -- | Filters GHC runtime system arguments: filterRTSArgs = filt False where filt _ [] = [] filt _ ("--RTS":rest) = [] filt False ("+RTS" :rest) = filt True rest filt True ("-RTS" :rest) = filt False rest filt False (_ :rest) = filt False rest filt True (arg :rest) = arg:filt True rest --filt state args = error $ "Error filtering RTS arguments in state " ++ show state ++ " remaining arguments: " ++ show args editRTSOptions opts (RTSReplace ls) = ls editRTSOptions opts (RTSAppend ls) = opts ++ ls handleRTSOptions h = do fargs <- getFullArgs args <- getArgs let rtsArgs = editRTSOptions (filterRTSArgs fargs) h assertM $ not $ "--RTS" `elem` rtsArgs case rtsArgs of [] -> if not $ "+RTS" `elem` args then return args -- cleaner output else return $ "--RTS":args _ -> return $ ["+RTS"] ++ rtsArgs ++ ["--RTS"] ++ args