{-# LANGUAGE CPP #-} {-# LANGUAGE DataKinds #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE TypeFamilies #-} {-# LANGUAGE TypeOperators #-} {-| Module : GHCup.Utils.Prelude Description : MegaParsec utilities Copyright : (c) Julian Ospald, 2020 License : LGPL-3.0 Maintainer : hasufell@hasufell.de Stability : experimental Portability : portable GHCup specific prelude. Lots of Excepts functionality. -} module GHCup.Utils.Prelude (module GHCup.Utils.Prelude, #if defined(IS_WINDOWS) module GHCup.Utils.Prelude.Windows #else module GHCup.Utils.Prelude.Posix #endif ) where import GHCup.Types import GHCup.Errors import GHCup.Types.Optics import {-# SOURCE #-} GHCup.Utils.Logger (logWarn) #if defined(IS_WINDOWS) import GHCup.Utils.Prelude.Windows #else import GHCup.Utils.Prelude.Posix #endif import Control.Applicative import Control.Exception.Safe import Control.Monad import Control.Monad.IO.Class import Control.Monad.Reader import Data.Bifunctor import Data.ByteString ( ByteString ) import Data.List ( nub, intercalate, stripPrefix, isPrefixOf, dropWhileEnd, intersperse ) import Data.Maybe import Data.Foldable import Data.List.NonEmpty ( NonEmpty( (:|) )) import Data.String import Data.Text ( Text ) import Data.Versions import Data.Word8 hiding ( isDigit ) import Haskus.Utils.Types.List import Haskus.Utils.Variant.Excepts import Text.PrettyPrint.HughesPJClass ( prettyShow, Pretty ) import System.IO.Error import System.IO.Temp import System.IO.Unsafe import System.Directory hiding ( copyFile ) import System.FilePath import Control.Retry import GHC.IO.Exception import qualified Data.ByteString as B import qualified Data.ByteString.Lazy as L import qualified Data.Strict.Maybe as S import qualified Data.List.Split as Split import qualified Data.List.NonEmpty as NE import qualified Data.Text as T import qualified Data.Text.Encoding as E import qualified Data.Text.Encoding.Error as E import qualified Data.Text.Lazy as TL import qualified Data.Text.Lazy.Builder as B import qualified Data.Text.Lazy.Builder.Int as B import qualified Data.Text.Lazy.Encoding as TLE -- $setup -- >>> import Data.ByteString.Internal (c2w, w2c) -- >>> import Test.QuickCheck -- >>> import Data.Word8 -- >>> import qualified Data.Text as T -- >>> import qualified Data.Char as C -- >>> import Data.List -- >>> instance Arbitrary T.Text where arbitrary = T.pack <$> arbitrary fS :: IsString a => String -> a fS = fromString fromStrictMaybe :: S.Maybe a -> Maybe a fromStrictMaybe = S.maybe Nothing Just fSM :: S.Maybe a -> Maybe a fSM = fromStrictMaybe toStrictMaybe :: Maybe a -> S.Maybe a toStrictMaybe = maybe S.Nothing S.Just tSM :: Maybe a -> S.Maybe a tSM = toStrictMaybe internalError :: String -> IO a internalError = fail . ("Internal error: " <>) iE :: String -> IO a iE = internalError showT :: Show a => a -> Text showT = fS . show -- | Like 'when', but where the test can be monadic. whenM :: Monad m => m Bool -> m () -> m () whenM ~b ~t = ifM b t (return ()) -- | Like 'unless', but where the test can be monadic. unlessM :: Monad m => m Bool -> m () -> m () unlessM ~b ~f = ifM b (return ()) f -- | Like @if@, but where the test can be monadic. ifM :: Monad m => m Bool -> m a -> m a -> m a ifM ~b ~t ~f = do b' <- b if b' then t else f whileM :: Monad m => m a -> (a -> m Bool) -> m a whileM ~action ~f = do a <- action b' <- f a if b' then whileM action f else pure a whileM_ :: Monad m => m a -> (a -> m Bool) -> m () whileM_ ~action = void . whileM action guardM :: (Monad m, Alternative m) => m Bool -> m () guardM ~f = guard =<< f handleIO' :: (MonadIO m, MonadCatch m) => IOErrorType -> (IOException -> m a) -> m a -> m a handleIO' err handler = handleIO (\e -> if err == ioeGetErrorType e then handler e else liftIO $ ioError e) (??) :: forall e es a m . (Monad m, e :< es) => Maybe a -> e -> Excepts es m a (??) m e = maybe (throwE e) pure m (!?) :: forall e es a m . (Monad m, e :< es) => m (Maybe a) -> e -> Excepts es m a (!?) em e = lift em >>= (?? e) lE :: forall e es a m . (Monad m, e :< es) => Either e a -> Excepts es m a lE = liftE . veitherToExcepts . fromEither lE' :: forall e' e es a m . (Monad m, e :< es) => (e' -> e) -> Either e' a -> Excepts es m a lE' f = liftE . veitherToExcepts . fromEither . first f lEM :: forall e es a m . (Monad m, e :< es) => m (Either e a) -> Excepts es m a lEM em = lift em >>= lE lEM' :: forall e' e es a m . (Monad m, e :< es) => (e' -> e) -> m (Either e' a) -> Excepts es m a lEM' f em = lift em >>= lE . first f -- for some obscure reason... this won't type-check if we move it to a different module catchWarn :: forall es m env . ( Pretty (V es) , MonadReader env m , HasLog env , MonadIO m , Monad m) => Excepts es m () -> Excepts '[] m () catchWarn = catchAllE @_ @es (\v -> lift $ logWarn (T.pack . prettyShow $ v)) fromEither :: Either a b -> VEither '[a] b fromEither = either (VLeft . V) VRight liftIOException' :: ( MonadCatch m , MonadIO m , Monad m , e :< es' , LiftVariant es es' ) => IOErrorType -> e -> Excepts es m a -> Excepts es' m a liftIOException' errType ex = handleIO (\e -> if errType == ioeGetErrorType e then throwE ex else liftIO $ ioError e ) . liftE liftIOException :: (MonadCatch m, MonadIO m, Monad m, e :< es') => IOErrorType -> e -> m a -> Excepts es' m a liftIOException errType ex = handleIO (\e -> if errType == ioeGetErrorType e then throwE ex else liftIO $ ioError e ) . lift -- | Uses safe-exceptions. hideError :: (MonadIO m, MonadCatch m) => IOErrorType -> m () -> m () hideError err = handleIO (\e -> if err == ioeGetErrorType e then pure () else liftIO . ioError $ e) hideErrorDef :: (MonadIO m, MonadCatch m) => [IOErrorType] -> a -> m a -> m a hideErrorDef errs def = handleIO (\e -> if ioeGetErrorType e `elem` errs then pure def else liftIO $ ioError e) hideErrorDefM :: (MonadIO m, MonadCatch m) => [IOErrorType] -> m a -> m a -> m a hideErrorDefM errs def = handleIO (\e -> if ioeGetErrorType e `elem` errs then def else liftIO $ ioError e) -- TODO: does this work? hideExcept :: forall e es es' a m . (Monad m, e :< es, LiftVariant (Remove e es) es') => e -> a -> Excepts es m a -> Excepts es' m a hideExcept _ a = catchLiftLeft ((\_ -> pure a) :: (e -> Excepts es' m a)) hideExcept' :: forall e es es' m . (Monad m, e :< es, LiftVariant (Remove e es) es') => e -> Excepts es m () -> Excepts es' m () hideExcept' _ = catchLiftLeft ((\_ -> pure ()) :: (e -> Excepts es' m ())) reThrowAll :: forall e es es' a m . (Monad m, e :< es') => (V es -> e) -> Excepts es m a -> Excepts es' m a reThrowAll f = catchAllE (throwE . f) reThrowAllIO :: forall e es es' a m . (MonadCatch m, Monad m, MonadIO m, e :< es') => (V es -> e) -> (IOException -> e) -> Excepts es m a -> Excepts es' m a reThrowAllIO f g = handleIO (throwE . g) . catchAllE (throwE . f) throwEither :: (Exception a, MonadThrow m) => Either a b -> m b throwEither a = case a of Left e -> throwM e Right r -> pure r throwEither' :: (Exception a, MonadThrow m) => a -> Either x b -> m b throwEither' e eth = case eth of Left _ -> throwM e Right r -> pure r throwMaybe :: (Exception a, MonadThrow m) => a -> Maybe b -> m b throwMaybe a m = case m of Nothing -> throwM a Just r -> pure r throwMaybeM :: (Exception a, MonadThrow m) => a -> m (Maybe b) -> m b throwMaybeM a am = do m <- am throwMaybe a m verToBS :: Version -> ByteString verToBS = E.encodeUtf8 . prettyVer verToS :: Version -> String verToS = T.unpack . prettyVer intToText :: Integral a => a -> T.Text intToText = TL.toStrict . B.toLazyText . B.decimal pvpToVersion :: MonadThrow m => PVP -> Text -> m Version pvpToVersion pvp_ rest = either (\_ -> throwM $ ParseError "Couldn't convert PVP to Version") pure . version . (<> rest) . prettyPVP $ pvp_ -- | Convert a version to a PVP and unparsable rest. -- -- -- prop> \v -> let (Just (pvp', r)) = versionToPVP v in pvpToVersion pvp' r === Just v versionToPVP :: MonadThrow m => Version -> m (PVP, Text) versionToPVP (Version (Just _) _ _ _) = throwM $ ParseError "Unexpected epoch" versionToPVP v = either (\_ -> (, rest v) <$> alternative v) (pure . (, mempty)) . pvp . prettyVer $ v where alternative :: MonadThrow m => Version -> m PVP alternative v' = case NE.takeWhile isDigit (_vChunks v') of [] -> throwM $ ParseError "Couldn't convert Version to PVP" xs -> pure $ pvpFromList (unsafeDigit <$> xs) rest :: Version -> Text rest (Version _ cs pr me) = let chunks = NE.dropWhile isDigit cs ver = intersperse (T.pack ".") . chunksAsT $ chunks me' = maybe [] (\m -> [T.pack "+",m]) me pr' = foldable [] (T.pack "-" :) $ intersperse (T.pack ".") (chunksAsT pr) prefix = case (ver, pr', me') of (_:_, _, _) -> T.pack "." _ -> T.pack "" in prefix <> mconcat (ver <> pr' <> me') where chunksAsT :: Functor t => t VChunk -> t Text chunksAsT = fmap (foldMap f) where f :: VUnit -> Text f (Digits i) = T.pack $ show i f (Str s) = s foldable :: Foldable f => f b -> (f a -> f b) -> f a -> f b foldable d g f | null f = d | otherwise = g f isDigit :: VChunk -> Bool isDigit (Digits _ :| []) = True isDigit _ = False unsafeDigit :: VChunk -> Int unsafeDigit (Digits x :| []) = fromIntegral x unsafeDigit _ = error "unsafeDigit: wrong input" pvpFromList :: [Int] -> PVP pvpFromList = PVP . NE.fromList . fmap fromIntegral -- | Safe 'decodeUtf8With'. Replaces an invalid input byte with -- the Unicode replacement character U+FFFD. decUTF8Safe :: ByteString -> Text decUTF8Safe = E.decodeUtf8With E.lenientDecode decUTF8Safe' :: L.ByteString -> Text decUTF8Safe' = TL.toStrict . TLE.decodeUtf8With E.lenientDecode -- | Escape a version for use in regex escapeVerRex :: Version -> ByteString escapeVerRex = B.pack . go . B.unpack . verToBS where go [] = [] go (x : xs) | x == _period = [_backslash, _period] ++ go xs | otherwise = x : go xs -- | More permissive version of 'createDirRecursive'. This doesn't -- error when the destination is a symlink to a directory. createDirRecursive' :: FilePath -> IO () createDirRecursive' p = handleIO (\e -> if isAlreadyExistsError e then isSymlinkDir e else throwIO e) . createDirectoryIfMissing True $ p where isSymlinkDir e = do ft <- pathIsSymbolicLink p case ft of True -> do rp <- canonicalizePath p rft <- doesDirectoryExist rp case rft of True -> pure () _ -> throwIO e _ -> throwIO e -- | Recursively copy the contents of one directory to another path. -- -- This is a rip-off of Cabal library. copyDirectoryRecursive :: FilePath -> FilePath -> (FilePath -> FilePath -> IO ()) -> IO () copyDirectoryRecursive srcDir destDir doCopy = do srcFiles <- getDirectoryContentsRecursive srcDir copyFilesWith destDir [ (srcDir, f) | f <- srcFiles ] where -- | Common implementation of 'copyFiles', 'installOrdinaryFiles', -- 'installExecutableFiles' and 'installMaybeExecutableFiles'. copyFilesWith :: FilePath -> [(FilePath, FilePath)] -> IO () copyFilesWith targetDir srcFiles = do -- Create parent directories for everything let dirs = map (targetDir ) . nub . map takeDirectory $ fmap snd srcFiles traverse_ (createDirectoryIfMissing True) dirs -- Copy all the files sequence_ [ let src = srcBase srcFile dest = targetDir srcFile in doCopy src dest | (srcBase, srcFile) <- srcFiles ] -- | List all the files in a directory and all subdirectories. -- -- The order places files in sub-directories after all the files in their -- parent directories. The list is generated lazily so is not well defined if -- the source directory structure changes before the list is used. -- -- TODO: use streamly getDirectoryContentsRecursive :: FilePath -> IO [FilePath] getDirectoryContentsRecursive topdir = recurseDirectories [""] where recurseDirectories :: [FilePath] -> IO [FilePath] recurseDirectories [] = return [] recurseDirectories (dir:dirs) = unsafeInterleaveIO $ do (files, dirs') <- collect [] [] =<< getDirectoryContents (topdir dir) files' <- recurseDirectories (dirs' ++ dirs) return (files ++ files') where collect files dirs' [] = return (reverse files ,reverse dirs') collect files dirs' (entry:entries) | ignore entry = collect files dirs' entries collect files dirs' (entry:entries) = do let dirEntry = dir entry isDirectory <- doesDirectoryExist (topdir dirEntry) if isDirectory then collect files (dirEntry:dirs') entries else collect (dirEntry:files) dirs' entries ignore ['.'] = True ignore ['.', '.'] = True ignore _ = False -- https://github.com/haskell/directory/issues/110 -- https://github.com/haskell/directory/issues/96 -- https://www.sqlite.org/src/info/89f1848d7f recyclePathForcibly :: ( MonadIO m , MonadReader env m , HasDirs env , MonadMask m ) => FilePath -> m () recyclePathForcibly fp | isWindows = do Dirs { recycleDir } <- getDirs tmp <- liftIO $ createTempDirectory recycleDir "recyclePathForcibly" let dest = tmp takeFileName fp liftIO (moveFile fp dest) `catch` (\e -> if | isDoesNotExistError e -> pure () | isPermissionError e || ioeGetErrorType e == UnsupportedOperation {- EXDEV on windows -} -> recover (liftIO $ removePathForcibly fp) | otherwise -> throwIO e) `finally` liftIO (handleIO (\_ -> pure ()) $ removePathForcibly tmp) | otherwise = liftIO $ removePathForcibly fp rmPathForcibly :: ( MonadIO m , MonadMask m ) => FilePath -> m () rmPathForcibly fp | isWindows = recover (liftIO $ removePathForcibly fp) | otherwise = liftIO $ removePathForcibly fp rmDirectory :: (MonadIO m, MonadMask m) => FilePath -> m () rmDirectory fp | isWindows = recover (liftIO $ removeDirectory fp) | otherwise = liftIO $ removeDirectory fp -- https://www.sqlite.org/src/info/89f1848d7f -- https://github.com/haskell/directory/issues/96 recycleFile :: ( MonadIO m , MonadMask m , MonadReader env m , HasDirs env ) => FilePath -> m () recycleFile fp | isWindows = do Dirs { recycleDir } <- getDirs liftIO $ whenM (doesDirectoryExist fp) $ ioError (IOError Nothing InappropriateType "recycleFile" "" Nothing (Just fp)) tmp <- liftIO $ createTempDirectory recycleDir "recycleFile" let dest = tmp takeFileName fp liftIO (moveFile fp dest) `catch` (\e -> if isPermissionError e || ioeGetErrorType e == UnsupportedOperation {- EXDEV on windows -} then recover (liftIO $ removePathForcibly fp) else throwIO e) `finally` liftIO (handleIO (\_ -> pure ()) $ removePathForcibly tmp) | otherwise = liftIO $ removeFile fp rmFile :: ( MonadIO m , MonadMask m ) => FilePath -> m () rmFile fp | isWindows = recover (liftIO $ removeFile fp) | otherwise = liftIO $ removeFile fp rmDirectoryLink :: (MonadIO m, MonadMask m, MonadReader env m, HasDirs env) => FilePath -> m () rmDirectoryLink fp | isWindows = recover (liftIO $ removeDirectoryLink fp) | otherwise = liftIO $ removeDirectoryLink fp recover :: (MonadIO m, MonadMask m) => m a -> m a recover action = recovering (fullJitterBackoff 25000 <> limitRetries 10) [\_ -> Handler (\e -> pure $ isPermissionError e) ,\_ -> Handler (\e -> pure (ioeGetErrorType e == InappropriateType)) ,\_ -> Handler (\e -> pure (ioeGetErrorType e == UnsatisfiedConstraints)) ] (\_ -> action) -- | Gathering monoidal values -- -- >>> traverseFold (pure . (:["0"])) ["1","2"] -- ["1","0","2","0"] -- >>> traverseFold Just ["1","2","3","4","5"] -- Just "12345" -- -- prop> \t -> traverseFold Just t === Just (mconcat t) traverseFold :: (Foldable t, Applicative m, Monoid b) => (a -> m b) -> t a -> m b traverseFold f = foldl (\mb a -> (<>) <$> mb <*> f a) (pure mempty) -- | Gathering monoidal values forFold :: (Foldable t, Applicative m, Monoid b) => t a -> (a -> m b) -> m b forFold = \t -> (`traverseFold` t) -- | Strip @\\r@ and @\\n@ from 'String's -- -- >>> stripNewline "foo\n\n\n" -- "foo" -- >>> stripNewline "foo\n\n\nfoo" -- "foofoo" -- >>> stripNewline "foo\r" -- "foo" -- >>> stripNewline "foo" -- "foo" -- -- prop> \t -> stripNewline (t <> "\n") === stripNewline t -- prop> \t -> not (any (isNewLine . c2w) t) ==> stripNewline t == t stripNewline :: String -> String stripNewline = filter (`notElem` "\n\r") -- | Strip @\\r@ and @\\n@ from end of 'String'. -- -- >>> stripNewlineEnd "foo\n\n\n" -- "foo" -- >>> stripNewlineEnd "foo\n\n\nfoo" -- "foo\n\n\nfoo" -- >>> stripNewlineEnd "foo\r" -- "foo" -- >>> stripNewlineEnd "foo" -- "foo" -- -- prop> \t -> stripNewlineEnd (t <> "\n") === stripNewlineEnd t -- prop> \t -> not (any (isNewLine . c2w) t) ==> stripNewlineEnd t == t stripNewlineEnd :: String -> String stripNewlineEnd = dropWhileEnd (`elem` "\n\r") -- | Strip @\\r@ and @\\n@ from 'Text's -- -- >>> stripNewline' "foo\n\n\n" -- "foo" -- >>> stripNewline' "foo\n\n\nfoo" -- "foofoo" -- >>> stripNewline' "foo\r" -- "foo" -- >>> stripNewline' "foo" -- "foo" -- -- prop> \t -> stripNewline' (t <> "\n") === stripNewline' t -- prop> \t -> not (T.any (isNewLine . c2w) t) ==> stripNewline' t == t stripNewline' :: T.Text -> T.Text stripNewline' = T.filter (`notElem` "\n\r") -- | Is the word8 a newline? -- -- >>> isNewLine (c2w '\n') -- True -- >>> isNewLine (c2w '\r') -- True -- -- prop> \w -> w /= _lf && w /= _cr ==> not (isNewLine w) isNewLine :: Word8 -> Bool isNewLine w | w == _lf = True | w == _cr = True | otherwise = False -- | Split on a PVP suffix. -- -- >>> splitOnPVP "-" "ghc-iserv-dyn-9.3.20210706" -- ("ghc-iserv-dyn","9.3.20210706") -- >>> splitOnPVP "-" "ghc-iserv-dyn" -- ("ghc-iserv-dyn","") splitOnPVP :: String -> String -> (String, String) splitOnPVP c s = case Split.splitOn c s of [] -> def [_] -> def xs | let l = last xs , (Right _) <- pvp (T.pack l) -> (intercalate c (init xs), l) | otherwise -> def where def = (s, "") -- | Like 'find', but where the test can be monadic. -- -- >>> findM (Just . C.isUpper) "teST" -- Just (Just 'S') -- >>> findM (Just . C.isUpper) "test" -- Just Nothing -- >>> findM (Just . const True) ["x",undefined] -- Just (Just "x") findM :: Monad m => (a -> m Bool) -> [a] -> m (Maybe a) findM ~p = foldr (\x -> ifM (p x) (pure $ Just x)) (pure Nothing) -- | Drops the given suffix from a list. -- It returns the original sequence if the sequence doesn't end with the given suffix. -- -- >>> dropSuffix "!" "Hello World!" -- "Hello World" -- >>> dropSuffix "!" "Hello World!!" -- "Hello World!" -- >>> dropSuffix "!" "Hello World." -- "Hello World." dropSuffix :: Eq a => [a] -> [a] -> [a] dropSuffix a b = fromMaybe b $ stripSuffix a b -- | Return the prefix of the second list if its suffix -- matches the entire first list. -- -- >>> stripSuffix "bar" "foobar" -- Just "foo" -- >>> stripSuffix "" "baz" -- Just "baz" -- >>> stripSuffix "foo" "quux" -- Nothing stripSuffix :: Eq a => [a] -> [a] -> Maybe [a] stripSuffix a b = reverse <$> stripPrefix (reverse a) (reverse b) -- | Drops the given prefix from a list. -- It returns the original sequence if the sequence doesn't start with the given prefix. -- -- >>> dropPrefix "Mr. " "Mr. Men" -- "Men" -- >>> dropPrefix "Mr. " "Dr. Men" -- "Dr. Men" dropPrefix :: Eq a => [a] -> [a] -> [a] dropPrefix a b = fromMaybe b $ stripPrefix a b -- | Break a list into pieces separated by the first -- list argument, consuming the delimiter. An empty delimiter is -- invalid, and will cause an error to be raised. -- -- >>> splitOn "\r\n" "a\r\nb\r\nd\r\ne" -- ["a","b","d","e"] -- >>> splitOn "aaa" "aaaXaaaXaaaXaaa" -- ["","X","X","X",""] -- >>> splitOn "x" "x" -- ["",""] -- >>> splitOn "x" "" -- [""] -- -- prop> \s x -> s /= "" ==> intercalate s (splitOn s x) == x -- prop> \c x -> splitOn [c] x == split (==c) x splitOn :: Eq a => [a] -> [a] -> [[a]] splitOn [] _ = error "splitOn, needle may not be empty" splitOn _ [] = [[]] splitOn needle haystack = a : if null b then [] else splitOn needle $ drop (length needle) b where (a,b) = breakOn needle haystack -- | Splits a list into components delimited by separators, -- where the predicate returns True for a separator element. The -- resulting components do not contain the separators. Two adjacent -- separators result in an empty component in the output. -- -- >>> split (== 'a') "aabbaca" -- ["","","bb","c",""] -- >>> split (== 'a') "" -- [""] -- >>> split (== ':') "::xyz:abc::123::" -- ["","","xyz","abc","","123","",""] -- >>> split (== ',') "my,list,here" -- ["my","list","here"] split :: (a -> Bool) -> [a] -> [[a]] split _ [] = [[]] split f (x:xs) | f x = [] : split f xs | y:ys <- split f xs = (x:y) : ys | otherwise = [[]] -- | Find the first instance of @needle@ in @haystack@. -- The first element of the returned tuple -- is the prefix of @haystack@ before @needle@ is matched. The second -- is the remainder of @haystack@, starting with the match. -- If you want the remainder /without/ the match, use 'stripInfix'. -- -- >>> breakOn "::" "a::b::c" -- ("a","::b::c") -- >>> breakOn "/" "foobar" -- ("foobar","") -- -- prop> \needle haystack -> let (prefix,match) = breakOn needle haystack in prefix ++ match == haystack breakOn :: Eq a => [a] -> [a] -> ([a], [a]) breakOn needle haystack | needle `isPrefixOf` haystack = ([], haystack) breakOn _ [] = ([], []) breakOn needle (x:xs) = first (x:) $ breakOn needle xs -- |Like `bracket`, but allows to have different clean-up -- actions depending on whether the in-between computation -- has raised an exception or not. bracketeer :: IO a -- ^ computation to run first -> (a -> IO b) -- ^ computation to run last, when -- no exception was raised -> (a -> IO b) -- ^ computation to run last, -- when an exception was raised -> (a -> IO c) -- ^ computation to run in-between -> IO c bracketeer before after afterEx thing = mask $ \restore -> do a <- before r <- restore (thing a) `onException` afterEx a _ <- after a return r