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{-# LANGUAGE NoMonomorphismRestriction #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE EmptyCase #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE UndecidableInstances #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# OPTIONS_GHC -fno-warn-orphans #-}
module LambdaCube.Compiler.Utils where
import qualified Data.IntSet as IS
import qualified Data.Text as T
import qualified Text.Show.Pretty as PP
import Control.Monad.Catch
import Control.Monad.Except
import Control.Monad.RWS
import System.Directory
import qualified Data.Text.IO as TIO
import qualified Text.Megaparsec as P
import qualified Text.Megaparsec.Prim as P
------------------------------------------------------- general functions
(<&>) :: Functor f => f a -> (a -> b) -> f b
(<&>) = flip (<$>)
dropIndex :: Int -> [a] -> [a]
dropIndex i xs = take i xs ++ drop (i+1) xs
iterateN :: Int -> (a -> a) -> a -> a
iterateN n f e = iterate f e !! n
foldlrev f = foldr (flip f)
------------------------------------------------------- Void data type
data Void
instance Eq Void where x == y = elimVoid x
elimVoid :: Void -> a
elimVoid v = case v of
------------------------------------------------------- supplementary data wrapper
-- supplementary data: data with no semantic relevance
newtype SData a = SData a
instance Eq (SData a) where _ == _ = True
instance Ord (SData a) where _ `compare` _ = EQ
------------------------------------------------------- strongly connected component calculation
type Children k = k -> [k]
data Task a = Return a | Visit a
scc :: forall k . (k -> Int) -> Children k -> Children k -> [k]{-roots-} -> [[k]]
scc key children revChildren
= filter (not . null) . uncurry (revMapWalk revChildren) . revPostOrderWalk children
where
revPostOrderWalk :: Children k -> [k] -> (IS.IntSet, [k])
revPostOrderWalk children = collect IS.empty [] . map Visit where
collect s acc [] = (s, acc)
collect s acc (Return h: t) = collect s (h: acc) t
collect s acc (Visit h: t)
| key h `IS.member` s = collect s acc t
| otherwise = collect (IS.insert (key h) s) acc $ map Visit (children h) ++ Return h: t
revMapWalk :: Children k -> IS.IntSet -> [k] -> [[k]]
revMapWalk children = f []
where
f acc s [] = acc
f acc s (h:t) = f (c: acc) s' t
where (s', c) = collect s [] [h]
collect s acc [] = (s, acc)
collect s acc (h:t)
| not (key h `IS.member` s) = collect s acc t
| otherwise = collect (IS.delete (key h) s) (h: acc) (children h ++ t)
------------------------------------------------------- wrapped pretty show
prettyShowUnlines :: Show a => a -> String
prettyShowUnlines = goPP 0 . PP.ppShow
where
goPP _ [] = []
goPP n ('"':xs) | isMultilineString xs = "\"\"\"\n" ++ indent ++ go xs where
indent = replicate n ' '
go ('\\':'n':xs) = "\n" ++ indent ++ go xs
go ('\\':c:xs) = '\\':c:go xs
go ('"':xs) = "\n" ++ indent ++ "\"\"\"" ++ goPP n xs
go (x:xs) = x : go xs
goPP n (x:xs) = x : goPP (if x == '\n' then 0 else n+1) xs
isMultilineString ('\\':'n':xs) = True
isMultilineString ('\\':c:xs) = isMultilineString xs
isMultilineString ('"':xs) = False
isMultilineString (x:xs) = isMultilineString xs
isMultilineString [] = False
------------------------------------------------------- file handling
readFileStrict :: FilePath -> IO String
readFileStrict = fmap T.unpack . TIO.readFile
readFileIfExists :: FilePath -> IO (Maybe (IO String))
readFileIfExists fname = do
b <- doesFileExist fname
return $ if b then Just $ readFileStrict fname else Nothing
------------------------------------------------------- missing instances
instance MonadMask m => MonadMask (ExceptT e m) where
mask f = ExceptT $ mask $ \u -> runExceptT $ f (mapExceptT u)
uninterruptibleMask = error "not implemented: uninterruptibleMask for ExcpetT"
instance (Monoid w, P.MonadParsec st m t) => P.MonadParsec st (RWST r w s m) t where
failure = lift . P.failure
label = mapRWST . P.label
try = mapRWST P.try
lookAhead (RWST m) = RWST $ \r s -> (\(a, _, _) -> (a, s, mempty)) <$> P.lookAhead (m r s)
notFollowedBy (RWST m) = RWST $ \r s -> P.notFollowedBy ((\(a, _, _) -> a) <$> m r s) >> return ((), s, mempty)
withRecovery rec (RWST m) = RWST $ \r s -> P.withRecovery (\e -> runRWST (rec e) r s) (m r s)
eof = lift P.eof
token f e = lift $ P.token f e
tokens f e ts = lift $ P.tokens f e ts
getParserState = lift P.getParserState
updateParserState f = lift $ P.updateParserState f
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