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|
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE UndecidableInstances #-}
-- |
-- Module : Verismith.Result
-- Description : Result monadic type.
-- Copyright : (c) 2019, Yann Herklotz Grave
-- License : GPL-3
-- Maintainer : yann [at] yannherklotz [dot] com
-- Stability : experimental
-- Portability : POSIX
--
-- Result monadic type. This is nearly equivalent to the transformers 'Error' type,
-- but to have more control this is reimplemented with the instances that are
-- needed in "Verismith".
module Verismith.Result
( Result (..),
ResultT (..),
justPass,
justFail,
(<?>),
annotate,
)
where
import Control.Monad (liftM)
import Control.Monad.Base
import Control.Monad.IO.Class
import Control.Monad.Trans.Class
import Control.Monad.Trans.Control
import Data.Bifunctor (Bifunctor (..))
import Shelly (RunFailed (..), Sh, catch_sh)
import Shelly.Lifted
( MonadSh,
MonadShControl,
ShM,
liftSh,
liftShWith,
restoreSh,
)
-- | Result type which is equivalent to 'Either' or 'Error'. This is
-- reimplemented so that there is full control over the 'Monad' definition and
-- definition of a 'Monad' transformer 'ResultT'.
data Result a b
= Fail a
| Pass b
deriving (Eq, Show)
justPass :: Result a b -> Maybe b
justPass (Fail _) = Nothing
justPass (Pass a) = Just a
justFail :: Result a b -> Maybe a
justFail (Pass _) = Nothing
justFail (Fail a) = Just a
instance Semigroup (Result a b) where
Pass _ <> a = a
a <> _ = a
instance (Monoid b) => Monoid (Result a b) where
mempty = Pass mempty
instance Functor (Result a) where
fmap f (Pass a) = Pass $ f a
fmap _ (Fail b) = Fail b
instance Applicative (Result a) where
pure = Pass
Fail e <*> _ = Fail e
Pass f <*> r = fmap f r
instance Monad (Result a) where
Pass a >>= f = f a
Fail b >>= _ = Fail b
instance MonadBase (Result a) (Result a) where
liftBase = id
instance Bifunctor Result where
bimap a _ (Fail c) = Fail $ a c
bimap _ b (Pass c) = Pass $ b c
-- | The transformer for the 'Result' type. This
newtype ResultT a m b = ResultT {runResultT :: m (Result a b)}
instance Functor f => Functor (ResultT a f) where
fmap f = ResultT . fmap (fmap f) . runResultT
instance Monad m => Applicative (ResultT a m) where
pure = ResultT . pure . pure
f <*> a = ResultT $ do
f' <- runResultT f
case f' of
Fail e -> return (Fail e)
Pass k -> do
a' <- runResultT a
case a' of
Fail e -> return (Fail e)
Pass v -> return (Pass $ k v)
instance Monad m => Monad (ResultT a m) where
a >>= b = ResultT $ do
m <- runResultT a
case m of
Fail e -> return (Fail e)
Pass p -> runResultT (b p)
instance (MonadSh m, Monoid a) => MonadSh (ResultT a m) where
liftSh s =
ResultT
. liftSh
. catch_sh (Pass <$> s)
$ (const (Fail <$> return mempty) :: RunFailed -> Sh (Result a b))
instance MonadIO m => MonadIO (ResultT a m) where
liftIO s = ResultT $ Pass <$> liftIO s
instance MonadBase b m => MonadBase b (ResultT a m) where
liftBase = liftBaseDefault
instance MonadTrans (ResultT e) where
lift m = ResultT $ Pass <$> m
instance MonadTransControl (ResultT a) where
type StT (ResultT a) b = Result a b
liftWith f = ResultT $ return <$> f runResultT
restoreT = ResultT
{-# INLINEABLE liftWith #-}
{-# INLINEABLE restoreT #-}
instance MonadBaseControl IO m => MonadBaseControl IO (ResultT a m) where
type StM (ResultT a m) b = ComposeSt (ResultT a) m b
liftBaseWith = defaultLiftBaseWith
restoreM = defaultRestoreM
{-# INLINEABLE liftBaseWith #-}
{-# INLINEABLE restoreM #-}
instance
(MonadShControl m) =>
MonadShControl (ResultT a m)
where
newtype ShM (ResultT a m) b = ResultTShM (ShM m (Result a b))
liftShWith f =
ResultT $ liftM return $ liftShWith $ \runInSh -> f $ \k ->
liftM ResultTShM $ runInSh $ runResultT k
restoreSh (ResultTShM m) = ResultT . restoreSh $ m
{-# INLINE liftShWith #-}
{-# INLINE restoreSh #-}
infix 0 <?>
(<?>) :: (Monad m, Monoid a) => ResultT a m b -> a -> ResultT a m b
m <?> b = ResultT $ do
a <- runResultT m
case a of
Pass a' -> return $ Pass a'
Fail a' -> return . Fail $ a' <> b
annotate :: (Monad m, Monoid a) => a -> ResultT a m b -> ResultT a m b
annotate = flip (<?>)
|