{- Copyright (C) 2015 Martin Linnemann This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA -} {- | Module : Text.Pandoc.Readers.Odt.Arrows.Utils Copyright : Copyright (C) 2015 Martin Linnemann License : GNU GPL, version 2 or above Maintainer : Martin Linnemann Stability : alpha Portability : portable Utility functions for Arrows (Kleisli monads). Some general notes on notation: * "^" is meant to stand for a pure function that is lifted into an arrow based on its usage for that purpose in "Control.Arrow". * "?" is meant to stand for the usage of a 'FallibleArrow' or a pure function with an equivalent return value. * "_" stands for the dropping of a value. -} -- We export everything module Text.Pandoc.Readers.Odt.Arrows.Utils where import Control.Arrow import Control.Monad ( join, MonadPlus(..) ) import qualified Data.Foldable as F import Text.Pandoc.Readers.Odt.Generic.Fallible import Text.Pandoc.Readers.Odt.Generic.Utils import Text.Pandoc.Compat.Monoid and2 :: (Arrow a) => a b c -> a b c' -> a b (c,c') and2 = (&&&) and3 :: (Arrow a) => a b c0->a b c1->a b c2 -> a b (c0,c1,c2 ) and4 :: (Arrow a) => a b c0->a b c1->a b c2->a b c3 -> a b (c0,c1,c2,c3 ) and5 :: (Arrow a) => a b c0->a b c1->a b c2->a b c3->a b c4 -> a b (c0,c1,c2,c3,c4 ) and6 :: (Arrow a) => a b c0->a b c1->a b c2->a b c3->a b c4->a b c5 -> a b (c0,c1,c2,c3,c4,c5 ) and7 :: (Arrow a) => a b c0->a b c1->a b c2->a b c3->a b c4->a b c5->a b c6 -> a b (c0,c1,c2,c3,c4,c5,c6 ) and8 :: (Arrow a) => a b c0->a b c1->a b c2->a b c3->a b c4->a b c5->a b c6->a b c7 -> a b (c0,c1,c2,c3,c4,c5,c6,c7) and3 a b c = (and2 a b ) &&& c >>^ \((z,y ) , x) -> (z,y,x ) and4 a b c d = (and3 a b c ) &&& d >>^ \((z,y,x ) , w) -> (z,y,x,w ) and5 a b c d e = (and4 a b c d ) &&& e >>^ \((z,y,x,w ) , v) -> (z,y,x,w,v ) and6 a b c d e f = (and5 a b c d e ) &&& f >>^ \((z,y,x,w,v ) , u) -> (z,y,x,w,v,u ) and7 a b c d e f g = (and6 a b c d e f ) &&& g >>^ \((z,y,x,w,v,u ) , t) -> (z,y,x,w,v,u,t ) and8 a b c d e f g h = (and7 a b c d e f g) &&& h >>^ \((z,y,x,w,v,u,t) , s) -> (z,y,x,w,v,u,t,s) liftA2 :: (Arrow a) => (x -> y -> z) -> a b x -> a b y -> a b z liftA2 f a b = a &&& b >>^ uncurry f liftA3 :: (Arrow a) => (z->y->x -> r) -> a b z->a b y->a b x -> a b r liftA4 :: (Arrow a) => (z->y->x->w -> r) -> a b z->a b y->a b x->a b w -> a b r liftA5 :: (Arrow a) => (z->y->x->w->v -> r) -> a b z->a b y->a b x->a b w->a b v -> a b r liftA6 :: (Arrow a) => (z->y->x->w->v->u -> r) -> a b z->a b y->a b x->a b w->a b v->a b u -> a b r liftA7 :: (Arrow a) => (z->y->x->w->v->u->t -> r) -> a b z->a b y->a b x->a b w->a b v->a b u->a b t -> a b r liftA8 :: (Arrow a) => (z->y->x->w->v->u->t->s -> r) -> a b z->a b y->a b x->a b w->a b v->a b u->a b t->a b s -> a b r liftA3 fun a b c = and3 a b c >>^ uncurry3 fun liftA4 fun a b c d = and4 a b c d >>^ uncurry4 fun liftA5 fun a b c d e = and5 a b c d e >>^ uncurry5 fun liftA6 fun a b c d e f = and6 a b c d e f >>^ uncurry6 fun liftA7 fun a b c d e f g = and7 a b c d e f g >>^ uncurry7 fun liftA8 fun a b c d e f g h = and8 a b c d e f g h >>^ uncurry8 fun liftA :: (Arrow a) => (y -> z) -> a b y -> a b z liftA fun a = a >>^ fun -- | Duplicate a value to subsequently feed it into different arrows. -- Can almost always be replaced with '(&&&)', 'keepingTheValue', -- or even '(|||)'. -- Aequivalent to -- > returnA &&& returnA duplicate :: (Arrow a) => a b (b,b) duplicate = arr $ join (,) -- | Lifts the combination of two values into an arrow. joinOn :: (Arrow a) => (x -> y -> z) -> a (x,y) z joinOn = arr.uncurry -- | Applies a function to the uncurried result-pair of an arrow-application. -- (The %-symbol was chosen to evoke an association with pairs.) (>>%) :: (Arrow a) => a x (b,c) -> (b -> c -> d) -> a x d a >>% f = a >>^ uncurry f -- | '(>>%)' with its arguments flipped (%<<) :: (Arrow a) => (b -> c -> d) -> a x (b,c) -> a x d (%<<) = flip (>>%) -- | Precomposition with an uncurried function (%>>) :: (Arrow a) => (b -> c -> d) -> a d r -> a (b,c) r f %>> a = uncurry f ^>> a -- | Precomposition with an uncurried function (right to left variant) (<<%) :: (Arrow a) => a d r -> (b -> c -> d) -> a (b,c) r (<<%) = flip (%>>) infixr 2 >>%, %<<, %>>, <<% -- | Duplicate a value and apply an arrow to the second instance. -- Aequivalent to -- > \a -> duplicate >>> second a -- or -- > \a -> returnA &&& a keepingTheValue :: (Arrow a) => a b c -> a b (b,c) keepingTheValue a = returnA &&& a -- | Duplicate a value and apply an arrow to the first instance. -- Aequivalent to -- > \a -> duplicate >>> first a -- or -- > \a -> a &&& returnA keepingTheValue' :: (Arrow a) => a b c -> a b (c,b) keepingTheValue' a = a &&& returnA -- | 'bind' from the "Maybe"-Monad lifted into an 'ArrowChoice'. -- Actually, it's the more complex '(>=>)', because 'bind' alone does not -- combine as nicely in arrow form. -- The current implementation is not the most efficient one, because it can -- not return directly if a 'Nothing' is encountered. That in turn follows -- from the type system, as 'Nothing' has an "invisible" type parameter that -- can not be dropped early. -- -- Also, there probably is a way to generalize this to other monads -- or applicatives, but I'm leaving that as an exercise to the reader. -- I have a feeling there is a new Arrow-typeclass to be found that is less -- restrictive than 'ArrowApply'. If it is already out there, -- I have not seen it yet. ('ArrowPlus' for example is not general enough.) (>>>=) :: (ArrowChoice a) => a x (Maybe b) -> a b (Maybe c) -> a x (Maybe c) a1 >>>= a2 = a1 >>> maybeToChoice >>> right a2 >>> choiceToMaybe >>^ join infixr 2 >>>= -- | 'mplus' Lifted into an arrow. No 'ArrowPlus' required. -- (But still different from a true bind) (>++<) :: (Arrow a, MonadPlus m) => a x (m b) -> a x (m b) -> a x (m b) (>++<) = liftA2 mplus -- | Left-compose with a pure function leftLift :: (ArrowChoice a) => (l -> l') -> a (Either l r) (Either l' r) leftLift = left.arr -- | Right-compose with a pure function rightLift :: (ArrowChoice a) => (r -> r') -> a (Either l r) (Either l r') rightLift = right.arr ( ^+++ ) :: (ArrowChoice a) => (b -> c) -> a b' c' -> a (Either b b') (Either c c') ( +++^ ) :: (ArrowChoice a) => a b c -> (b' -> c') -> a (Either b b') (Either c c') ( ^+++^ ) :: (ArrowChoice a) => (b -> c) -> (b' -> c') -> a (Either b b') (Either c c') l ^+++ r = leftLift l >>> right r l +++^ r = left l >>> rightLift r l ^+++^ r = leftLift l >>> rightLift r infixr 2 ^+++, +++^, ^+++^ ( ^||| ) :: (ArrowChoice a) => (b -> d) -> a c d -> a (Either b c) d ( |||^ ) :: (ArrowChoice a) => a b d -> (c -> d) -> a (Either b c) d ( ^|||^ ) :: (ArrowChoice a) => (b -> d) -> (c -> d) -> a (Either b c) d l ^||| r = arr l ||| r l |||^ r = l ||| arr r l ^|||^ r = arr l ||| arr r infixr 2 ^||| , |||^, ^|||^ ( ^&&& ) :: (Arrow a) => (b -> c) -> a b c' -> a b (c,c') ( &&&^ ) :: (Arrow a) => a b c -> (b -> c') -> a b (c,c') ( ^&&&^ ) :: (Arrow a) => (b -> c) -> (b -> c') -> a b (c,c') l ^&&& r = arr l &&& r l &&&^ r = l &&& arr r l ^&&&^ r = arr l &&& arr r infixr 3 ^&&&, &&&^, ^&&&^ ( ^*** ) :: (Arrow a) => (b -> c) -> a b' c' -> a (b,b') (c,c') ( ***^ ) :: (Arrow a) => a b c -> (b' -> c') -> a (b,b') (c,c') ( ^***^ ) :: (Arrow a) => (b -> c) -> (b' -> c') -> a (b,b') (c,c') l ^*** r = arr l *** r l ***^ r = l *** arr r l ^***^ r = arr l *** arr r infixr 3 ^***, ***^, ^***^ -- | A version of -- -- >>> \p -> arr (\x -> if p x the Right x else Left x) -- -- but with p being an arrow choose :: (ArrowChoice a) => a b Bool -> a b (Either b b) choose checkValue = keepingTheValue checkValue >>^ select where select (x,True ) = Right x select (x,False ) = Left x -- | Converts @Right a@ into @Just a@ and @Left _@ into @Nothing@. choiceToMaybe :: (ArrowChoice a) => a (Either l r) (Maybe r) choiceToMaybe = arr eitherToMaybe -- | Converts @Nothing@ into @Left ()@ and @Just a@ into @Right a@. maybeToChoice :: (ArrowChoice a) => a (Maybe b) (Fallible b) maybeToChoice = arr maybeToEither -- | Lifts a constant value into an arrow returnV :: (Arrow a) => c -> a x c returnV = arr.const -- | 'returnA' dropping everything returnA_ :: (Arrow a) => a _b () returnA_ = returnV () -- | Wrapper for an arrow that can be evaluated im parallel. All -- Arrows can be evaluated in parallel, as long as they return a -- monoid. newtype ParallelArrow a b c = CoEval { evalParallelArrow :: a b c } deriving (Eq, Ord, Show) instance (Arrow a, Monoid m) => Monoid (ParallelArrow a b m) where mempty = CoEval $ returnV mempty (CoEval a) `mappend` (CoEval ~b) = CoEval $ a &&& b >>% mappend -- | Evaluates a collection of arrows in a parallel fashion. -- -- This is in essence a fold of '(&&&)' over the collection, -- so the actual execution order and parallelity depends on the -- implementation of '(&&&)' in the arrow in question. -- The default implementation of '(&&&)' for example keeps the -- order as given in the collection. -- -- This function can be seen as a generalization of -- 'Control.Applicative.sequenceA' to arrows or as an alternative to -- a fold with 'Control.Applicative.WrappedArrow', which -- substitutes the monoid with function application. -- coEval :: (Arrow a, F.Foldable f, Monoid m) => f (a b m) -> a b m coEval = evalParallelArrow . (F.foldMap CoEval) -- | Defines Left as failure, Right as success type FallibleArrow a input failure success = a input (Either failure success) type ReFallibleArrow a failure success success' = FallibleArrow a (Either failure success) failure success' -- | Wrapper for fallible arrows. Fallible arrows are all arrows that return -- an Either value where left is a faliure and right is a success value. newtype AlternativeArrow a input failure success = TryArrow { evalAlternativeArrow :: FallibleArrow a input failure success } instance (ArrowChoice a, Monoid failure) => Monoid (AlternativeArrow a input failure success) where mempty = TryArrow $ returnV $ Left mempty (TryArrow a) `mappend` (TryArrow b) = TryArrow $ a &&& b >>^ \(a',~b') -> ( (\a'' -> left (mappend a'') b') ||| Right ) a' -- | Evaluates a collection of fallible arrows, trying each one in succession. -- Left values are interpreted as failures, right values as successes. -- -- The evaluation is stopped once an arrow succeeds. -- Up to that point, all failures are collected in the failure-monoid. -- Note that '()' is a monoid, and thus can serve as a failure-collector if -- you are uninterested in the exact failures. -- -- This is in essence a fold of '(&&&)' over the collection, enhanced with a -- little bit of repackaging, so the actual execution order depends on the -- implementation of '(&&&)' in the arrow in question. -- The default implementation of '(&&&)' for example keeps the -- order as given in the collection. -- tryArrows :: (ArrowChoice a, F.Foldable f, Monoid failure) => f (FallibleArrow a b failure success) -> FallibleArrow a b failure success tryArrows = evalAlternativeArrow . (F.foldMap TryArrow) -- liftSuccess :: (ArrowChoice a) => (success -> success') -> ReFallibleArrow a failure success success' liftSuccess = rightLift -- liftAsSuccess :: (ArrowChoice a) => a x success -> FallibleArrow a x failure success liftAsSuccess a = a >>^ Right -- asFallibleArrow :: (ArrowChoice a) => a x success -> FallibleArrow a x failure success asFallibleArrow a = a >>^ Right -- | Raises an error into a 'ReFallibleArrow' if the arrow is already in -- "error mode" liftError :: (ArrowChoice a, Monoid failure) => failure -> ReFallibleArrow a failure success success liftError e = leftLift (e <>) -- | Raises an error into a 'FallibleArrow', droping both the arrow input -- and any previously stored error value. _raiseA :: (ArrowChoice a) => failure -> FallibleArrow a x failure success _raiseA e = returnV (Left e) -- | Raises an empty error into a 'FallibleArrow', droping both the arrow input -- and any previously stored error value. _raiseAEmpty :: (ArrowChoice a, Monoid failure) => FallibleArrow a x failure success _raiseAEmpty = _raiseA mempty -- | Raises an error into a 'ReFallibleArrow', possibly appending the new error -- to an existing one raiseA :: (ArrowChoice a, Monoid failure) => failure -> ReFallibleArrow a failure success success raiseA e = arr $ Left.(either (<> e) (const e)) -- | Raises an empty error into a 'ReFallibleArrow'. If there already is an -- error, nothing changes. -- (Note that this function is only aequivalent to @raiseA mempty@ iff the -- failure monoid follows the monoid laws.) raiseAEmpty :: (ArrowChoice a, Monoid failure) => ReFallibleArrow a failure success success raiseAEmpty = arr (fromRight (const mempty) >>> Left) -- | Execute the second arrow if the first succeeds (>>?) :: (ArrowChoice a) => FallibleArrow a x failure success -> FallibleArrow a success failure success' -> FallibleArrow a x failure success' a >>? b = a >>> Left ^||| b -- | Execute the lifted second arrow if the first succeeds (>>?^) :: (ArrowChoice a) => FallibleArrow a x failure success -> (success -> success') -> FallibleArrow a x failure success' a >>?^ f = a >>^ Left ^|||^ Right . f -- | Execute the lifted second arrow if the first succeeds (>>?^?) :: (ArrowChoice a) => FallibleArrow a x failure success -> (success -> Either failure success') -> FallibleArrow a x failure success' a >>?^? b = a >>> Left ^|||^ b -- | Execute the second arrow if the lifted first arrow succeeds (^>>?) :: (ArrowChoice a) => (x -> Either failure success) -> FallibleArrow a success failure success' -> FallibleArrow a x failure success' a ^>>? b = a ^>> Left ^||| b -- | Execute the lifted second arrow if the lifted first arrow succeeds (^>>?^) :: (ArrowChoice a) => (x -> Either failure success) -> (success -> success') -> FallibleArrow a x failure success' a ^>>?^ f = arr $ a >>> right f -- | Execute the lifted second arrow if the lifted first arrow succeeds (^>>?^?) :: (ArrowChoice a) => (x -> Either failure success) -> (success -> Either failure success') -> FallibleArrow a x failure success' a ^>>?^? f = a ^>> Left ^|||^ f -- | Execute the second, non-fallible arrow if the first arrow succeeds (>>?!) :: (ArrowChoice a) => FallibleArrow a x failure success -> a success success' -> FallibleArrow a x failure success' a >>?! f = a >>> right f --- (>>?%) :: (ArrowChoice a, Monoid f) => FallibleArrow a x f (b,b') -> (b -> b' -> c) -> FallibleArrow a x f c a >>?% f = a >>?^ (uncurry f) --- (^>>?%) :: (ArrowChoice a, Monoid f) => (x -> Either f (b,b')) -> (b -> b' -> c) -> FallibleArrow a x f c a ^>>?% f = arr a >>?^ (uncurry f) --- (>>?%?) :: (ArrowChoice a, Monoid f) => FallibleArrow a x f (b,b') -> (b -> b' -> (Either f c)) -> FallibleArrow a x f c a >>?%? f = a >>?^? (uncurry f) infixr 1 >>?, >>?^, >>?^? infixr 1 ^>>?, ^>>?^, ^>>?^?, >>?! infixr 1 >>?%, ^>>?%, >>?%? -- | Keep values that are Right, replace Left values by a constant. ifFailedUse :: (ArrowChoice a) => v -> a (Either f v) v ifFailedUse v = arr $ either (const v) id -- | '(&&)' lifted into an arrow (<&&>) :: (Arrow a) => a x Bool -> a x Bool -> a x Bool (<&&>) = liftA2 (&&) -- | '(||)' lifted into an arrow (<||>) :: (Arrow a) => a x Bool -> a x Bool -> a x Bool (<||>) = liftA2 (||) -- | An equivalent of '(&&)' in a fallible arrow (>&&<) :: (ArrowChoice a, Monoid f) => FallibleArrow a x f s -> FallibleArrow a x f s' -> FallibleArrow a x f (s,s') (>&&<) = liftA2 chooseMin -- | An equivalent of '(||)' in some forms of fallible arrows (>||<) :: (ArrowChoice a, Monoid f, Monoid s) => FallibleArrow a x f s -> FallibleArrow a x f s -> FallibleArrow a x f s (>||<) = liftA2 chooseMax -- | An arrow version of a short-circuit (<|>) ifFailedDo :: (ArrowChoice a) => FallibleArrow a x f y -> FallibleArrow a x f y -> FallibleArrow a x f y ifFailedDo a b = keepingTheValue a >>> repackage ^>> (b |||^ Right) where repackage (x , Left _) = Left x repackage (_ , Right y) = Right y infixr 4 <&&>, <||>, >&&<, >||< infixr 1 `ifFailedDo`