Plan 9 from Bell Labs’s /usr/web/sources/contrib/fernan/nhc98/src/libraries/base/Data/Generics/Twins.hs

Copyright © 2021 Plan 9 Foundation.
Distributed under the MIT License.
Download the Plan 9 distribution.


-----------------------------------------------------------------------------
-- |
-- Module      :  Data.Generics.Twins
-- Copyright   :  (c) The University of Glasgow, CWI 2001--2004
-- License     :  BSD-style (see the file libraries/base/LICENSE)
-- 
-- Maintainer  :  libraries@haskell.org
-- Stability   :  experimental
-- Portability :  non-portable (local universal quantification)
--
-- \"Scrap your boilerplate\" --- Generic programming in Haskell 
-- See <http://www.cs.vu.nl/boilerplate/>. The present module 
-- provides support for multi-parameter traversal, which is also 
-- demonstrated with generic operations like equality.
--
-----------------------------------------------------------------------------

module Data.Generics.Twins ( 

	-- * Generic folds and maps that also accumulate
	gfoldlAccum,
	gmapAccumT,
	gmapAccumM,
	gmapAccumQl,
	gmapAccumQr,
	gmapAccumQ,

	-- * Mapping combinators for twin traversal
	gzipWithT,
  	gzipWithM,
  	gzipWithQ,

	-- * Typical twin traversals
	geq,
	gzip

  ) where


------------------------------------------------------------------------------

#ifdef __HADDOCK__
import Prelude
#endif
import Data.Generics.Basics
import Data.Generics.Aliases

#ifdef __GLASGOW_HASKELL__
import Prelude hiding ( GT )
#endif

------------------------------------------------------------------------------


------------------------------------------------------------------------------
--
--	Generic folds and maps that also accumulate
--
------------------------------------------------------------------------------

{--------------------------------------------------------------

A list map can be elaborated to perform accumulation.
In the same sense, we can elaborate generic maps over terms.

We recall the type of map:
map :: (a -> b) -> [a] -> [b]

We recall the type of an accumulating map (see Data.List):
mapAccumL :: (a -> b -> (a,c)) -> a -> [b] -> (a,[c])

Applying the same scheme we obtain an accumulating gfoldl.

--------------------------------------------------------------}

-- | gfoldl with accumulation

gfoldlAccum :: Data d
            => (forall d r. Data d => a -> c (d -> r) -> d -> (a, c r))
            -> (forall g. a -> g -> (a, c g))
            -> a -> d -> (a, c d)

gfoldlAccum k z a d = unA (gfoldl k' z' d) a
 where
  k' c y = A (\a -> let (a', c') = unA c a in k a' c' y)
  z' f   = A (\a -> z a f)


-- | A type constructor for accumulation
newtype A a c d = A { unA :: a -> (a, c d) }


-- | gmapT with accumulation
gmapAccumT :: Data d
           => (forall d. Data d => a -> d -> (a,d))
           -> a -> d -> (a, d)
gmapAccumT f a d = let (a',d') = gfoldlAccum k z a d
                    in (a',unID d')
 where
  k a (ID c) d = let (a',d') = f a d 
                  in (a', ID (c d'))
  z a x = (a, ID x)


-- | gmapM with accumulation
gmapAccumM :: (Data d, Monad m)
           => (forall d. Data d => a -> d -> (a, m d))
           -> a -> d -> (a, m d)
gmapAccumM f = gfoldlAccum k z
 where
  k a c d = let (a',d') = f a d 
             in (a', d' >>= \d'' -> c >>= \c' -> return (c' d''))
  z a x = (a, return x)


-- | gmapQl with accumulation
gmapAccumQl :: Data d 
            => (r -> r' -> r) 
            -> r
            -> (forall d. Data d => a -> d -> (a,r'))
            -> a -> d -> (a, r)
gmapAccumQl o r f a d = let (a',r) = gfoldlAccum k z a d
                         in (a',unCONST r)
 where
  k a (CONST c) d = let (a',r') = f a d 
                     in (a', CONST (c `o` r'))
  z a _ = (a, CONST r)


-- | gmapQr with accumulation
gmapAccumQr :: Data d 
            => (r' -> r -> r) 
            -> r
            -> (forall d. Data d => a -> d -> (a,r'))
            -> a -> d -> (a, r)
gmapAccumQr o r f a d = let (a',l) = gfoldlAccum k z a d
                         in (a',unQr l r)
 where
  k a (Qr c) d = let (a',r') = f a d 
                  in (a', Qr (\r -> c (r' `o` r)))
  z a _ = (a, Qr id)


-- | gmapQ with accumulation
gmapAccumQ :: Data d
           => (forall d. Data d => a -> d -> (a,q))
           -> a -> d -> (a, [q])
gmapAccumQ f = gmapAccumQr (:) [] f



------------------------------------------------------------------------------
--
--	Helper type constructors
--
------------------------------------------------------------------------------


-- | The identity type constructor needed for the definition of gmapAccumT
newtype ID x = ID { unID :: x }


-- | The constant type constructor needed for the definition of gmapAccumQl
newtype CONST c a = CONST { unCONST :: c }


-- | The type constructor needed for the definition of gmapAccumQr
newtype Qr r a = Qr { unQr  :: r -> r }



------------------------------------------------------------------------------
--
--	Mapping combinators for twin traversal
--
------------------------------------------------------------------------------


-- | Twin map for transformation 
gzipWithT :: GenericQ (GenericT) -> GenericQ (GenericT)
gzipWithT f x y = case gmapAccumT perkid funs y of
                    ([], c) -> c
                    _       -> error "gzipWithT" 
 where
  perkid a d = (tail a, unGT (head a) d)
  funs = gmapQ (\k -> GT (f k)) x



-- | Twin map for monadic transformation 
gzipWithM :: Monad m => GenericQ (GenericM m) -> GenericQ (GenericM m)
gzipWithM f x y = case gmapAccumM perkid funs y of
                    ([], c) -> c
                    _       -> error "gzipWithM" 
 where
  perkid a d = (tail a, unGM (head a) d)
  funs = gmapQ (\k -> GM (f k)) x


-- | Twin map for queries
gzipWithQ :: GenericQ (GenericQ r) -> GenericQ (GenericQ [r])
gzipWithQ f x y = case gmapAccumQ perkid funs y of
                   ([], r) -> r
                   _       -> error "gzipWithQ" 
 where
  perkid a d = (tail a, unGQ (head a) d)
  funs = gmapQ (\k -> GQ (f k)) x



------------------------------------------------------------------------------
--
--	Typical twin traversals
--
------------------------------------------------------------------------------

-- | Generic equality: an alternative to \"deriving Eq\"
geq :: Data a => a -> a -> Bool

{-

Testing for equality of two terms goes like this. Firstly, we
establish the equality of the two top-level datatype
constructors. Secondly, we use a twin gmap combinator, namely tgmapQ,
to compare the two lists of immediate subterms.

(Note for the experts: the type of the worker geq' is rather general
but precision is recovered via the restrictive type of the top-level
operation geq. The imprecision of geq' is caused by the type system's
unability to express the type equivalence for the corresponding
couples of immediate subterms from the two given input terms.)

-}

geq x y = geq' x y
  where
    geq' :: GenericQ (GenericQ Bool)
    geq' x y =     (toConstr x == toConstr y)
                && and (gzipWithQ geq' x y)


-- | Generic zip controlled by a function with type-specific branches
gzip :: GenericQ (GenericM Maybe) -> GenericQ (GenericM Maybe)
-- See testsuite/.../Generics/gzip.hs for an illustration
gzip f x y = 
  f x y
  `orElse`
  if toConstr x == toConstr y
    then gzipWithM (gzip f) x y
    else Nothing

Bell Labs OSI certified Powered by Plan 9

(Return to Plan 9 Home Page)

Copyright © 2021 Plan 9 Foundation. All Rights Reserved.
Comments to webmaster@9p.io.