-- For the Show (Fix f) instance {-# LANGUAGE UndecidableInstances #-} -- For 'build' and 'hmap' {-# LANGUAGE Rank2Types #-} -- Unfortunately GHC < 6.10 needs -fglasgow-exts in order to actually -- parse RULES (see -ddump-rules); the -frewrite-rules flag only -- enables the application of rules, instead of doing what we want. -- Apparently this is fixed in 6.10. In newer GHC (e.g., 7.6.1) the -- -frewrite-rules flag is deprecated in favor of -fenable-rewrite-rules. -- It's unclear whether we can use CPP to switch between -fglasgow-exts -- -frewrite-rules and -fenable-rewrite-rules based on the GHC -- version... -- -- http://hackage.haskell.org/trac/ghc/ticket/2213 -- http://www.mail-archive.com/glasgow-haskell-users@haskell.org/msg14313.html {-# OPTIONS_GHC -O2 -fenable-rewrite-rules #-} -- NOTE #1: on GHC >= 7.8 we need to eta expand rules to avoid a -- warning about the fact that the rule may never fire because (.) -- might inline first... {-# OPTIONS_GHC -Wall -fwarn-tabs #-} ---------------------------------------------------------------- -- 2014.05.28 -- | -- Module : Data.Functor.Fixedpoint -- Copyright : Copyright (c) 2007--2014 wren gayle romano -- License : BSD -- Maintainer : wren@community.haskell.org -- Stability : provisional -- Portability : semi-portable (Rank2Types) -- -- This module provides a fixed point operator on functor types. -- For Haskell the least and greatest fixed points coincide, so we -- needn't distinguish them. This abstract nonsense is helpful in -- conjunction with other category theoretic tricks like Swierstra's -- functor coproducts (not provided by this package). For more on -- the utility of two-level recursive types, see: -- -- * Tim Sheard (2001) /Generic Unification via Two-Level Types/ -- /and Paramterized Modules/, Functional Pearl, ICFP. -- -- * Tim Sheard & Emir Pasalic (2004) /Two-Level Types and/ -- /Parameterized Modules/. JFP 14(5): 547--587. This is -- an expanded version of Sheard (2001) with new examples. -- -- * Wouter Swierstra (2008) /Data types a la carte/, Functional -- Pearl. JFP 18: 423--436. ---------------------------------------------------------------- module Data.Functor.Fixedpoint ( -- * Fixed point operator for functors Fix(..) -- * Maps , hmap, hmapM , ymap, ymapM -- * Builders , build -- * Catamorphisms , cata, cataM , ycata, ycataM -- * Anamorphisms , ana, anaM -- * Hylomorphisms , hylo, hyloM ) where import Prelude hiding (mapM, sequence) import Control.Monad hiding (mapM, sequence) import Data.Traversable ---------------------------------------------------------------- ---------------------------------------------------------------- -- | @Fix f@ is a fix point of the 'Functor' @f@. Note that in -- Haskell the least and greatest fixed points coincide, so we don't -- need to distinguish between @Mu f@ and @Nu f@. This type used -- to be called @Y@, hence the naming convention for all the @yfoo@ -- functions. -- -- This type lets us invoke category theory to get recursive types -- and operations over them without the type checker complaining -- about infinite types. The 'Show' instance doesn't print the -- constructors, for legibility. newtype Fix f = Fix { unFix :: f (Fix f) } -- This requires UndecidableInstances because the context is larger -- than the head and so GHC can't guarantee that the instance safely -- terminates. It is in fact safe, however. instance (Show (f (Fix f))) => Show (Fix f) where showsPrec p (Fix f) = showsPrec p f instance (Eq (f (Fix f))) => Eq (Fix f) where Fix x == Fix y = x == y Fix x /= Fix y = x /= y instance (Ord (f (Fix f))) => Ord (Fix f) where Fix x `compare` Fix y = x `compare` y Fix x > Fix y = x > y Fix x >= Fix y = x >= y Fix x <= Fix y = x <= y Fix x < Fix y = x < y Fix x `max` Fix y = Fix (max x y) Fix x `min` Fix y = Fix (min x y) ---------------------------------------------------------------- -- | A higher-order map taking a natural transformation @(f -> g)@ -- and lifting it to operate on @Fix@. hmap :: (Functor f, Functor g) => (forall a. f a -> g a) -> Fix f -> Fix g {-# INLINE [0] hmap #-} hmap eps = ana (eps . unFix) -- == cata (Fix . eps) -- But the anamorphism is a better producer. {-# RULES "hmap id" hmap id = id -- cf., NOTE #1 "hmap-compose" forall (eps :: forall a. g a -> h a) (eta :: forall a. f a -> g a) x. hmap eps (hmap eta x) = hmap (eps . eta) x #-} -- | A monadic variant of 'hmap'. hmapM :: (Functor f, Traversable g, Monad m) => (forall a. f a -> m (g a)) -> Fix f -> m (Fix g) {-# INLINE [0] hmapM #-} hmapM eps = anaM (eps . unFix) {-# RULES "hmapM return" hmapM return = return -- "hmapM-compose" -- forall eps eta. -- hmap eps <=< hmap eta = hmapM (eps <=< eta) #-} -- | A version of 'fmap' for endomorphisms on the fixed point. That -- is, this maps the function over the first layer of recursive -- structure. ymap :: (Functor f) => (Fix f -> Fix f) -> Fix f -> Fix f {-# INLINE [0] ymap #-} ymap f = Fix . fmap f . unFix {-# RULES "ymap id" ymap id = id -- cf., NOTE #1 "ymap-compose" forall f g x. ymap f (ymap g x) = ymap (f . g) x #-} -- | A monadic variant of 'ymap'. ymapM :: (Traversable f, Monad m) => (Fix f -> m (Fix f)) -> Fix f -> m (Fix f) {-# INLINE [0] ymapM #-} ymapM f = liftM Fix . mapM f . unFix {-# RULES "ymapM id" ymapM return = return -- "ymapM-compose" -- forall f g. -- ymapM f <=< ymapM g = ymapM (f <=< g) #-} ---------------------------------------------------------------- -- BUG: this isn't as helful as normal build\/fold fusion as in Data.Functor.Fusable -- -- | Take a Church encoding of a fixed point into the data -- representation of the fixed point. build :: (Functor f) => (forall r. (f r -> r) -> r) -> Fix f {-# INLINE [0] build #-} build g = g Fix -- N.B., the signature is required on @g@ in order to be Rank-2. -- The signature is required on @phi@ in order to bring @f@ into -- scope. Otherwise we'd need -XScopedTypeVariables. {-# RULES "build/cata" [1] forall (phi :: f a -> a) (g :: forall r. (f r -> r) -> r). cata phi (build g) = g phi #-} ---------------------------------------------------------------- -- | A pure catamorphism over the least fixed point of a functor. -- This function applies the @f@-algebra from the bottom up over -- @Fix f@ to create some residual value. cata :: (Functor f) => (f a -> a) -> (Fix f -> a) {-# INLINE [0] cata #-} cata phi = self where self = phi . fmap self . unFix {-# RULES "cata-refl" cata Fix = id -- cf., NOTE #1 "cata-compose" forall (eps :: forall a. f a -> g a) phi x. cata phi (cata (Fix . eps) x) = cata (phi . eps) x #-} -- We can't really use this one because of the implication constraint {- RULES "cata-fusion" forall f phi. (f . phi) == (phi . fmap f) ==> f . cata phi = cata phi -} -- | A catamorphism for monadic @f@-algebras. Alas, this isn't wholly -- generic to @Functor@ since it requires distribution of @f@ over -- @m@ (provided by 'sequence' or 'mapM' in 'Traversable'). -- -- N.B., this orders the side effects from the bottom up. cataM :: (Traversable f, Monad m) => (f a -> m a) -> (Fix f -> m a) {-# INLINE [0] cataM #-} cataM phiM = self where self = phiM <=< (mapM self . unFix) -- TODO: other rules for cataM {-# RULES "cataM-refl" cataM (return . Fix) = return #-} -- TODO: remove this, or add similar versions for ana* and hylo*? -- | A variant of 'cata' which restricts the return type to being -- a new fixpoint. Though more restrictive, it can be helpful when -- you already have an algebra which expects the outermost @Fix@. -- -- If you don't like either @fmap@ or @cata@, then maybe this is -- what you were thinking? ycata :: (Functor f) => (Fix f -> Fix f) -> Fix f -> Fix f {-# INLINE ycata #-} ycata f = cata (f . Fix) -- TODO: remove this, or add similar versions for ana* and hylo*? -- | Monadic variant of 'ycata'. ycataM :: (Traversable f, Monad m) => (Fix f -> m (Fix f)) -> Fix f -> m (Fix f) {-# INLINE ycataM #-} ycataM f = cataM (f . Fix) ---------------------------------------------------------------- -- | A pure anamorphism generating the greatest fixed point of a -- functor. This function applies an @f@-coalgebra from the top -- down to expand a seed into a @Fix f@. ana :: (Functor f) => (a -> f a) -> (a -> Fix f) {-# INLINE [0] ana #-} ana psi = self where self = Fix . fmap self . psi {-# RULES "ana-refl" ana unFix = id -- BUG: I think I dualized this right... -- cf., NOTE #1 "ana-compose" forall (eps :: forall a. f a -> g a) psi x. ana (eps . unFix) (ana psi x) = ana (eps . psi) x #-} -- We can't really use this because of the implication constraint {- RULES -- BUG: I think I dualized this right... "ana-fusion" forall f psi. (psi . f) == (fmap f . psi) ==> ana psi . f = ana psi -} -- | An anamorphism for monadic @f@-coalgebras. Alas, this isn't -- wholly generic to @Functor@ since it requires distribution of -- @f@ over @m@ (provided by 'sequence' or 'mapM' in 'Traversable'). -- -- N.B., this orders the side effects from the top down. anaM :: (Traversable f, Monad m) => (a -> m (f a)) -> (a -> m (Fix f)) {-# INLINE anaM #-} anaM psiM = self where self = (liftM Fix . mapM self) <=< psiM ---------------------------------------------------------------- -- Is this even worth mentioning? We can amortize the construction -- of @Fix f@ (which we'd do anyways because of laziness), but we -- can't fuse the @f@ away unless we inline all of @psi@, @fmap@, -- and @phi@ at the use sites. Will inlining this definition be -- sufficient to do that? -- | @hylo phi psi == cata phi . ana psi@ hylo :: (Functor f) => (f b -> b) -> (a -> f a) -> (a -> b) {-# INLINE hylo #-} hylo phi psi = self where self = phi . fmap self . psi -- TODO: rules for hylo? -- | @hyloM phiM psiM == cataM phiM <=< anaM psiM@ hyloM :: (Traversable f, Monad m) => (f b -> m b) -> (a -> m (f a)) -> (a -> m b) {-# INLINE hyloM #-} hyloM phiM psiM = self where self = phiM <=< mapM self <=< psiM -- TODO: rules for hyloM? ---------------------------------------------------------------- ----------------------------------------------------------- fin.