{-# OPTIONS_GHC -cpp #-} {-# LANGUAGE RankNTypes #-} ----------------------------------------------------------------------------- -- | -- Module : Data.Generics.Aliases -- Copyright : (c) The University of Glasgow, CWI 2001--2004 -- License : BSD-style (see the LICENSE file) -- -- Maintainer : generics@haskell.org -- Stability : experimental -- Portability : non-portable (local universal quantification) -- -- \"Scrap your boilerplate\" --- Generic programming in Haskell -- See <http://www.cs.uu.nl/wiki/GenericProgramming/SYB>. -- The present module provides a number of declarations for typical generic -- function types, corresponding type case, and others. -- ----------------------------------------------------------------------------- module Data.Generics.Aliases ( -- * Combinators to \"make\" generic functions via cast mkT, mkQ, mkM, mkMp, mkR, ext0, extT, extQ, extM, extMp, extB, extR, -- * Type synonyms for generic function types GenericT, GenericQ, GenericM, GenericB, GenericR, Generic, Generic'(..), GenericT'(..), GenericQ'(..), GenericM'(..), -- * Ingredients of generic functions orElse, -- * Function combinators on generic functions recoverMp, recoverQ, choiceMp, choiceQ, -- * Type extension for unary type constructors ext1, ext1T, ext1M, ext1Q, ext1R, ext1B, -- * Type extension for binary type constructors ext2T, ext2M, ext2Q, ext2R, ext2B ) where #ifdef __HADDOCK__ import Prelude #endif import Control.Monad import Data.Data ------------------------------------------------------------------------------ -- -- Combinators to "make" generic functions -- We use type-safe cast in a number of ways to make generic functions. -- ------------------------------------------------------------------------------ -- | Make a generic transformation; -- start from a type-specific case; -- preserve the term otherwise -- mkT :: ( Typeable a , Typeable b ) => (b -> b) -> a -> a mkT = extT id -- | Make a generic query; -- start from a type-specific case; -- return a constant otherwise -- mkQ :: ( Typeable a , Typeable b ) => r -> (b -> r) -> a -> r (r `mkQ` br) a = case cast a of Just b -> br b Nothing -> r -- | Make a generic monadic transformation; -- start from a type-specific case; -- resort to return otherwise -- mkM :: ( Monad m , Typeable a , Typeable b ) => (b -> m b) -> a -> m a mkM = extM return {- For the remaining definitions, we stick to a more concise style, i.e., we fold maybes with "maybe" instead of case ... of ..., and we also use a point-free style whenever possible. -} -- | Make a generic monadic transformation for MonadPlus; -- use \"const mzero\" (i.e., failure) instead of return as default. -- mkMp :: ( MonadPlus m , Typeable a , Typeable b ) => (b -> m b) -> a -> m a mkMp = extM (const mzero) -- | Make a generic builder; -- start from a type-specific ase; -- resort to no build (i.e., mzero) otherwise -- mkR :: ( MonadPlus m , Typeable a , Typeable b ) => m b -> m a mkR f = mzero `extR` f -- | Flexible type extension ext0 :: (Typeable a, Typeable b) => c a -> c b -> c a ext0 def ext = maybe def id (gcast ext) -- | Extend a generic transformation by a type-specific case extT :: ( Typeable a , Typeable b ) => (a -> a) -> (b -> b) -> a -> a extT def ext = unT ((T def) `ext0` (T ext)) -- | Extend a generic query by a type-specific case extQ :: ( Typeable a , Typeable b ) => (a -> q) -> (b -> q) -> a -> q extQ f g a = maybe (f a) g (cast a) -- | Extend a generic monadic transformation by a type-specific case extM :: ( Monad m , Typeable a , Typeable b ) => (a -> m a) -> (b -> m b) -> a -> m a extM def ext = unM ((M def) `ext0` (M ext)) -- | Extend a generic MonadPlus transformation by a type-specific case extMp :: ( MonadPlus m , Typeable a , Typeable b ) => (a -> m a) -> (b -> m b) -> a -> m a extMp = extM -- | Extend a generic builder extB :: ( Typeable a , Typeable b ) => a -> b -> a extB a = maybe a id . cast -- | Extend a generic reader extR :: ( Monad m , Typeable a , Typeable b ) => m a -> m b -> m a extR def ext = unR ((R def) `ext0` (R ext)) ------------------------------------------------------------------------------ -- -- Type synonyms for generic function types -- ------------------------------------------------------------------------------ -- | Generic transformations, -- i.e., take an \"a\" and return an \"a\" -- type GenericT = forall a. Data a => a -> a -- | Generic queries of type \"r\", -- i.e., take any \"a\" and return an \"r\" -- type GenericQ r = forall a. Data a => a -> r -- | Generic monadic transformations, -- i.e., take an \"a\" and compute an \"a\" -- type GenericM m = forall a. Data a => a -> m a -- | Generic builders -- i.e., produce an \"a\". -- type GenericB = forall a. Data a => a -- | Generic readers, say monadic builders, -- i.e., produce an \"a\" with the help of a monad \"m\". -- type GenericR m = forall a. Data a => m a -- | The general scheme underlying generic functions -- assumed by gfoldl; there are isomorphisms such as -- GenericT = Generic T. -- type Generic c = forall a. Data a => a -> c a -- | Wrapped generic functions; -- recall: [Generic c] would be legal but [Generic' c] not. -- data Generic' c = Generic' { unGeneric' :: Generic c } -- | Other first-class polymorphic wrappers newtype GenericT' = GT { unGT :: forall a. Data a => a -> a } newtype GenericQ' r = GQ { unGQ :: GenericQ r } newtype GenericM' m = GM { unGM :: forall a. Data a => a -> m a } -- | Left-biased choice on maybes orElse :: Maybe a -> Maybe a -> Maybe a x `orElse` y = case x of Just _ -> x Nothing -> y {- The following variations take "orElse" to the function level. Furthermore, we generalise from "Maybe" to any "MonadPlus". This makes sense for monadic transformations and queries. We say that the resulting combinators modell choice. We also provide a prime example of choice, that is, recovery from failure. In the case of transformations, we recover via return whereas for queries a given constant is returned. -} -- | Choice for monadic transformations choiceMp :: MonadPlus m => GenericM m -> GenericM m -> GenericM m choiceMp f g x = f x `mplus` g x -- | Choice for monadic queries choiceQ :: MonadPlus m => GenericQ (m r) -> GenericQ (m r) -> GenericQ (m r) choiceQ f g x = f x `mplus` g x -- | Recover from the failure of monadic transformation by identity recoverMp :: MonadPlus m => GenericM m -> GenericM m recoverMp f = f `choiceMp` return -- | Recover from the failure of monadic query by a constant recoverQ :: MonadPlus m => r -> GenericQ (m r) -> GenericQ (m r) recoverQ r f = f `choiceQ` const (return r) ------------------------------------------------------------------------------ -- Type extension for unary type constructors ------------------------------------------------------------------------------ -- | Flexible type extension ext1 :: (Data a, Typeable1 t) => c a -> (forall d. Data d => c (t d)) -> c a ext1 def ext = maybe def id (dataCast1 ext) -- | Type extension of transformations for unary type constructors ext1T :: (Data d, Typeable1 t) => (forall e. Data e => e -> e) -> (forall f. Data f => t f -> t f) -> d -> d ext1T def ext = unT ((T def) `ext1` (T ext)) -- | Type extension of monadic transformations for type constructors ext1M :: (Monad m, Data d, Typeable1 t) => (forall e. Data e => e -> m e) -> (forall f. Data f => t f -> m (t f)) -> d -> m d ext1M def ext = unM ((M def) `ext1` (M ext)) -- | Type extension of queries for type constructors ext1Q :: (Data d, Typeable1 t) => (d -> q) -> (forall e. Data e => t e -> q) -> d -> q ext1Q def ext = unQ ((Q def) `ext1` (Q ext)) -- | Type extension of readers for type constructors ext1R :: (Monad m, Data d, Typeable1 t) => m d -> (forall e. Data e => m (t e)) -> m d ext1R def ext = unR ((R def) `ext1` (R ext)) -- | Type extension of builders for type constructors ext1B :: (Data a, Typeable1 t) => a -> (forall b. Data b => (t b)) -> a ext1B def ext = unB ((B def) `ext1` (B ext)) ------------------------------------------------------------------------------ -- Type extension for binary type constructors ------------------------------------------------------------------------------ -- | Flexible type extension ext2 :: (Data a, Typeable2 t) => c a -> (forall d1 d2. (Data d1, Data d2) => c (t d1 d2)) -> c a ext2 def ext = maybe def id (dataCast2 ext) -- | Type extension of transformations for unary type constructors ext2T :: (Data d, Typeable2 t) => (forall e. Data e => e -> e) -> (forall d1 d2. (Data d1, Data d2) => t d1 d2 -> t d1 d2) -> d -> d ext2T def ext = unT ((T def) `ext2` (T ext)) -- | Type extension of monadic transformations for type constructors ext2M :: (Monad m, Data d, Typeable2 t) => (forall e. Data e => e -> m e) -> (forall d1 d2. (Data d1, Data d2) => t d1 d2 -> m (t d1 d2)) -> d -> m d ext2M def ext = unM ((M def) `ext2` (M ext)) -- | Type extension of queries for type constructors ext2Q :: (Data d, Typeable2 t) => (d -> q) -> (forall d1 d2. (Data d1, Data d2) => t d1 d2 -> q) -> d -> q ext2Q def ext = unQ ((Q def) `ext2` (Q ext)) -- | Type extension of readers for type constructors ext2R :: (Monad m, Data d, Typeable2 t) => m d -> (forall d1 d2. (Data d1, Data d2) => m (t d1 d2)) -> m d ext2R def ext = unR ((R def) `ext2` (R ext)) -- | Type extension of builders for type constructors ext2B :: (Data a, Typeable2 t) => a -> (forall d1 d2. (Data d1, Data d2) => (t d1 d2)) -> a ext2B def ext = unB ((B def) `ext2` (B ext)) ------------------------------------------------------------------------------ -- -- Type constructors for type-level lambdas -- ------------------------------------------------------------------------------ -- | The type constructor for transformations newtype T x = T { unT :: x -> x } -- | The type constructor for transformations newtype M m x = M { unM :: x -> m x } -- | The type constructor for queries newtype Q q x = Q { unQ :: x -> q } -- | The type constructor for readers newtype R m x = R { unR :: m x } -- | The type constructor for builders newtype B x = B {unB :: x}