{-# LANGUAGE CPP #-} {-# LANGUAGE MagicHash #-} {-# LANGUAGE Rank2Types #-} #ifndef HLINT {-# LANGUAGE UnboxedTuples #-} #endif {-# LANGUAGE PatternGuards #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE DeriveDataTypeable #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE ExistentialQuantification #-} {-# LANGUAGE GADTs #-} #ifdef TRUSTWORTHY {-# LANGUAGE Trustworthy #-} #endif {-# OPTIONS_GHC -fno-full-laziness #-} ----------------------------------------------------------------------------- -- | -- Module : Data.Data.Lens -- Copyright : (C) 2012-2015 Edward Kmett, (C) 2006-2012 Neil Mitchell -- License : BSD-style (see the file LICENSE) -- Maintainer : Edward Kmett <ekmett@gmail.com> -- Stability : experimental -- Portability : Rank2Types -- -- Smart and naïve generic traversals given 'Data' instances. -- -- 'template', 'uniplate', and 'biplate' each build up information about what -- types can be contained within another type to speed up 'Traversal'. -- ---------------------------------------------------------------------------- module Data.Data.Lens ( -- * Generic Traversal template , tinplate , uniplate , biplate -- * Field Accessor Traversal , upon , upon' , onceUpon , onceUpon' -- * Data Traversal , gtraverse ) where import Control.Applicative import Control.Exception as E import Control.Lens.Internal.Context import Control.Lens.Internal.Indexed import Control.Lens.Lens import Control.Lens.Setter import Control.Lens.Traversal import Control.Lens.Type import Data.Data import GHC.IO import Data.Maybe import Data.Foldable import qualified Data.HashMap.Strict as M import Data.HashMap.Strict (HashMap, (!)) import qualified Data.HashSet as S import Data.HashSet (HashSet) import Data.IORef import Data.Monoid import GHC.Exts (realWorld#) import Prelude #ifdef HLINT {-# ANN module "HLint: ignore Eta reduce" #-} {-# ANN module "HLint: ignore Use foldl" #-} {-# ANN module "HLint: ignore Reduce duplication" #-} {-# ANN module "HLint: ignore Unused LANGUAGE pragma" #-} #endif -- $setup -- >>> :set -XNoOverloadedStrings -- >>> import Control.Lens ------------------------------------------------------------------------------- -- Generic Traversal ------------------------------------------------------------------------------- -- | A generic applicative transformation that maps over the immediate subterms. -- -- 'gtraverse' is to 'traverse' what 'gmapM' is to 'mapM' -- -- This really belongs in @Data.Data@. gtraverse :: (Applicative f, Data a) => (forall d. Data d => d -> f d) -> a -> f a gtraverse f = gfoldl (\x y -> x <*> f y) pure {-# INLINE gtraverse #-} ------------------------------------------------------------------------------- -- Naïve Traversal ------------------------------------------------------------------------------- -- | Naïve 'Traversal' using 'Data'. This does not attempt to optimize the traversal. -- -- This is primarily useful when the children are immediately obvious, and for benchmarking. tinplate :: (Data s, Typeable a) => Traversal' s a tinplate f = gfoldl (step f) pure {-# INLINE tinplate #-} step :: forall s a f r. (Applicative f, Typeable a, Data s) => (a -> f a) -> f (s -> r) -> s -> f r step f w s = w <*> case mightBe :: Maybe (Is s a) of Just Data.Data.Lens.Refl -> f s Nothing -> tinplate f s {-# INLINE step #-} ------------------------------------------------------------------------------- -- Smart Traversal ------------------------------------------------------------------------------- -- | Find every occurrence of a given type @a@ recursively that doesn't require -- passing through something of type @a@ using 'Data', while avoiding traversal -- of areas that cannot contain a value of type @a@. -- -- This is 'uniplate' with a more liberal signature. template :: forall s a. (Data s, Typeable a) => Traversal' s a template = uniplateData (fromOracle answer) where answer = hitTest (undefined :: s) (undefined :: a) {-# INLINE template #-} -- | Find descendants of type @a@ non-transitively, while avoiding computation of areas that cannot contain values of -- type @a@ using 'Data'. -- -- 'uniplate' is a useful default definition for 'Control.Lens.Plated.plate' uniplate :: Data a => Traversal' a a uniplate = template {-# INLINE uniplate #-} -- | 'biplate' performs like 'template', except when @s ~ a@, it returns itself and nothing else. biplate :: forall s a. (Data s, Typeable a) => Traversal' s a biplate = biplateData (fromOracle answer) where answer = hitTest (undefined :: s) (undefined :: a) {-# INLINE biplate #-} ------------------------------------------------------------------------------ -- Automatic Traversal construction from field accessors ------------------------------------------------------------------------------ data FieldException a = FieldException !Int a deriving Typeable instance Show (FieldException a) where showsPrec d (FieldException i _) = showParen (d > 10) $ showString "<field " . showsPrec 11 i . showChar '>' instance Typeable a => Exception (FieldException a) lookupon :: Typeable a => LensLike' (Indexing Identity) s a -> (s -> a) -> s -> Maybe (Int, Context a a s) lookupon l field s = case unsafePerformIO $ E.try $ evaluate $ field $ s & indexing l %@~ \i (a::a) -> E.throw (FieldException i a) of Right _ -> Nothing Left e -> case fromException e of Nothing -> Nothing Just (FieldException i a) -> Just (i, Context (\a' -> set (elementOf l i) a' s) a) {-# INLINE lookupon #-} -- | This automatically constructs a 'Traversal'' from an function. -- -- >>> (2,4) & upon fst *~ 5 -- (10,4) -- -- There are however, caveats on how this function can be used! -- -- First, the user supplied function must access only one field of the specified type. That is to say the target -- must be a single element that would be visited by @'holesOnOf' 'template' 'uniplate'@ -- -- Note: this even permits a number of functions to be used directly. -- -- >>> [1,2,3,4] & upon head .~ 0 -- [0,2,3,4] -- -- >>> [1,2,3,4] & upon last .~ 5 -- [1,2,3,5] -- -- >>> [1,2,3,4] ^? upon tail -- Just [2,3,4] -- -- >>> "" ^? upon tail -- Nothing -- -- Accessing parents on the way down to children is okay: -- -- >>> [1,2,3,4] & upon (tail.tail) .~ [10,20] -- [1,2,10,20] -- -- Second, the structure must not contain strict or unboxed fields of the same type that will be visited by 'Data' -- -- @'upon' :: ('Data' s, 'Data' a) => (s -> a) -> 'IndexedTraversal'' [Int] s a@ upon :: forall p f s a. (Indexable [Int] p, Applicative f, Data s, Data a) => (s -> a) -> p a (f a) -> s -> f s upon field f s = case lookupon template field s of Nothing -> pure s Just (i, Context k0 a0) -> let go :: [Int] -> Traversal' s a -> (a -> s) -> a -> f s go is l k a = case lookupon (l.uniplate) field s of Nothing -> k <$> indexed f (reverse is) a Just (j, Context k' a') -> go (j:is) (l.elementOf uniplate j) k' a' in go [i] (elementOf template i) k0 a0 {-# INLINE upon #-} -- | The design of 'onceUpon'' doesn't allow it to search inside of values of type 'a' for other values of type 'a'. -- 'upon'' provides this additional recursion. -- -- Like 'onceUpon'', 'upon'' trusts the user supplied function more than 'upon' using it directly -- as the accessor. This enables reading from the resulting 'Lens' to be considerably faster at the risk of -- generating an illegal lens. -- -- >>> upon' (tail.tail) .~ [10,20] $ [1,2,3,4] -- [1,2,10,20] upon' :: forall s a. (Data s, Data a) => (s -> a) -> IndexedLens' [Int] s a upon' field f s = let ~(isn, kn) = case lookupon template field s of Nothing -> (error "upon': no index, not a member", const s) Just (i, Context k0 _) -> go [i] (elementOf template i) k0 go :: [Int] -> Traversal' s a -> (a -> s) -> ([Int], a -> s) go is l k = case lookupon (l.uniplate) field s of Nothing -> (reverse is, k) Just (j, Context k' _) -> go (j:is) (l.elementOf uniplate j) k' in kn <$> indexed f isn (field s) {-# INLINE upon' #-} -- | This automatically constructs a 'Traversal'' from a field accessor. -- -- The index of the 'Traversal' can be used as an offset into @'elementOf' ('indexing' 'template')@ or into the list -- returned by @'holesOf' 'template'@. -- -- The design of 'onceUpon' doesn't allow it to search inside of values of type 'a' for other values of type 'a'. -- 'upon' provides this additional recursion, but at the expense of performance. -- -- >>> onceUpon (tail.tail) .~ [10,20] $ [1,2,3,4] -- BAD -- [1,10,20] -- -- >>> upon (tail.tail) .~ [10,20] $ [1,2,3,4] -- GOOD -- [1,2,10,20] -- -- When in doubt, use 'upon' instead. onceUpon :: forall s a. (Data s, Typeable a) => (s -> a) -> IndexedTraversal' Int s a onceUpon field f s = case lookupon template field s of Nothing -> pure s Just (i, Context k a) -> k <$> indexed f i a {-# INLINE onceUpon #-} -- | This more trusting version of 'upon' uses your function directly as the getter for a 'Lens'. -- -- This means that reading from 'upon'' is considerably faster than 'upon'. -- -- However, you pay for faster access in two ways: -- -- 1. When passed an illegal field accessor, 'upon'' will give you a 'Lens' that quietly violates -- the laws, unlike 'upon', which will give you a legal 'Traversal' that avoids modifying the target. -- -- 2. Modifying with the lens is slightly slower, since it has to go back and calculate the index after the fact. -- -- When given a legal field accessor, the index of the 'Lens' can be used as an offset into -- @'elementOf' ('indexed' 'template')@ or into the list returned by @'holesOf' 'template'@. -- -- When in doubt, use 'upon'' instead. onceUpon' :: forall s a. (Data s, Typeable a) => (s -> a) -> IndexedLens' Int s a onceUpon' field f s = k <$> indexed f i (field s) where ~(i, Context k _) = fromMaybe (error "upon': no index, not a member") (lookupon template field s) {-# INLINE onceUpon' #-} ------------------------------------------------------------------------------- -- Type equality ------------------------------------------------------------------------------- data Is a b where Refl :: Is a a mightBe :: (Typeable a, Typeable b) => Maybe (Is a b) mightBe = gcast Data.Data.Lens.Refl {-# INLINE mightBe #-} ------------------------------------------------------------------------------- -- Data Box ------------------------------------------------------------------------------- data DataBox = forall a. Data a => DataBox { dataBoxKey :: TypeRep , _dataBoxVal :: a } dataBox :: Data a => a -> DataBox dataBox a = DataBox (typeOf a) a {-# INLINE dataBox #-} -- partial, caught elsewhere sybChildren :: Data a => a -> [DataBox] sybChildren x | isAlgType dt = do c <- dataTypeConstrs dt gmapQ dataBox (fromConstr c `asTypeOf` x) | otherwise = [] where dt = dataTypeOf x {-# INLINE sybChildren #-} ------------------------------------------------------------------------------- -- HitMap ------------------------------------------------------------------------------- type HitMap = HashMap TypeRep (HashSet TypeRep) emptyHitMap :: HitMap emptyHitMap = M.fromList [ (tRational, S.singleton tInteger) , (tInteger, S.empty) ] where tRational = typeOf (undefined :: Rational) tInteger = typeOf (undefined :: Integer ) insertHitMap :: DataBox -> HitMap -> HitMap insertHitMap box hit = fixEq trans (populate box) `mappend` hit where populate :: DataBox -> HitMap populate a = f a M.empty where f (DataBox k v) m | M.member k hit || M.member k m = m | cs <- sybChildren v = fs cs $ M.insert k (S.fromList $ map dataBoxKey cs) m fs [] m = m fs (x:xs) m = fs xs (f x m) trans :: HitMap -> HitMap trans m = M.map f m where f x = x `mappend` foldMap g x g x = fromMaybe (hit ! x) (M.lookup x m) fixEq :: Eq a => (a -> a) -> a -> a fixEq f = go where go x | x == x' = x' | otherwise = go x' where x' = f x {-# INLINE fixEq #-} #ifndef HLINT -- | inlineable 'unsafePerformIO' inlinePerformIO :: IO a -> a inlinePerformIO (IO m) = case m realWorld# of (# _, r #) -> r {-# INLINE inlinePerformIO #-} #endif ------------------------------------------------------------------------------- -- Cache ------------------------------------------------------------------------------- data Cache = Cache HitMap (HashMap TypeRep (HashMap TypeRep (Maybe Follower))) cache :: IORef Cache cache = unsafePerformIO $ newIORef $ Cache emptyHitMap M.empty {-# NOINLINE cache #-} readCacheFollower :: DataBox -> TypeRep -> Maybe Follower readCacheFollower b@(DataBox kb _) ka = inlinePerformIO $ readIORef cache >>= \ (Cache hm m) -> case M.lookup kb m >>= M.lookup ka of Just a -> return a Nothing -> E.try (return $! insertHitMap b hm) >>= \r -> case r of Left SomeException{} -> atomicModifyIORef cache $ \(Cache hm' n) -> (Cache hm' (insert2 kb ka Nothing n), Nothing) Right hm' | fol <- Just (follower kb ka hm') -> atomicModifyIORef cache $ \(Cache _ n) -> (Cache hm' (insert2 kb ka fol n), fol) insert2 :: TypeRep -> TypeRep -> a -> HashMap TypeRep (HashMap TypeRep a) -> HashMap TypeRep (HashMap TypeRep a) insert2 x y v = M.insertWith (const $ M.insert y v) x (M.singleton y v) {-# INLINE insert2 #-} {- readCacheHitMap :: DataBox -> Maybe HitMap readCacheHitMap b@(DataBox kb _) = inlinePerformIO $ readIORef cache >>= \ (Cache hm _) -> case M.lookup kb hm of Just _ -> return $ Just hm Nothing -> E.try (return $! insertHitMap b hm) >>= \r -> case r of Left SomeException{} -> return Nothing Right hm' -> atomicModifyIORef cache $ \(Cache _ follow) -> (Cache hm' follow, Just hm') -} ------------------------------------------------------------------------------- -- Answers ------------------------------------------------------------------------------- data Answer b a = b ~ a => Hit a | Follow | Miss ------------------------------------------------------------------------------- -- Oracles ------------------------------------------------------------------------------- newtype Oracle a = Oracle { fromOracle :: forall t. Typeable t => t -> Answer t a } hitTest :: forall a b. (Data a, Typeable b) => a -> b -> Oracle b hitTest a b = Oracle $ \(c :: c) -> case mightBe :: Maybe (Is c b) of Just Data.Data.Lens.Refl -> Hit c Nothing -> case readCacheFollower (dataBox a) (typeOf b) of Just p | not (p (typeOf c)) -> Miss _ -> Follow ------------------------------------------------------------------------------- -- Traversals ------------------------------------------------------------------------------- biplateData :: forall f s a. (Applicative f, Data s) => (forall c. Typeable c => c -> Answer c a) -> (a -> f a) -> s -> f s biplateData o f a0 = go2 a0 where go :: Data d => d -> f d go s = gfoldl (\x y -> x <*> go2 y) pure s go2 :: Data d => d -> f d go2 s = case o s of Hit a -> f a Follow -> go s Miss -> pure s {-# INLINE biplateData #-} uniplateData :: forall f s a. (Applicative f, Data s) => (forall c. Typeable c => c -> Answer c a) -> (a -> f a) -> s -> f s uniplateData o f a0 = go a0 where go :: Data d => d -> f d go s = gfoldl (\x y -> x <*> go2 y) pure s go2 :: Data d => d -> f d go2 s = case o s of Hit a -> f a Follow -> go s Miss -> pure s {-# INLINE uniplateData #-} ------------------------------------------------------------------------------- -- Follower ------------------------------------------------------------------------------- part :: (a -> Bool) -> HashSet a -> (HashSet a, HashSet a) part p s = (S.filter p s, S.filter (not . p) s) {-# INLINE part #-} type Follower = TypeRep -> Bool follower :: TypeRep -> TypeRep -> HitMap -> Follower follower a b m | S.null hit = const False | S.null miss = const True | S.size hit < S.size miss = S.member ?? hit | otherwise = \k -> not (S.member k miss) where (hit, miss) = part (\x -> S.member b (m ! x)) (S.insert a (m ! a))