{-# LANGUAGE TypeOperators, TypeFamilies, UndecidableInstances, CPP , FlexibleContexts, DeriveFunctor, StandaloneDeriving #-} {-# OPTIONS_GHC -Wall -fno-warn-orphans #-} {-# OPTIONS_GHC -fno-warn-unused-binds -fno-warn-unused-imports #-} -- temporary while testing ---------------------------------------------------------------------- -- | -- Module : FunctorCombo.MemoTrie -- Copyright : (c) Conal Elliott 2010 -- License : BSD3 -- -- Maintainer : conal@conal.net -- Stability : experimental -- -- Functor-based memo tries (strict for now) -- ---------------------------------------------------------------------- module FunctorCombo.StrictMemo ( HasTrie(..),(:->:),memo,memo2,memo3 ) where import Control.Arrow (first) import Control.Applicative ((<$>)) import Data.Foldable (Foldable,toList) import Data.Tree import qualified Data.IntTrie as IT -- data-inttrie import Data.Tree import Control.Compose (result) -- TypeCompose -- import FunctorCombo.Strict import FunctorCombo.Functor import FunctorCombo.Regular {-------------------------------------------------------------------- Class --------------------------------------------------------------------} infixr 0 :->: -- | Memo trie from k to v type k :->: v = Trie k v -- #define FunctorSuperClass #ifdef FunctorSuperClass #define HasTrieContext(Ty) Functor (Trie(Ty)) #define HF(Ty) HasTrie (Ty) #else #define HasTrieContext(Ty) () #define HF(Ty) HasTrie (Ty), Functor (Trie (Ty)) #endif -- | Domain types with associated memo tries class HasTrieContext(k) => HasTrie k where -- | Representation of trie with domain type @a@ type Trie k :: * -> * -- | Create the trie for the entire domain of a function trie :: (k -> v) -> (k :->: v) -- | Convert k trie to k function, i.e., access k field of the trie untrie :: (k :->: v) -> (k -> v) -- -- | List the trie elements. Order of keys (@:: k@) is always the same. -- enumerate :: (k :->: v) -> [(k,v)] -- -- | Domain elements of a trie -- domain :: HasTrie a => [a] -- domain = map fst (enumerate (trie (const oops))) -- where -- oops = error "Data.MemoTrie.domain: range element evaluated." -- Identity trie. To do: make idTrie the method, and define trie via idTrie. idTrie :: HasTrie k => k :->: k idTrie = trie id -- | List the trie elements. Order of keys (@:: k@) is always the same. enumerate :: (Foldable (Trie k), HasTrie k) => (k :->: v) -> [(k,v)] enumerate = zip (toList idTrie) . toList -- TODO: Improve this implementation, using an interface from Edward -- Kmett. Something about collections with keys, so that I can efficiently -- implement `(k :->: v) -> (k :->: (k,v))`. {-------------------------------------------------------------------- Memo functions --------------------------------------------------------------------} -- | Trie-based function memoizer memo :: HasTrie k => Unop (k -> v) memo = untrie . trie -- | Memoize a binary function, on its first argument and then on its -- second. Take care to exploit any partial evaluation. memo2 :: (HasTrie s,HasTrie t) => Unop (s -> t -> a) -- | Memoize a ternary function on successive arguments. Take care to -- exploit any partial evaluation. memo3 :: (HasTrie r,HasTrie s,HasTrie t) => Unop (r -> s -> t -> a) -- | Lift a memoizer to work with one more argument. mup :: HasTrie t => (b -> c) -> (t -> b) -> (t -> c) mup mem f = memo (mem . f) memo2 = mup memo memo3 = mup memo2 {-------------------------------------------------------------------- Instances --------------------------------------------------------------------} instance HasTrie () where type Trie () = Id trie f = Id (f ()) untrie (Id v) = const v -- enumerate (Id a) = [((),a)] instance (HasTrie a, HasTrie b) => HasTrie (Either a b) where type Trie (Either a b) = Trie a :*: Trie b trie f = trie (f . Left) :*: trie (f . Right) untrie (ta :*: tb) = untrie ta `either` untrie tb -- enumerate (ta :*: tb) = enum' Left ta `weave` enum' Right tb -- enum' :: (HasTrie a) => (a -> a') -> (a :->: b) -> [(a', b)] -- enum' f = (fmap.first) f . enumerate weave :: [a] -> [a] -> [a] [] `weave` as = as as `weave` [] = as (a:as) `weave` bs = a : (bs `weave` as) instance (HF(a), HasTrie b) => HasTrie (a , b) where type Trie (a , b) = Trie a :. Trie b trie f = O (trie (trie . curry f)) -- untrie (O tt) = uncurry (untrie . untrie tt) untrie (O tt) = uncurry (untrie (fmap untrie tt)) -- enumerate (O tt) = -- [ ((a,b),x) | (a,t) <- enumerate tt , (b,x) <- enumerate t ] #define HasTrieIsomorph(Context,Type,IsoType,toIso,fromIso) \ instance Context => HasTrie (Type) where {\ type Trie (Type) = Trie (IsoType); \ trie f = trie (f . (fromIso)); \ untrie t = untrie t . (toIso); \ } -- enumerate = (result.fmap.first) (fromIso) enumerate; HasTrieIsomorph( (), Bool, Either () () , bool (Right ()) (Left ()) , either (\ () -> False) (\ () -> True)) HasTrieIsomorph( (HF(a),HF(b), HasTrie c) , (a,b,c), ((a,b),c) , \ (a,b,c) -> ((a,b),c), \ ((a,b),c) -> (a,b,c)) HasTrieIsomorph( (HF(a),HF(b),HF(c), HasTrie d) , (a,b,c,d), ((a,b,c),d) , \ (a,b,c,d) -> ((a,b,c),d), \ ((a,b,c),d) -> (a,b,c,d)) -- As well as the functor combinators themselves HasTrieIsomorph( HasTrie x, Const x a, x, getConst, Const ) HasTrieIsomorph( HasTrie a, Id a, a, unId, Id ) HasTrieIsomorph( ( HF(f a), HasTrie (g a) ) , (f :*: g) a, (f a,g a) , \ (fa :*: ga) -> (fa,ga), \ (fa,ga) -> (fa :*: ga) ) HasTrieIsomorph( (HasTrie (f a), HasTrie (g a)) , (f :+: g) a, Either (f a) (g a) , eitherF Left Right, either InL InR ) HasTrieIsomorph( HasTrie (g (f a)) , (g :. f) a, g (f a) , unO, O ) -- newtype ListTrie a v = ListTrie (PF [a] [a] :->: v) -- instance (HF(a)) => HasTrie [a] where -- type Trie [a] = ListTrie a -- trie f = ListTrie (trie (f . wrap)) -- untrie (ListTrie t) = untrie t . unwrap -- enumerate (ListTrie t) = (result.fmap.first) wrap enumerate $ t -- deriving instance Functor (Trie a) => Functor (ListTrie a) -- HasTrieIsomorph( HasTrie (PF ([a]) ([a]) :->: v) -- , ListTrie a v, PF ([a]) ([a]) :->: v -- , \ (ListTrie w) -> w, ListTrie ) -- instance HasTrie (PF ([a]) ([a]) :->: v) => HasTrie (ListTrie a v) where -- type Trie (ListTrie a v) = Trie (PF ([a]) ([a]) :->: v) -- trie f = trie (f . ListTrie) -- untrie t = untrie t . \ (ListTrie w) -> w -- instance (HasTrie (PF ([a]) ([a]) :->: v)) => HasTrie (ListTrie a v) where -- type Trie (ListTrie a v) = Trie (PF ([a]) ([a]) :->: v) -- instance (Functor (Trie v), HasTrie (PF ([a]) ([a]) :->: v)) => HasTrie (ListTrie a v) where -- type Trie (ListTrie a v) = Trie (PF ([a]) ([a]) :->: v) -- Could not deduce (Functor -- (Trie (Trie (Const a [a]) (ListTrie a v)))) -- from the context (Functor (Trie v), HasTrie (PF [a] [a] :->: v)) -- arising from the superclasses of an instance declaration -- Functor (Trie (Trie (Const a [a]) (ListTrie a v))) -- Functor (Trie (Const a [a] :->: ListTrie a v)) -- Const a [a] :->: ListTrie a v -- a :->: ListTrie a v -- instance (Functor (Trie a), Functor (Trie v), HasTrie (PF ([a]) ([a]) :->: v)) => HasTrie (ListTrie a v) where -- type Trie (ListTrie a v) = Trie (PF ([a]) ([a]) :->: v) -- Could not deduce (Functor (Trie (Trie a (ListTrie a v)))) ... -- arising from the superclasses of an instance declaration -- newtype ListTrie a v = ListTrie (PF [a] [a] :->: v) -- instance HasTrie a => HasTrie [a] where -- type Trie [a] = ListTrie a -- trie f = ListTrie (trie (f . wrap)) -- untrie (ListTrie t) = untrie t . unwrap -- enumerate (ListTrie t) = (result.fmap.first) wrap enumerate $ t -- HasTrieIsomorph( HasTrie (PF ([a]) ([a]) :->: v) -- , ListTrie a v, PF ([a]) ([a]) :->: v -- , \ (ListTrie w) -> w, ListTrie ) -- deriving instance Functor (Trie a) => Functor (ListTrie a) -- newtype ListTrie a v = ListTrie (PF ([a]) ([a]) :->: v); \ -- instance HasTrie a => HasTrie ([a]) where { \ -- type Trie ([a]) = ListTrie a; \ -- trie f = ListTrie (trie (f . wrap)); \ -- untrie (ListTrie t) = untrie t . unwrap; \ -- enumerate (ListTrie t) = (result.fmap.first) wrap enumerate t; \ -- }; \ -- HasTrieIsomorph( HasTrie (PF ([a]) ([a]) :->: v) \ -- , ListTrie a v, PF ([a]) ([a]) :->: v \ -- , \ (ListTrie w) -> w, ListTrie ) -- deriving instance Functor (Trie a) => Functor (ListTrie a) -- Works. Now abstract into a macro #define HasTrieRegular(Context,Type,TrieType,TrieCon) \ newtype TrieType v = TrieCon (PF (Type) (Type) :->: v); \ instance Context => HasTrie (Type) where { \ type Trie (Type) = TrieType; \ trie f = TrieCon (trie (f . wrap)); \ untrie (TrieCon t) = untrie t . unwrap; \ }; \ HasTrieIsomorph( HasTrie (PF (Type) (Type) :->: v) \ , TrieType v, PF (Type) (Type) :->: v \ , \ (TrieCon w) -> w, TrieCon ) -- enumerate (TrieCon t) = (result.fmap.first) wrap enumerate t; -- For instance, -- HasTrieRegular(HasTrie a, [a] , ListTrie a, ListTrie) -- -- deriving instance Functor (Trie a) => Functor (ListTrie a) -- HasTrieRegular(HasTrie a, Tree a, TreeTrie a, TreeTrie) -- -- deriving instance Functor (Trie a) => Functor (TreeTrie a) -- Simplify a bit with a macro for unary regular types. -- Make similar defs for binary etc as needed. #define HasTrieRegular1(TypeCon,TrieCon) \ HasTrieRegular((HF(a)), TypeCon a, TrieCon a, TrieCon); \ deriving instance Functor (Trie a) => Functor (TrieCon a) HasTrieRegular1([] , ListTrie) HasTrieRegular1(Tree, TreeTrie) -- HasTrieIsomorph(Context,Type,IsoType,toIso,fromIso) -- HasTrieIsomorph( HasTrie (PF [a] [a] :->: v) -- , ListTrie a v, PF [a] [a] :->: v -- , \ (ListTrie w) -> w, ListTrie ) -- enumerateEnum :: (Enum k, Num k, HasTrie k) => (k :->: v) -> [(k,v)] -- enumerateEnum t = [(k, f k) | k <- [0 ..] `weave` [-1, -2 ..]] -- where -- f = untrie t #define HasTrieIntegral(Type) \ instance HasTrie Type where { \ type Trie Type = IT.IntTrie; \ trie = (<$> IT.identity); \ untrie = IT.apply; \ } -- enumerate = enumerateEnum; HasTrieIntegral(Int) HasTrieIntegral(Integer) -- Memoizing higher-order functions HasTrieIsomorph((HasTrie a, HasTrie (a :->: b)), a -> b, a :->: b, trie, untrie) {-------------------------------------------------------------------- Misc --------------------------------------------------------------------} type Unop a = a -> a bool :: a -> a -> Bool -> a bool t e b = if b then t else e {-------------------------------------------------------------------- Testing --------------------------------------------------------------------} fib :: Integer -> Integer fib m = mfib m where mfib = memo fib' fib' 0 = 0 fib' 1 = 1 fib' n = mfib (n-1) + mfib (n-2) -- The eta-redex in fib is important to prevent a CAF. ft1 :: (Bool -> a) -> [a] ft1 f = [f False, f True] f1 :: Bool -> Int f1 False = 0 f1 True = 1 trie1a :: (HF(a)) => (Bool -> a) :->: [a] trie1a = trie ft1 trie1b :: (HF(a)) => (Bool :->: a) :->: [a] trie1b = trie1a trie1c :: (HF(a)) => (Either () () :->: a) :->: [a] trie1c = trie1a trie1d :: (HF(a)) => ((Trie () :*: Trie ()) a) :->: [a] trie1d = trie1a trie1e :: (HF(a)) => (Trie () a, Trie () a) :->: [a] trie1e = trie1a trie1f :: (HF(a)) => (() :->: a, () :->: a) :->: [a] trie1f = trie1a trie1g :: (HF(a)) => (a, a) :->: [a] trie1g = trie1a trie1h :: (HF(a)) => (Trie a :. Trie a) [a] trie1h = trie1a trie1i :: (HF(a)) => a :->: a :->: [a] trie1i = unO trie1a ft2 :: ([Bool] -> Int) -> Int ft2 f = f (alts 15) alts :: Int -> [Bool] alts n = take n (cycle [True,False]) f2 :: [Bool] -> Int f2 = length . filter id -- Memoization fails: -- *FunctorCombo.MemoTrie> ft2 f2 -- 8 -- *FunctorCombo.MemoTrie> memo ft2 f2 -- ... (hang forever) ... -- Would nonstrict memoization work? <http://conal.net/blog/posts/nonstrict-memoization/> {-------------------------------------------------------------------- Regular instances. --------------------------------------------------------------------} -- Re-think where to put these instances. I want different versions for -- list, depending on whether I'm taking care with bottoms. instance Regular [a] where type PF [a] = Unit :+: Const a :*: Id unwrap [] = InL (Const ()) unwrap (a:as) = InR (Const a :*: Id as) wrap (InL (Const ())) = [] wrap (InR (Const a :*: Id as)) = a:as -- Rose tree (from Data.Tree) -- -- data Tree a = Node a [Tree a] -- instance Functor Tree where -- fmap f (Node a ts) = Node (f a) (fmap f ts) instance Regular (Tree a) where type PF (Tree a) = Const a :*: [] unwrap (Node a ts) = Const a :*: ts wrap (Const a :*: ts) = Node a ts