module Data.Edison.Seq.RevSeq (
Rev,
empty,singleton,lcons,rcons,append,lview,lhead,ltail,rview,rhead,rtail,
lheadM,ltailM,rheadM,rtailM,
null,size,concat,reverse,reverseOnto,fromList,toList,map,concatMap,
fold,fold',fold1,fold1',foldr,foldr',foldl,foldl',foldr1,foldr1',foldl1,foldl1',
reducer,reducer',reducel,reducel',reduce1,reduce1',
copy,inBounds,lookup,lookupM,lookupWithDefault,update,adjust,
mapWithIndex,foldrWithIndex,foldrWithIndex',foldlWithIndex,foldlWithIndex',
take,drop,splitAt,subseq,filter,partition,takeWhile,dropWhile,splitWhile,
zip,zip3,zipWith,zipWith3,unzip,unzip3,unzipWith,unzipWith3,
strict, strictWith,
structuralInvariant,
moduleName,instanceName,
fromSeq,toSeq
) where
import Prelude hiding (concat,reverse,map,concatMap,foldr,foldl,foldr1,foldl1,
filter,takeWhile,dropWhile,lookup,take,drop,splitAt,
zip,zip3,zipWith,zipWith3,unzip,unzip3,null)
import qualified Control.Applicative as App
import qualified Data.Edison.Seq as S
import qualified Data.Edison.Seq.ListSeq as L
import Data.Edison.Seq.Defaults
import Control.Monad
import Data.Monoid
import Test.QuickCheck
moduleName :: String
instanceName :: S.Sequence s => Rev s a -> String
empty :: S.Sequence s => Rev s a
singleton :: S.Sequence s => a -> Rev s a
lcons :: S.Sequence s => a -> Rev s a -> Rev s a
rcons :: S.Sequence s => a -> Rev s a -> Rev s a
append :: S.Sequence s => Rev s a -> Rev s a -> Rev s a
lview :: (S.Sequence s, Monad m) => Rev s a -> m (a, Rev s a)
lhead :: S.Sequence s => Rev s a -> a
lheadM :: (S.Sequence s, Monad m) => Rev s a -> m a
ltail :: S.Sequence s => Rev s a -> Rev s a
ltailM :: (S.Sequence s, Monad m) => Rev s a -> m (Rev s a)
rview :: (S.Sequence s, Monad m) => Rev s a -> m (a, Rev s a)
rhead :: S.Sequence s => Rev s a -> a
rheadM :: (S.Sequence s, Monad m) => Rev s a -> m a
rtail :: S.Sequence s => Rev s a -> Rev s a
rtailM :: (S.Sequence s, Monad m) => Rev s a -> m (Rev s a)
null :: S.Sequence s => Rev s a -> Bool
size :: S.Sequence s => Rev s a -> Int
concat :: S.Sequence s => Rev s (Rev s a) -> Rev s a
reverse :: S.Sequence s => Rev s a -> Rev s a
reverseOnto :: S.Sequence s => Rev s a -> Rev s a -> Rev s a
fromList :: S.Sequence s => [a] -> Rev s a
toList :: S.Sequence s => Rev s a -> [a]
map :: S.Sequence s => (a -> b) -> Rev s a -> Rev s b
concatMap :: S.Sequence s => (a -> Rev s b) -> Rev s a -> Rev s b
fold :: S.Sequence s => (a -> b -> b) -> b -> Rev s a -> b
fold' :: S.Sequence s => (a -> b -> b) -> b -> Rev s a -> b
fold1 :: S.Sequence s => (a -> a -> a) -> Rev s a -> a
fold1' :: S.Sequence s => (a -> a -> a) -> Rev s a -> a
foldr :: S.Sequence s => (a -> b -> b) -> b -> Rev s a -> b
foldl :: S.Sequence s => (b -> a -> b) -> b -> Rev s a -> b
foldr1 :: S.Sequence s => (a -> a -> a) -> Rev s a -> a
foldl1 :: S.Sequence s => (a -> a -> a) -> Rev s a -> a
reducer :: S.Sequence s => (a -> a -> a) -> a -> Rev s a -> a
reducel :: S.Sequence s => (a -> a -> a) -> a -> Rev s a -> a
reduce1 :: S.Sequence s => (a -> a -> a) -> Rev s a -> a
foldr' :: S.Sequence s => (a -> b -> b) -> b -> Rev s a -> b
foldl' :: S.Sequence s => (b -> a -> b) -> b -> Rev s a -> b
foldr1' :: S.Sequence s => (a -> a -> a) -> Rev s a -> a
foldl1' :: S.Sequence s => (a -> a -> a) -> Rev s a -> a
reducer' :: S.Sequence s => (a -> a -> a) -> a -> Rev s a -> a
reducel' :: S.Sequence s => (a -> a -> a) -> a -> Rev s a -> a
reduce1' :: S.Sequence s => (a -> a -> a) -> Rev s a -> a
copy :: S.Sequence s => Int -> a -> Rev s a
inBounds :: S.Sequence s => Int -> Rev s a -> Bool
lookup :: S.Sequence s => Int -> Rev s a -> a
lookupM :: (S.Sequence s, Monad m) => Int -> Rev s a -> m a
lookupWithDefault :: S.Sequence s => a -> Int -> Rev s a -> a
update :: S.Sequence s => Int -> a -> Rev s a -> Rev s a
adjust :: S.Sequence s => (a -> a) -> Int -> Rev s a -> Rev s a
mapWithIndex :: S.Sequence s => (Int -> a -> b) -> Rev s a -> Rev s b
foldrWithIndex :: S.Sequence s => (Int -> a -> b -> b) -> b -> Rev s a -> b
foldlWithIndex :: S.Sequence s => (b -> Int -> a -> b) -> b -> Rev s a -> b
foldrWithIndex' :: S.Sequence s => (Int -> a -> b -> b) -> b -> Rev s a -> b
foldlWithIndex' :: S.Sequence s => (b -> Int -> a -> b) -> b -> Rev s a -> b
take :: S.Sequence s => Int -> Rev s a -> Rev s a
drop :: S.Sequence s => Int -> Rev s a -> Rev s a
splitAt :: S.Sequence s => Int -> Rev s a -> (Rev s a, Rev s a)
subseq :: S.Sequence s => Int -> Int -> Rev s a -> Rev s a
filter :: S.Sequence s => (a -> Bool) -> Rev s a -> Rev s a
partition :: S.Sequence s => (a -> Bool) -> Rev s a -> (Rev s a, Rev s a)
takeWhile :: S.Sequence s => (a -> Bool) -> Rev s a -> Rev s a
dropWhile :: S.Sequence s => (a -> Bool) -> Rev s a -> Rev s a
splitWhile :: S.Sequence s => (a -> Bool) -> Rev s a -> (Rev s a, Rev s a)
zip :: S.Sequence s => Rev s a -> Rev s b -> Rev s (a,b)
zip3 :: S.Sequence s => Rev s a -> Rev s b -> Rev s c -> Rev s (a,b,c)
zipWith :: S.Sequence s => (a -> b -> c) -> Rev s a -> Rev s b -> Rev s c
zipWith3 :: S.Sequence s => (a -> b -> c -> d) -> Rev s a -> Rev s b -> Rev s c -> Rev s d
unzip :: S.Sequence s => Rev s (a,b) -> (Rev s a, Rev s b)
unzip3 :: S.Sequence s => Rev s (a,b,c) -> (Rev s a, Rev s b, Rev s c)
unzipWith :: S.Sequence s => (a -> b) -> (a -> c) -> Rev s a -> (Rev s b, Rev s c)
unzipWith3 :: S.Sequence s => (a -> b) -> (a -> c) -> (a -> d) -> Rev s a -> (Rev s b, Rev s c, Rev s d)
strict :: S.Sequence s => Rev s a -> Rev s a
strictWith :: S.Sequence s => (a -> b) -> Rev s a -> Rev s a
structuralInvariant :: S.Sequence s => Rev s a -> Bool
fromSeq :: S.Sequence s => s a -> Rev s a
toSeq :: S.Sequence s => Rev s a -> s a
moduleName = "Data.Edison.Seq.RevSeq"
instanceName (N _ s) = "RevSeq(" ++ S.instanceName s ++ ")"
data Rev s a = N !Int (s a)
fromSeq xs = N (S.size xs 1) xs
toSeq (N _ xs) = xs
empty = N (1) S.empty
singleton x = N 0 (S.singleton x)
lcons x (N m xs) = N (m+1) (S.rcons x xs)
rcons x (N m xs) = N (m+1) (S.lcons x xs)
append (N m xs) (N n ys) = N (m+n+1) (S.append ys xs)
lview (N m xs) = case S.rview xs of
Nothing -> fail "RevSeq.lview: empty sequence"
Just (x,xs) -> return (x, N (m1) xs)
lhead (N _ xs) = S.rhead xs
lheadM (N _ xs) = S.rheadM xs
ltail (N (1) _) = error "RevSeq.ltail: empty sequence"
ltail (N m xs) = N (m1) (S.rtail xs)
ltailM (N (1) _) = fail "RevSeq.ltailM: empty sequence"
ltailM (N m xs) = return (N (m1) (S.rtail xs))
rview (N m xs) = case S.lview xs of
Nothing -> fail "RevSeq.rview: empty sequence"
Just (x,xs) -> return (x, N (m1) xs)
rhead (N _ xs) = S.lhead xs
rheadM (N _ xs) = S.lheadM xs
rtail (N (1) _) = error "RevSeq.rtail: empty sequence"
rtail (N m xs) = N (m1) (S.ltail xs)
rtailM (N (1) _) = fail "RevSeq.rtailM: empty sequence"
rtailM (N m xs) = return (N (m1) (S.ltail xs))
null (N m _) = m == 1
size (N m _) = m+1
concat (N _ xss) = fromSeq (S.concat (S.map toSeq xss))
reverse (N m xs) = N m (S.reverse xs)
reverseOnto (N m xs) (N n ys) = N (m+n+1) (S.append ys (S.reverse xs))
fromList = fromSeq . S.fromList . L.reverse
toList (N _ xs) = S.foldl (flip (:)) [] xs
map f (N m xs) = N m (S.map f xs)
concatMap = concatMapUsingFoldr
fold f e (N _ xs) = S.fold f e xs
fold' f e (N _ xs) = S.fold' f e xs
fold1 f (N _ xs) = S.fold1 f xs
fold1' f (N _ xs) = S.fold1' f xs
foldr f e (N _ xs) = S.foldl (flip f) e xs
foldr' f e (N _ xs) = S.foldl' (flip f) e xs
foldl f e (N _ xs) = S.foldr (flip f) e xs
foldl' f e (N _ xs) = S.foldr' (flip f) e xs
foldr1 f (N _ xs) = S.foldl1 (flip f) xs
foldr1' f (N _ xs) = S.foldl1' (flip f) xs
foldl1 f (N _ xs) = S.foldr1 (flip f) xs
foldl1' f (N _ xs) = S.foldr1' (flip f) xs
reducer f e (N _ xs) = S.reducel (flip f) e xs
reducer' f e (N _ xs) = S.reducel' (flip f) e xs
reducel f e (N _ xs) = S.reducer (flip f) e xs
reducel' f e (N _ xs) = S.reducer' (flip f) e xs
reduce1 f (N _ xs) = S.reduce1 (flip f) xs
reduce1' f (N _ xs) = S.reduce1' (flip f) xs
copy n x
| n <= 0 = empty
| otherwise = N (n1) (S.copy n x)
inBounds i (N m _) = (i >= 0) && (i <= m)
lookup i (N m xs) = S.lookup (mi) xs
lookupM i (N m xs) = S.lookupM (mi) xs
lookupWithDefault d i (N m xs) = S.lookupWithDefault d (mi) xs
update i x (N m xs) = N m (S.update (mi) x xs)
adjust f i (N m xs) = N m (S.adjust f (mi) xs)
mapWithIndex f (N m xs) = N m (S.mapWithIndex (f . (m)) xs)
foldrWithIndex f e (N m xs) = S.foldlWithIndex f' e xs
where f' xs i x = f (mi) x xs
foldrWithIndex' f e (N m xs) = S.foldlWithIndex' f' e xs
where f' xs i x = f (mi) x xs
foldlWithIndex f e (N m xs) = S.foldrWithIndex f' e xs
where f' i x xs = f xs (mi) x
foldlWithIndex' f e (N m xs) = S.foldrWithIndex' f' e xs
where f' i x xs = f xs (mi) x
take i original@(N m xs)
| i <= 0 = empty
| i > m = original
| otherwise = N (i1) (S.drop (mi+1) xs)
drop i original@(N m xs)
| i <= 0 = original
| i > m = empty
| otherwise = N (mi) (S.take (mi+1) xs)
splitAt i original@(N m xs)
| i <= 0 = (empty, original)
| i > m = (original, empty)
| otherwise = let (ys,zs) = S.splitAt (mi+1) xs
in (N (i1) zs, N (mi) ys)
subseq i len original@(N m xs)
| i <= 0 = take len original
| i > m || len <= 0 = empty
| i+len > m = N (mi) (S.take (mi+1) xs)
| otherwise = N (len1) (S.subseq (milen+1) len xs)
filter p = fromSeq . S.filter p . toSeq
partition p (N m xs) = (N (k1) ys, N (mk) zs)
where (ys,zs) = S.partition p xs
k = S.size ys
takeWhile p = fromSeq . S.reverse . S.takeWhile p . S.reverse . toSeq
dropWhile p = fromSeq . S.reverse . S.dropWhile p . S.reverse . toSeq
splitWhile p (N m xs) = (N (k1) (S.reverse ys), N (mk) (S.reverse zs))
where (ys,zs) = S.splitWhile p (S.reverse xs)
k = S.size ys
zip (N m xs) (N n ys)
| m < n = N m (S.zip xs (S.drop (nm) ys))
| m > n = N n (S.zip (S.drop (mn) xs) ys)
| otherwise = N m (S.zip xs ys)
zip3 (N l xs) (N m ys) (N n zs) = N k (S.zip3 xs' ys' zs')
where k = min l (min m n)
xs' = if l == k then xs else S.drop (lk) xs
ys' = if m == k then ys else S.drop (mk) ys
zs' = if n == k then zs else S.drop (nk) zs
zipWith f (N m xs) (N n ys)
| m < n = N m (S.zipWith f xs (S.drop (nm) ys))
| m > n = N n (S.zipWith f (S.drop (mn) xs) ys)
| otherwise = N m (S.zipWith f xs ys)
zipWith3 f (N l xs) (N m ys) (N n zs) = N k (S.zipWith3 f xs' ys' zs')
where k = min l (min m n)
xs' = if l == k then xs else S.drop (lk) xs
ys' = if m == k then ys else S.drop (mk) ys
zs' = if n == k then zs else S.drop (nk) zs
unzip (N m xys) = (N m xs, N m ys)
where (xs,ys) = S.unzip xys
unzip3 (N m xyzs) = (N m xs, N m ys, N m zs)
where (xs,ys,zs) = S.unzip3 xyzs
unzipWith f g (N m xys) = (N m xs, N m ys)
where (xs,ys) = S.unzipWith f g xys
unzipWith3 f g h (N m xyzs) = (N m xs, N m ys, N m zs)
where (xs,ys,zs) = S.unzipWith3 f g h xyzs
strict s@(N _ s') = S.strict s' `seq` s
strictWith f s@(N _ s') = S.strictWith f s' `seq` s
structuralInvariant (N i s) = i == ((S.size s) 1)
instance S.Sequence s => S.Sequence (Rev s) where
{lcons = lcons; rcons = rcons;
lview = lview; lhead = lhead; ltail = ltail;
lheadM = lheadM; ltailM = ltailM; rheadM = rheadM; rtailM = rtailM;
rview = rview; rhead = rhead; rtail = rtail; null = null;
size = size; concat = concat; reverse = reverse;
reverseOnto = reverseOnto; fromList = fromList; toList = toList;
fold = fold; fold' = fold'; fold1 = fold1; fold1' = fold1';
foldr = foldr; foldr' = foldr'; foldl = foldl; foldl' = foldl';
foldr1 = foldr1; foldr1' = foldr1'; foldl1 = foldl1; foldl1' = foldl1';
reducer = reducer; reducer' = reducer'; reducel = reducel;
reducel' = reducel'; reduce1 = reduce1; reduce1' = reduce1';
copy = copy; inBounds = inBounds; lookup = lookup;
lookupM = lookupM; lookupWithDefault = lookupWithDefault;
update = update; adjust = adjust; mapWithIndex = mapWithIndex;
foldrWithIndex = foldrWithIndex; foldrWithIndex' = foldrWithIndex';
foldlWithIndex = foldlWithIndex; foldlWithIndex' = foldlWithIndex';
take = take; drop = drop; splitAt = splitAt; subseq = subseq;
filter = filter; partition = partition; takeWhile = takeWhile;
dropWhile = dropWhile; splitWhile = splitWhile; zip = zip;
zip3 = zip3; zipWith = zipWith; zipWith3 = zipWith3; unzip = unzip;
unzip3 = unzip3; unzipWith = unzipWith; unzipWith3 = unzipWith3;
strict = strict; strictWith = strictWith;
structuralInvariant = structuralInvariant; instanceName = instanceName}
instance S.Sequence s => Functor (Rev s) where
fmap = map
instance S.Sequence s => App.Alternative (Rev s) where
empty = empty
(<|>) = append
instance S.Sequence s => App.Applicative (Rev s) where
pure = return
x <*> y = do
x' <- x
y' <- y
return (x' y')
instance S.Sequence s => Monad (Rev s) where
return = singleton
xs >>= k = concatMap k xs
instance S.Sequence s => MonadPlus (Rev s) where
mplus = append
mzero = empty
instance Eq (s a) => Eq (Rev s a) where
(N m xs) == (N n ys) = (m == n) && (xs == ys)
instance (S.Sequence s, Ord a, Eq (s a)) => Ord (Rev s a) where
compare = defaultCompare
instance (S.Sequence s, Show (s a)) => Show (Rev s a) where
showsPrec i xs rest
| i == 0 = L.concat [ moduleName,".fromSeq ",showsPrec 10 (toSeq xs) rest]
| otherwise = L.concat ["(",moduleName,".fromSeq ",showsPrec 10 (toSeq xs) (')':rest)]
instance (S.Sequence s, Read (s a)) => Read (Rev s a) where
readsPrec _ xs = maybeParens p xs
where p xs = tokenMatch (moduleName++".fromSeq") xs
>>= readsPrec 10
>>= \(l,rest) -> return (fromSeq l,rest)
instance (S.Sequence s, Arbitrary (s a)) => Arbitrary (Rev s a) where
arbitrary = do xs <- arbitrary
return (fromSeq xs)
instance (S.Sequence s, CoArbitrary (s a)) => CoArbitrary (Rev s a) where
coarbitrary xs = coarbitrary (toSeq xs)
instance S.Sequence s => Monoid (Rev s a) where
mempty = empty
mappend = append