HaskCalc/cp2223t/LTree.hs


-- (c) MP-I (1998/9-2006/7) and CP (2005/6-2022/23)

module LTree where

import Cp
import Data.Monoid
import Control.Applicative
import List

-- (1) Datatype definition -----------------------------------------------------

data LTree a = Leaf a | Fork (LTree a, LTree a) deriving (Show, Eq, Ord)

inLTree :: Either a (LTree a, LTree a) -> LTree a
inLTree = either Leaf Fork

outLTree :: LTree a -> Either a (LTree a,LTree a)
outLTree (Leaf a)       = i1 a
outLTree (Fork (t1,t2)) = i2 (t1,t2)

baseLTree g f = g -|- f >< f

-- (2) Ana + cata + hylo -------------------------------------------------------

recLTree f = baseLTree id f          -- that is:  id -|- (f >< f)

cataLTree g = g . (recLTree (cataLTree g)) . outLTree

anaLTree f = inLTree . (recLTree (anaLTree f) ) . f

hyloLTree f g = cataLTree f . anaLTree g

-- (3) Map ---------------------------------------------------------------------

instance Functor LTree
         where fmap f = cataLTree ( inLTree . baseLTree f id )

-- (4) Examples ----------------------------------------------------------------

-- (4.0) Inversion (mirror) ----------------------------------------------------

mirrorLTree = cataLTree (inLTree . (id -|- swap))

-- (4.1) Count and depth -------------------------------------------------------

countLTree = cataLTree (either one add)

depth = cataLTree (either one (succ.umax))

-- (4.2) Serialization ---------------------------------------------------------

tips = cataLTree (either singl conc)

-- (4.3) Double factorial ------------------------------------------------------

dfac 0 = 1
dfac n = hyloLTree (either id mul) dfacd (1,n)

dfacd(n,m) | n==m      = i1 n
           | otherwise = i2 ((n,k),(k+1,m))
                            where k = div (n+m) 2

-- (4.4) Double square function ------------------------------------------------

dsq 0 = 0
dsq n = (cataLTree (either id add) . fmap (\n->2*n-1) . (anaLTree dfacd)) (1,n)

{--
dsq 0 = 0
dsq n = (hyloLTree (either id add) (fdfacd nthodd)) (1,n)
        where   nthodd n = 2*n - 1 
                fdfacd f (n,m) | n==m  = i1   (f n)
                               | otherwise = i2   ((n,k),(k+1,m))
                                        where k = div (n+m) 2
--}

-- (4.5) Fibonacci -------------------------------------------------------------

fib =  hyloLTree (either one add) fibd

-- where

fibd n | n < 2     = i1   ()
       | otherwise = i2   (n-1,n-2)

-- (4.6) Merge sort ------------------------------------------------------------

mSort :: Ord a => [a] -> [a]
mSort [] = []
mSort l = hyloLTree (either singl merge) lsplit l

--where

-- singl   x = [x]

merge (l,[])                  = l
merge ([],r)                  = r
merge (x:xs,y:ys) | x < y     = x : merge(xs,y:ys) 
                  | otherwise = y : merge(x:xs,ys)

lsplit [x] = i1 x
lsplit l   = i2 (sep l) where
     sep []    = ([],[])
     sep (h:t) = let (l,r) = sep t in (h:r,l)  -- a List cata

{-- pointwise version:

mSort :: Ord a => [a] -> [a]
mSort [] = []
mSort [x] = [x]
mSort l = let (l1,l2) = sep l
          in merge(mSort l1, mSort l2)
--}

-- (4.7) Double map (unordered lists) ------------------------------------------

dmap :: (b -> a) -> [b] -> [a]
dmap f [] = []
dmap f x = (hyloLTree (either (singl.f) conc) lsplit) x

-- (4.8) Double map (keeps the order) ------------------------------------------

dmap1 :: (b -> a) -> [b] -> [a]
dmap1 f [] = []
dmap1 f x = (hyloLTree (either (singl.f) conc) divide) x
     where divide [x] = i1 x
           divide l   = i2 (split (take m) (drop m) l) where m = div (length l) 2

-- (4.8) Combinations ----------------------------------------------------------

comb = hyloLTree (either id add) divide
   where divide(n,k) = if k `elem` [0,n] then i1 1 else i2((n-1,k),(n-1,k-1))

{-- pointwise: comb (n,k) = if k `elem` [0,n] then 1 else comb(n-1,k)+comb(n-1,k-1) --}

-- (5) Monads ------------------------------------------------------------------

instance Monad LTree where
     return  = Leaf
     t >>= g = (mu . fmap g) t

mu  :: LTree (LTree a) -> LTree a
mu  =  cataLTree (either id Fork)

instance Strong LTree

{-- fmap :: (Monad m) => (t -> a) -> m t -> m a
    fmap f t = do { a <- t ; return (f a) }
--}

mcataLTree g = k where
        k (Leaf a) = return(g1 a)
        k (Fork(x,y)) = do { a <- k x; b <- k y; return(g2(a,b)) }
        g1 = g . i1
        g2 = g . i2

-- (6) Going polytipic -------------------------------------------------------

-- natural transformation from base functor to monoid
tnat :: Monoid c => (a -> c) -> Either a (c, c) -> c
tnat f = either f (uncurry mappend)

-- monoid reduction 

monLTree f = cataLTree (tnat f)

-- alternative to (4.2) serialization ----------------------------------------

tips' = monLTree singl

-- alternative to (4.1) counting ---------------------------------------------

countLTree' = monLTree (const (Sum 1))

-- distributive law ----------------------------------------------------------

dlLTree :: Strong f => LTree (f a) -> f (LTree a)
dlLTree = cataLTree (either (fmap Leaf) (fmap Fork .dstr))

-- (7) Zipper ----------------------------------------------------------------

data Deriv a = Dr Bool (LTree a)

type Zipper a = [ Deriv a ]

plug :: Zipper a -> LTree a -> LTree a
plug [] t = t
plug ((Dr False l):z) t = Fork (plug z t,l) 
plug ((Dr True  r):z) t = Fork (r,plug z t)

-- (8) Advanced --------------------------------------------------------------

instance Applicative LTree where
    pure = return
    (<*>) = aap

-- (9) Spine representation --------------------------------------------------

roll = inLTree.(id -|- roll>< id).beta.(id><outList')

spinecata g = g . (id -|- (spinecata g)>< id).spineOut

spineOut = beta.(id><outList')

outList' [] = i1()
outList' x = i2(last x, blast x)

blast = reverse . tail . reverse

inList' = either nil snoc

snoc(a,x)= x++[a]

unroll = (id><inList').alpha.(id -|- unroll>< id).outLTree

alpha :: Either a ((a, t), t1) -> (a, Either () (t1, t))
alpha(Left a) = (a,Left())
alpha(Right ((a,ts),t)) = (a,Right(t,ts))

beta :: (a, Either () (t1, t)) -> Either a ((a, t), t1)
beta(a,Left()) = Left a
beta(a,Right(t,ts)) = Right ((a,ts),t)

height = cataLTree (either id (uncurry ht)) where ht a b = 1 + (max a b)

---------------------------- end of library ----------------------------------
Initial code structure 2022-11-19 11:35:14 +00:00
			`-- (c) MP-I (1998/9-2006/7) and CP (2005/6-2022/23)`

			`module LTree where`

			`import Cp`
			`import Data.Monoid`
			`import Control.Applicative`
			`import List`

			`-- (1) Datatype definition -----------------------------------------------------`

			`data LTree a = Leaf a \| Fork (LTree a, LTree a) deriving (Show, Eq, Ord)`

			`inLTree :: Either a (LTree a, LTree a) -> LTree a`
			`inLTree = either Leaf Fork`

			`outLTree :: LTree a -> Either a (LTree a,LTree a)`
			`outLTree (Leaf a) = i1 a`
			`outLTree (Fork (t1,t2)) = i2 (t1,t2)`

			`baseLTree g f = g -\|- f >< f`

			`-- (2) Ana + cata + hylo -------------------------------------------------------`

			`recLTree f = baseLTree id f -- that is: id -\|- (f >< f)`

			`cataLTree g = g . (recLTree (cataLTree g)) . outLTree`

			`anaLTree f = inLTree . (recLTree (anaLTree f) ) . f`

			`hyloLTree f g = cataLTree f . anaLTree g`

			`-- (3) Map ---------------------------------------------------------------------`

			`instance Functor LTree`
			`where fmap f = cataLTree ( inLTree . baseLTree f id )`

			`-- (4) Examples ----------------------------------------------------------------`

			`-- (4.0) Inversion (mirror) ----------------------------------------------------`

			`mirrorLTree = cataLTree (inLTree . (id -\|- swap))`

			`-- (4.1) Count and depth -------------------------------------------------------`

			`countLTree = cataLTree (either one add)`

			`depth = cataLTree (either one (succ.umax))`

			`-- (4.2) Serialization ---------------------------------------------------------`

			`tips = cataLTree (either singl conc)`

			`-- (4.3) Double factorial ------------------------------------------------------`

			`dfac 0 = 1`
			`dfac n = hyloLTree (either id mul) dfacd (1,n)`

			`dfacd(n,m) \| n==m = i1 n`
			`\| otherwise = i2 ((n,k),(k+1,m))`
			`where k = div (n+m) 2`

			`-- (4.4) Double square function ------------------------------------------------`

			`dsq 0 = 0`
			`dsq n = (cataLTree (either id add) . fmap (\n->2*n-1) . (anaLTree dfacd)) (1,n)`

			`{--`
			`dsq 0 = 0`
			`dsq n = (hyloLTree (either id add) (fdfacd nthodd)) (1,n)`
			`where nthodd n = 2*n - 1`
			`fdfacd f (n,m) \| n==m = i1 (f n)`
			`\| otherwise = i2 ((n,k),(k+1,m))`
			`where k = div (n+m) 2`
			`--}`

			`-- (4.5) Fibonacci -------------------------------------------------------------`

			`fib = hyloLTree (either one add) fibd`

			`-- where`

			`fibd n \| n < 2 = i1 ()`
			`\| otherwise = i2 (n-1,n-2)`

			`-- (4.6) Merge sort ------------------------------------------------------------`

			`mSort :: Ord a => [a] -> [a]`
			`mSort [] = []`
			`mSort l = hyloLTree (either singl merge) lsplit l`

			`--where`

			`-- singl x = [x]`

			`merge (l,[]) = l`
			`merge ([],r) = r`
			`merge (x:xs,y:ys) \| x < y = x : merge(xs,y:ys)`
			`\| otherwise = y : merge(x:xs,ys)`

			`lsplit [x] = i1 x`
			`lsplit l = i2 (sep l) where`
			`sep [] = ([],[])`
			`sep (h:t) = let (l,r) = sep t in (h:r,l) -- a List cata`

			`{-- pointwise version:`

			`mSort :: Ord a => [a] -> [a]`
			`mSort [] = []`
			`mSort [x] = [x]`
			`mSort l = let (l1,l2) = sep l`
			`in merge(mSort l1, mSort l2)`
			`--}`

			`-- (4.7) Double map (unordered lists) ------------------------------------------`

			`dmap :: (b -> a) -> [b] -> [a]`
			`dmap f [] = []`
			`dmap f x = (hyloLTree (either (singl.f) conc) lsplit) x`

			`-- (4.8) Double map (keeps the order) ------------------------------------------`

			`dmap1 :: (b -> a) -> [b] -> [a]`
			`dmap1 f [] = []`
			`dmap1 f x = (hyloLTree (either (singl.f) conc) divide) x`
			`where divide [x] = i1 x`
			`divide l = i2 (split (take m) (drop m) l) where m = div (length l) 2`

			`-- (4.8) Combinations ----------------------------------------------------------`

			`comb = hyloLTree (either id add) divide`
			where divide(n,k) = if k `elem` [0,n] then i1 1 else i2((n-1,k),(n-1,k-1))

			{-- pointwise: comb (n,k) = if k `elem` [0,n] then 1 else comb(n-1,k)+comb(n-1,k-1) --}

			`-- (5) Monads ------------------------------------------------------------------`

			`instance Monad LTree where`
			`return = Leaf`
			`t >>= g = (mu . fmap g) t`

			`mu :: LTree (LTree a) -> LTree a`
			`mu = cataLTree (either id Fork)`

			`instance Strong LTree`

			`{-- fmap :: (Monad m) => (t -> a) -> m t -> m a`
			`fmap f t = do { a <- t ; return (f a) }`
			`--}`

			`mcataLTree g = k where`
			`k (Leaf a) = return(g1 a)`
			`k (Fork(x,y)) = do { a <- k x; b <- k y; return(g2(a,b)) }`
			`g1 = g . i1`
			`g2 = g . i2`

			`-- (6) Going polytipic -------------------------------------------------------`

			`-- natural transformation from base functor to monoid`
			`tnat :: Monoid c => (a -> c) -> Either a (c, c) -> c`
			`tnat f = either f (uncurry mappend)`

			`-- monoid reduction`

			`monLTree f = cataLTree (tnat f)`

			`-- alternative to (4.2) serialization ----------------------------------------`

			`tips' = monLTree singl`

			`-- alternative to (4.1) counting ---------------------------------------------`

			`countLTree' = monLTree (const (Sum 1))`

			`-- distributive law ----------------------------------------------------------`

			`dlLTree :: Strong f => LTree (f a) -> f (LTree a)`
			`dlLTree = cataLTree (either (fmap Leaf) (fmap Fork .dstr))`

			`-- (7) Zipper ----------------------------------------------------------------`

			`data Deriv a = Dr Bool (LTree a)`

			`type Zipper a = [ Deriv a ]`

			`plug :: Zipper a -> LTree a -> LTree a`
			`plug [] t = t`
			`plug ((Dr False l):z) t = Fork (plug z t,l)`
			`plug ((Dr True r):z) t = Fork (r,plug z t)`

			`-- (8) Advanced --------------------------------------------------------------`

			`instance Applicative LTree where`
			`pure = return`
			`(<*>) = aap`

			`-- (9) Spine representation --------------------------------------------------`

			`roll = inLTree.(id -\|- roll>< id).beta.(id><outList')`

			`spinecata g = g . (id -\|- (spinecata g)>< id).spineOut`

			`spineOut = beta.(id><outList')`

			`outList' [] = i1()`
			`outList' x = i2(last x, blast x)`

			`blast = reverse . tail . reverse`

			`inList' = either nil snoc`

			`snoc(a,x)= x++[a]`

			`unroll = (id><inList').alpha.(id -\|- unroll>< id).outLTree`

			`alpha :: Either a ((a, t), t1) -> (a, Either () (t1, t))`
			`alpha(Left a) = (a,Left())`
			`alpha(Right ((a,ts),t)) = (a,Right(t,ts))`

			`beta :: (a, Either () (t1, t)) -> Either a ((a, t), t1)`
			`beta(a,Left()) = Left a`
			`beta(a,Right(t,ts)) = Right ((a,ts),t)`

			`height = cataLTree (either id (uncurry ht)) where ht a b = 1 + (max a b)`

			`---------------------------- end of library ----------------------------------`