{-# LANGUAGE TypeFamilyDependencies #-}
{-# LANGUAGE ConstraintKinds #-}
{-# LANGUAGE AllowAmbiguousTypes #-}
{-# LANGUAGE DataKinds #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE GADTs #-}
{-# LANGUAGE InstanceSigs #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE NoStarIsType #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE StandaloneDeriving #-}
{-# LANGUAGE TypeApplications #-}
{-# LANGUAGE TypeOperators #-}
{-# LANGUAGE UndecidableInstances #-}

-----------------------------------------------------------------------------
-- |
-- Module     : LAoP.Matrix.Internal
-- Copyright  : (c) Armando Santos 2019-2020
-- Maintainer : armandoifsantos@gmail.com
-- Stability  : experimental
--
-- The LAoP discipline generalises relations and functions treating them as
-- Boolean matrices and in turn consider these as arrows.
--
-- __LAoP__ is a library for algebraic (inductive) construction and manipulation of matrices
-- in Haskell. See <https://github.com/bolt12/master-thesis my Msc Thesis> for the
-- motivation behind the library, the underlying theory, and implementation details.
--
-- This module offers many of the combinators mentioned in the work of
-- Macedo (2012) and Oliveira (2012). 
--
-- This is an Internal module and it is no supposed to be imported.
--
-----------------------------------------------------------------------------

module LAoP.Matrix.Internal
  ( -- | This definition makes use of the fact that 'Void' is
    -- isomorphic to 0 and '()' to 1 and captures matrix
    -- dimensions as stacks of 'Either's.
    --
    -- There exists two type families that make it easier to write
    -- matrix dimensions: 'FromNat' and 'Count'. This approach
    -- leads to a very straightforward implementation 
    -- of LAoP combinators. 

    -- * Type safe matrix representation
    Matrix (..),

    -- * Primitives
    empty,
    one,
    junc,
    split,

    -- * Auxiliary type families
    FromNat,
    Count,
    Normalize,

    -- * Matrix construction and conversion
    FromLists,
    fromLists,
    toLists,
    toList,
    matrixBuilder,
    row,
    col,
    zeros,
    ones,
    bang,
    constant,

    -- * Misc
    -- ** Get dimensions
    columns,
    rows,

    -- ** Matrix Transposition
    tr,

    -- ** Selective operator
    select,

    -- ** McCarthy's Conditional
    cond,

    -- ** Matrix "abiding"
    abideJS,
    abideSJ,

    -- * Biproduct approach
    -- ** Split
    (===),
    -- *** Projections
    p1,
    p2,
    -- ** Junc
    (|||),
    -- *** Injections
    i1,
    i2,
    -- ** Bifunctors
    (-|-),
    (><),

    -- ** Applicative matrix combinators

    -- | Note that given the restrictions imposed it is not possible to
    -- implement the standard type classes present in standard Haskell.
    -- *** Matrix pairing projections
    kp1,
    kp2,

    -- *** Matrix pairing
    khatri,

    -- * Matrix composition and lifting

    -- ** Arrow matrix combinators

    -- | Note that given the restrictions imposed it is not possible to
    -- implement the standard type classes present in standard Haskell.
    identity,
    comp,
    fromF,
    fromF',

    -- * Matrix printing
    pretty,
    prettyPrint,

    -- * Other
    toBool,
    fromBool,
    compRel,
    divR,
    divL,
    divS,
    fromFRel,
    fromFRel',
    toRel,
    negateM,
    orM,
    andM,
    subM
  )
    where

import LAoP.Utils.Internal
import Data.Bool
import Data.Kind
import Data.List
import Data.Proxy
import Data.Void
import GHC.TypeLits
import Data.Type.Equality
import GHC.Generics
import Control.DeepSeq
import Control.Category
import Prelude hiding ((.))

-- | LAoP (Linear Algebra of Programming) Inductive Matrix definition.
data Matrix e cols rows where
  Empty :: Matrix e Void Void
  One :: e -> Matrix e () ()
  Junc :: Matrix e a rows -> Matrix e b rows -> Matrix e (Either a b) rows
  Split :: Matrix e cols a -> Matrix e cols b -> Matrix e cols (Either a b)

deriving instance (Show e) => Show (Matrix e cols rows)

-- | Type family that computes the cardinality of a given type dimension.
--
--   It can also count the cardinality of custom types that implement the
-- 'Generic' instance.
type family Count (d :: Type) :: Nat where
  Count (Natural n m) = (m - n) + 1
  Count (Powerset a)  = (^) (Count a) (Count a)
  Count (Either a b)  = (+) (Count a) (Count b)
  Count (a, b)        = (*) (Count a) (Count b)
  Count (a -> b)      = (^) (Count b) (Count a)
  -- Generics
  Count (M1 _ _ f p)  = Count (f p)
  Count (K1 _ _ _)    = 1
  Count (V1 _)        = 0
  Count (U1 _)        = 1
  Count ((:*:) a b p) = Count (a p) * Count (b p)
  Count ((:+:) a b p) = Count (a p) + Count (b p)
  Count d             = Count (Rep d R)

-- | Type family that computes of a given type dimension from a given natural
--
--   Thanks to Li-Yao Xia this type family is super fast.
type family FromNat (n :: Nat) :: Type where
  FromNat 0 = Void
  FromNat 1 = ()
  FromNat n = FromNat' (Mod n 2 == 0) (FromNat (Div n 2))

type family FromNat' (b :: Bool) (m :: Type) :: Type where
  FromNat' 'True m = Either m m
  FromNat' 'False m = Either () (Either m m)

-- | Type family that normalizes the representation of a given data
-- structure
type family Normalize (d :: Type) :: Type where
  Normalize d = FromNat (Count d)

-- | Constraint type synonyms to keep the type signatures less convoluted
type Countable a = KnownNat (Count a)
type CountableN a = KnownNat (Count (Normalize a))
type CountableDimensions a b = (Countable a, Countable b)
type CountableDimensionsN a b = (CountableN a, CountableN b)
type FromListsN e a b = FromLists e (Normalize a) (Normalize b)
type Liftable e a b = (Bounded a, Bounded b, Enum a, Enum b, Eq b, Num e, Ord e)

-- | It isn't possible to implement the 'id' function so it's
-- implementation is 'undefined'. However 'comp' can be and this partial
-- class implementation exists just to make the code more readable.
--
-- Please use 'identity' instead.
instance (Num e) => Category (Matrix e) where
    id = undefined
    (.) = comp

instance NFData e => NFData (Matrix e cols rows) where
    rnf Empty = ()
    rnf (One e) = rnf e
    rnf (Junc a b) = rnf a `seq` rnf b
    rnf (Split a b) = rnf a `seq` rnf b

instance Eq e => Eq (Matrix e cols rows) where
  Empty == Empty                = True
  (One a) == (One b)            = a == b
  (Junc a b) == (Junc c d)      = a == c && b == d
  (Split a b) == (Split c d)    = a == c && b == d
  x@(Split _ _) == y@(Junc _ _) = x == abideJS y
  x@(Junc _ _) == y@(Split _ _) = abideJS x == y

instance Num e => Num (Matrix e cols rows) where

  Empty + Empty                = Empty
  (One a) + (One b)            = One (a + b)
  (Junc a b) + (Junc c d)      = Junc (a + c) (b + d)
  (Split a b) + (Split c d)    = Split (a + c) (b + d)
  x@(Split _ _) + y@(Junc _ _) = x + abideJS y
  x@(Junc _ _) + y@(Split _ _) = abideJS x + y

  Empty - Empty             = Empty
  (One a) - (One b)         = One (a - b)
  (Junc a b) - (Junc c d)   = Junc (a - c) (b - d)
  (Split a b) - (Split c d) = Split (a - c) (b - d)
  x@(Split _ _) - y@(Junc _ _) = x - abideJS y
  x@(Junc _ _) - y@(Split _ _) = abideJS x - y

  Empty * Empty             = Empty
  (One a) * (One b)         = One (a * b)
  (Junc a b) * (Junc c d)   = Junc (a * c) (b * d)
  (Split a b) * (Split c d) = Split (a * c) (b * d)
  x@(Split _ _) * y@(Junc _ _) = x * abideJS y
  x@(Junc _ _) * y@(Split _ _) = abideJS x * y

  abs Empty       = Empty
  abs (One a)     = One (abs a)
  abs (Junc a b)  = Junc (abs a) (abs b)
  abs (Split a b) = Split (abs a) (abs b)

  signum Empty       = Empty
  signum (One a)     = One (signum a)
  signum (Junc a b)  = Junc (signum a) (signum b)
  signum (Split a b) = Split (signum a) (signum b)

instance Ord e => Ord (Matrix e cols rows) where
    Empty <= Empty                = True
    (One a) <= (One b)            = a <= b
    (Junc a b) <= (Junc c d)      = (a <= c) && (b <= d)
    (Split a b) <= (Split c d)    = (a <= c) && (b <= d)
    x@(Split _ _) <= y@(Junc _ _) = x <= abideJS y
    x@(Junc _ _) <= y@(Split _ _) = abideJS x <= y

-- Primitives

-- | Empty matrix constructor
empty :: Matrix e Void Void
empty = Empty

-- | Unit matrix constructor
one :: e -> Matrix e () ()
one = One

-- | Matrix 'Junc' constructor
junc :: Matrix e a rows -> Matrix e b rows -> Matrix e (Either a b) rows
junc = Junc

infixl 3 |||

-- | Matrix 'Junc' constructor
(|||) :: Matrix e a rows -> Matrix e b rows -> Matrix e (Either a b) rows
(|||) = Junc

-- | Matrix 'Split' constructor
split :: Matrix e cols a -> Matrix e cols b -> Matrix e cols (Either a b)
split = Split

infixl 2 ===

-- | Matrix 'Split' constructor
(===) :: Matrix e cols a -> Matrix e cols b -> Matrix e cols (Either a b)
(===) = Split

-- Construction

-- | Type class for defining the 'fromList' conversion function.
--
--   Given that it is not possible to branch on types at the term level type
-- classes are needed bery much like an inductive definition but on types.
class FromLists e cols rows where
  -- | Build a matrix out of a list of list of elements. Throws a runtime
  -- error if the dimensions do not match.
  fromLists :: [[e]] -> Matrix e cols rows

instance FromLists e Void Void where
  fromLists [] = Empty
  fromLists _  = error "Wrong dimensions"

instance {-# OVERLAPPING #-} FromLists e () () where
  fromLists [[e]] = One e
  fromLists _     = error "Wrong dimensions"

instance {-# OVERLAPPING #-} (FromLists e cols ()) => FromLists e (Either () cols) () where
  fromLists [h : t] = Junc (One h) (fromLists [t])
  fromLists _       = error "Wrong dimensions"

instance {-# OVERLAPPABLE #-} (FromLists e a (), FromLists e b (), Countable a) => FromLists e (Either a b) () where
  fromLists [l] =
      let rowsA = fromInteger (natVal (Proxy :: Proxy (Count a)))
       in Junc (fromLists [take rowsA l]) (fromLists [drop rowsA l])
  fromLists _       = error "Wrong dimensions"

instance {-# OVERLAPPING #-} (FromLists e () rows) => FromLists e () (Either () rows) where
  fromLists ([h] : t) = Split (One h) (fromLists t)
  fromLists _         = error "Wrong dimensions"

instance {-# OVERLAPPABLE #-} (FromLists e () a, FromLists e () b, Countable a) => FromLists e () (Either a b) where
  fromLists l@([_] : _) =
      let rowsA = fromInteger (natVal (Proxy :: Proxy (Count a)))
       in Split (fromLists (take rowsA l)) (fromLists (drop rowsA l))
  fromLists _         = error "Wrong dimensions"

instance {-# OVERLAPPABLE #-} (FromLists e (Either a b) c, FromLists e (Either a b) d, Countable c) => FromLists e (Either a b) (Either c d) where
  fromLists l@(h : t) =
    let lh        = length h
        rowsC     = fromInteger (natVal (Proxy :: Proxy (Count c)))
        condition = all (== lh) (map length t)
     in if lh > 0 && condition
          then Split (fromLists (take rowsC l)) (fromLists (drop rowsC l))
          else error "Not all rows have the same length"

-- | Matrix builder function. Constructs a matrix provided with
-- a construction function.
matrixBuilder ::
  forall e cols rows.
  ( FromLists e cols rows,
    CountableDimensions cols rows
  ) =>
  ((Int, Int) -> e) ->
  Matrix e cols rows
matrixBuilder f =
  let c         = fromInteger $ natVal (Proxy :: Proxy (Count cols))
      r         = fromInteger $ natVal (Proxy :: Proxy (Count rows))
      positions = [(a, b) | a <- [0 .. (r - 1)], b <- [0 .. (c - 1)]]
   in fromLists . map (map f) . groupBy (\(x, _) (w, _) -> x == w) $ positions

-- | Constructs a column vector matrix
col :: (FromLists e () rows) => [e] -> Matrix e () rows
col = fromLists . map (: [])

-- | Constructs a row vector matrix
row :: (FromLists e cols ()) => [e] -> Matrix e cols ()
row = fromLists . (: [])

-- | Lifts functions to matrices with arbitrary dimensions.
--
--   NOTE: Be careful to not ask for a matrix bigger than the cardinality of
-- types @a@ or @b@ allows.
fromF ::
  forall a b cols rows e.
  ( Liftable e a b,
    CountableDimensions cols rows,
    FromLists e rows cols
  ) =>
  (a -> b) ->
  Matrix e cols rows
fromF f =
  let minA         = minBound @a
      maxA         = maxBound @a
      minB         = minBound @b
      maxB         = maxBound @b
      ccols        = fromInteger $ natVal (Proxy :: Proxy (Count cols))
      rrows        = fromInteger $ natVal (Proxy :: Proxy (Count rows))
      elementsA    = take ccols [minA .. maxA]
      elementsB    = take rrows [minB .. maxB]
      combinations = (,) <$> elementsA <*> elementsB
      combAp       = map snd . sort . map (\(a, b) -> if f a == b
                                                         then ((fromEnum a, fromEnum b), 1)
                                                         else ((fromEnum a, fromEnum b), 0)) $ combinations
      mList        = buildList combAp rrows
   in tr $ fromLists mList
  where
    buildList [] _ = []
    buildList l r  = take r l : buildList (drop r l) r

-- | Lifts functions to matrices with dimensions matching @a@ and @b@
-- cardinality's.
fromF' ::
  forall a b e.
  ( Liftable e a b,
    CountableDimensionsN a b,
    FromListsN e b a
  ) =>
  (a -> b) ->
  Matrix e (Normalize a) (Normalize b)
fromF' f =
  let minA         = minBound @a
      maxA         = maxBound @a
      minB         = minBound @b
      maxB         = maxBound @b
      ccols        = fromInteger $ natVal (Proxy :: Proxy (Count (Normalize a)))
      rrows        = fromInteger $ natVal (Proxy :: Proxy (Count (Normalize b)))
      elementsA    = take ccols [minA .. maxA]
      elementsB    = take rrows [minB .. maxB]
      combinations = (,) <$> elementsA <*> elementsB
      combAp       = map snd . sort . map (\(a, b) -> if f a == b
                                                         then ((fromEnum a, fromEnum b), 1)
                                                         else ((fromEnum a, fromEnum b), 0)) $ combinations
      mList        = buildList combAp rrows
   in tr $ fromLists mList
  where
    buildList [] _ = []
    buildList l r  = take r l : buildList (drop r l) r

-- Conversion

-- | Converts a matrix to a list of lists of elements.
toLists :: Matrix e cols rows -> [[e]]
toLists Empty       = []
toLists (One e)     = [[e]]
toLists (Split l r) = toLists l ++ toLists r
toLists (Junc l r)  = zipWith (++) (toLists l) (toLists r)

-- | Converts a matrix to a list of elements.
toList :: Matrix e cols rows -> [e]
toList = concat . toLists

-- Zeros Matrix

-- | The zero matrix. A matrix wholly filled with zeros.
zeros :: (Num e, FromLists e cols rows, CountableDimensions cols rows) => Matrix e cols rows
zeros = matrixBuilder (const 0)

-- Ones Matrix

-- | The ones matrix. A matrix wholly filled with ones.
--
--   Also known as T (Top) matrix.
ones :: (Num e, FromLists e cols rows, CountableDimensions cols rows) => Matrix e cols rows
ones = matrixBuilder (const 1)

-- Const Matrix

-- | The constant matrix constructor. A matrix wholly filled with a given
-- value.
constant :: (Num e, FromLists e cols rows, CountableDimensions cols rows) => e -> Matrix e cols rows
constant e = matrixBuilder (const e)

-- Bang Matrix

-- | The T (Top) row vector matrix.
bang :: forall e cols. (Num e, Enum e, FromLists e cols (), Countable cols) => Matrix e cols ()
bang =
  let c = fromInteger $ natVal (Proxy :: Proxy (Count cols))
   in fromLists [take c [1, 1 ..]]

-- Identity Matrix

-- | Identity matrix.
identity :: (Num e, FromLists e cols cols, Countable cols) => Matrix e cols cols
identity = matrixBuilder (bool 0 1 . uncurry (==))

-- Matrix composition (MMM)

-- | Matrix composition. Equivalent to matrix-matrix multiplication.
--
--   This definition takes advantage of divide-and-conquer and fusion laws
-- from LAoP.
comp :: (Num e) => Matrix e cr rows -> Matrix e cols cr -> Matrix e cols rows
comp Empty Empty            = Empty
comp (One a) (One b)        = One (a * b)
comp (Junc a b) (Split c d) = comp a c + comp b d         -- Divide-and-conquer law
comp (Split a b) c          = Split (comp a c) (comp b c) -- Split fusion law
comp c (Junc a b)           = Junc (comp c a) (comp c b)  -- Junc fusion law

-- Projections

-- | Biproduct first component projection
p1 :: forall e m n. (Num e, CountableDimensions n m, FromLists e n m, FromLists e m m) => Matrix e (Either m n) m
p1 =
  let iden = identity :: Matrix e m m
      zero = zeros :: Matrix e n m
   in junc iden zero

-- | Biproduct second component projection
p2 :: forall e m n. (Num e, CountableDimensions n m, FromLists e m n, FromLists e n n) => Matrix e (Either m n) n
p2 =
  let iden = identity :: Matrix e n n
      zero = zeros :: Matrix e m n
   in junc zero iden

-- Injections

-- | Biproduct first component injection
i1 :: (Num e, CountableDimensions n m, FromLists e n m, FromLists e m m) => Matrix e m (Either m n)
i1 = tr p1

-- | Biproduct second component injection
i2 :: (Num e, CountableDimensions n m, FromLists e m n, FromLists e n n) => Matrix e n (Either m n)
i2 = tr p2

-- Dimensions

-- | Obtain the number of rows.
--
--   NOTE: The 'KnownNat' constaint is needed in order to obtain the
-- dimensions in constant time.
--
-- TODO: A 'rows' function that does not need the 'KnownNat' constraint in
-- exchange for performance.
rows :: forall e cols rows. (Countable rows) => Matrix e cols rows -> Int
rows _ = fromInteger $ natVal (Proxy :: Proxy (Count rows))

-- | Obtain the number of columns.
-- 
--   NOTE: The 'KnownNat' constaint is needed in order to obtain the
-- dimensions in constant time.
--
-- TODO: A 'columns' function that does not need the 'KnownNat' constraint in
-- exchange for performance.
columns :: forall e cols rows. (Countable cols) => Matrix e cols rows -> Int
columns _ = fromInteger $ natVal (Proxy :: Proxy (Count cols))

-- Coproduct Bifunctor

infixl 5 -|-

-- | Matrix coproduct functor also known as matrix direct sum.
(-|-) ::
  forall e n k m j.
  ( Num e,
    CountableDimensions j k,
    FromLists e k k,
    FromLists e j k,
    FromLists e k j,
    FromLists e j j
  ) =>
  Matrix e n k ->
  Matrix e m j ->
  Matrix e (Either n m) (Either k j)
(-|-) a b = Junc (i1 . a) (i2 . b)

-- Khatri Rao Product and projections

-- | Khatri Rao product first component projection matrix.
kp1 ::
  forall e m k .
  ( Num e,
    CountableDimensions k m,
    FromLists e (Normalize (m, k)) m,
    CountableN (m, k)
  ) => Matrix e (Normalize (m, k)) m
kp1 = matrixBuilder f
  where
    offset = fromInteger (natVal (Proxy :: Proxy (Count k)))
    f (x, y)
      | y >= (x * offset) && y <= (x * offset + offset - 1) = 1
      | otherwise = 0

-- | Khatri Rao product second component projection matrix.
kp2 ::
    forall e m k .
    ( Num e,
      CountableDimensions k m,
      FromLists e (Normalize (m, k)) k,
      CountableN (m, k)
    ) => Matrix e (Normalize (m, k)) k
kp2 = matrixBuilder f
  where
    offset = fromInteger (natVal (Proxy :: Proxy (Count k)))
    f (x, y)
      | x == y || mod (y - x) offset == 0 = 1
      | otherwise                         = 0

-- | Khatri Rao Matrix product also known as matrix pairing.
--
--   NOTE: That this is not a true categorical product, see for instance:
-- 
-- @
--                | kp1 . khatri a b == a 
-- khatri a b ==> |
--                | kp2 . khatri a b == b
-- @
--
-- __Emphasis__ on the implication symbol.
khatri ::
       forall e cols a b.
       ( Num e,
         CountableDimensions a b,
         CountableN (a, b),
         FromLists e (Normalize (a, b)) a,
         FromLists e (Normalize (a, b)) b
       ) => Matrix e cols a -> Matrix e cols b -> Matrix e cols (Normalize (a, b))
khatri a b =
  let kp1' = kp1 @e @a @b
      kp2' = kp2 @e @a @b
   in (tr kp1') . a * (tr kp2') . b

-- Product Bifunctor (Kronecker)

infixl 4 ><

-- | Matrix product functor also known as kronecker product
(><) ::
     forall e m p n q.
     ( Num e,
       CountableDimensions m n,
       CountableDimensions p q,
       CountableDimensionsN (m, n) (p, q),
       FromLists e (Normalize (m, n)) m,
       FromLists e (Normalize (m, n)) n,
       FromLists e (Normalize (p, q)) p,
       FromLists e (Normalize (p, q)) q
     )
     => Matrix e m p -> Matrix e n q -> Matrix e (Normalize (m, n)) (Normalize (p, q))
(><) a b =
  let kp1' = kp1 @e @m @n
      kp2' = kp2 @e @m @n
   in khatri (a . kp1') (b . kp2')

-- Matrix abide Junc Split

-- | Matrix "abiding" followin the 'Junc'-'Split' abide law.
-- 
-- Law:
--
-- @
-- 'Junc' ('Split' a c) ('Split' b d) == 'Split' ('Junc' a b) ('Junc' c d)
-- @
abideJS :: Matrix e cols rows -> Matrix e cols rows
abideJS (Junc (Split a c) (Split b d)) = Split (Junc (abideJS a) (abideJS b)) (Junc (abideJS c) (abideJS d)) -- Junc-Split abide law
abideJS Empty                          = Empty
abideJS (One e)                        = One e
abideJS (Junc a b)                     = Junc (abideJS a) (abideJS b)
abideJS (Split a b)                    = Split (abideJS a) (abideJS b)

-- Matrix abide Split Junc

-- | Matrix "abiding" followin the 'Split'-'Junc' abide law.
-- 
-- @
-- 'Split' ('Junc' a b) ('Junc' c d) == 'Junc' ('Split' a c) ('Split' b d)
-- @
abideSJ :: Matrix e cols rows -> Matrix e cols rows
abideSJ (Split (Junc a b) (Junc c d)) = Junc (Split (abideSJ a) (abideSJ c)) (Split (abideSJ b) (abideSJ d)) -- Split-Junc abide law
abideSJ Empty                         = Empty
abideSJ (One e)                       = One e
abideSJ (Junc a b)                    = Junc (abideSJ a) (abideSJ b)
abideSJ (Split a b)                   = Split (abideSJ a) (abideSJ b)

-- Matrix transposition

-- | Matrix transposition.
tr :: Matrix e cols rows -> Matrix e rows cols
tr Empty       = Empty
tr (One e)     = One e
tr (Junc a b)  = Split (tr a) (tr b)
tr (Split a b) = Junc (tr a) (tr b)

-- Selective 'select' operator

-- | Selective functors 'select' operator equivalent inspired by the
-- ArrowMonad solution presented in the paper.
select :: (Num e, FromLists e b b, Countable b) => Matrix e cols (Either a b) -> Matrix e a b -> Matrix e cols b
select m y = junc y identity . m

-- McCarthy's Conditional

-- | McCarthy's Conditional expresses probabilistic choice.
cond ::
     ( cols ~ Normalize cols,
       Countable cols,
       FromLists e () cols,
       FromLists e cols (),
       FromLists e cols cols,
       Bounded a,
       Enum a,
       Num e,
       Ord e
     )
     =>
     (a -> Bool) -> Matrix e cols rows -> Matrix e cols rows -> Matrix e cols rows
cond p f g = junc f g . grd p

grd ::
    ( q ~ Normalize q,
      Countable q,
      FromLists e () q,
      FromLists e q (),
      FromLists e q q,
      Bounded a,
      Enum a,
      Num e,
      Ord e
    )
    =>
    (a -> Bool) -> Matrix e q (Either q q)
grd f = split (corr f) (corr (not . f))

corr ::
    forall e a q .
    ( q ~ Normalize q,
      Countable q,
      FromLists e () q,
      FromLists e q (),
      FromLists e q q,
      Liftable e a Bool
    )
     => (a -> Bool) -> Matrix e q q
corr p = let f = fromF p :: Matrix e q ()
          in khatri f (identity :: Matrix e q q)

-- Pretty print

prettyAux :: Show e => [[e]] -> [[e]] -> String
prettyAux [] _     = ""
prettyAux [[e]] m   = "│ " ++ fill (show e) ++ " │\n"
  where
   v  = fmap show m
   widest = maximum $ fmap length v
   fill str = replicate (widest - length str - 2) ' ' ++ str
prettyAux [h] m     = "│ " ++ fill (unwords $ map show h) ++ " │\n"
  where
   v  = fmap show m
   widest = maximum $ fmap length v
   fill str = replicate (widest - length str - 2) ' ' ++ str
prettyAux (h : t) l = "│ " ++ fill (unwords $ map show h) ++ " │\n" ++
                      prettyAux t l
  where
   v  = fmap show l
   widest = maximum $ fmap length v
   fill str = replicate (widest - length str - 2) ' ' ++ str

-- | Matrix pretty printer
pretty :: (Countable cols, Show e) => Matrix e cols rows -> String
pretty m = "┌ " ++ unwords (replicate (columns m) blank) ++ " ┐\n" ++
            prettyAux (toLists m) (toLists m) ++
            "└ " ++ unwords (replicate (columns m) blank) ++ " ┘"
  where
   v  = fmap show (toList m)
   widest = maximum $ fmap length v
   fill str = replicate (widest - length str) ' ' ++ str
   blank = fill ""

-- | Matrix pretty printer
prettyPrint :: (Countable cols, Show e) => Matrix e cols rows -> IO ()
prettyPrint = putStrLn . pretty

-- Relational operators functions

type Boolean = Natural 0 1
type Relation a b = Matrix Boolean a b

-- | Helper conversion function
toBool :: (Num e, Eq e) => e -> Bool
toBool n
  | n == 0 = False
  | n == 1 = True

-- | Helper conversion function
fromBool :: Bool -> Natural 0 1
fromBool True  = nat 1
fromBool False = nat 0

-- | Relational negation
negateM :: Relation cols rows -> Relation cols rows
negateM Empty         = Empty
negateM (One (Nat 0)) = One (Nat 1)
negateM (One (Nat 1)) = One (Nat 0)
negateM (Junc a b)    = Junc (negateM a) (negateM b)
negateM (Split a b)   = Split (negateM a) (negateM b)

-- | Relational addition
orM :: Relation cols rows -> Relation cols rows -> Relation cols rows
orM Empty Empty                = Empty
orM (One a) (One b)            = One (fromBool (toBool a || toBool b))
orM (Junc a b) (Junc c d)      = Junc (orM a c) (orM b d)
orM (Split a b) (Split c d)    = Split (orM a c) (orM b d)
orM x@(Split _ _) y@(Junc _ _) = orM x (abideJS y)
orM x@(Junc _ _) y@(Split _ _) = orM (abideJS x) y

-- | Relational multiplication
andM :: Relation cols rows -> Relation cols rows -> Relation cols rows
andM Empty Empty                = Empty
andM (One a) (One b)            = One (fromBool (toBool a && toBool b))
andM (Junc a b) (Junc c d)      = Junc (andM a c) (andM b d)
andM (Split a b) (Split c d)    = Split (andM a c) (andM b d)
andM x@(Split _ _) y@(Junc _ _) = andM x (abideJS y)
andM x@(Junc _ _) y@(Split _ _) = andM (abideJS x) y

-- | Relational subtraction
subM :: Relation cols rows -> Relation cols rows -> Relation cols rows
subM Empty Empty                = Empty
subM (One a) (One b)            = if a - b < nat 0 then One (nat 0) else One (a - b)
subM (Junc a b) (Junc c d)      = Junc (subM a c) (subM b d)
subM (Split a b) (Split c d)    = Split (subM a c) (subM b d)
subM x@(Split _ _) y@(Junc _ _) = subM x (abideJS y)
subM x@(Junc _ _) y@(Split _ _) = subM (abideJS x) y

-- | Matrix relational composition.
compRel :: Relation cr rows -> Relation cols cr -> Relation cols rows
compRel Empty Empty            = Empty
compRel (One a) (One b)        = One (fromBool (toBool a && toBool b))
compRel (Junc a b) (Split c d) = orM (compRel a c) (compRel b d)   -- Divide-and-conquer law
compRel (Split a b) c          = Split (compRel a c) (compRel b c) -- Split fusion law
compRel c (Junc a b)           = Junc (compRel c a) (compRel c b)  -- Junc fusion law

-- | Matrix relational right division
divR :: Relation b c -> Relation b a -> Relation a c
divR Empty Empty           = Empty
divR (One a) (One b)       = One (fromBool (not (toBool b) || toBool a)) -- b implies a
divR (Junc a b) (Junc c d) = andM (divR a c) (divR b d)
divR (Split a b) c         = Split (divR a c) (divR b c)
divR c (Split a b)         = Junc (divR c a) (divR c b)

-- | Matrix relational left division
divL :: Relation c b -> Relation a b -> Relation a c
divL x y = tr (divR (tr y) (tr x))

-- | Matrix relational symmetric division
divS :: Relation c a -> Relation b a -> Relation c b
divS s r = divL r s `intersection` divR (tr r) (tr s)
  where
    intersection = andM

-- | Lifts functions to relations with arbitrary dimensions.
--
--   NOTE: Be careful to not ask for a relation bigger than the cardinality of
-- types @a@ or @b@ allows.
fromFRel ::
  forall a b cols rows.
  ( Liftable Boolean a b,
    CountableDimensions cols rows,
    FromLists Boolean rows cols
  ) =>
  (a -> b) ->
  Relation cols rows
fromFRel f =
  let minA         = minBound @a
      maxA         = maxBound @a
      minB         = minBound @b
      maxB         = maxBound @b
      ccols        = fromInteger $ natVal (Proxy :: Proxy (Count cols))
      rrows        = fromInteger $ natVal (Proxy :: Proxy (Count rows))
      elementsA    = take ccols [minA .. maxA]
      elementsB    = take rrows [minB .. maxB]
      combinations = (,) <$> elementsA <*> elementsB
      combAp       = map snd . sort . map (\(a, b) -> if f a == b
                                                         then ((fromEnum a, fromEnum b), nat 1)
                                                         else ((fromEnum a, fromEnum b), nat 0)) $ combinations
      mList        = buildList combAp rrows
   in tr $ fromLists mList
  where
    buildList [] _ = []
    buildList l r  = take r l : buildList (drop r l) r

-- | Lifts functions to relations with dimensions matching @a@ and @b@
-- cardinality's.
fromFRel' ::
  forall a b.
  ( Liftable Boolean a b,
    CountableDimensionsN a b,
    FromLists Boolean (Normalize b) (Normalize a)
  ) =>
  (a -> b) ->
  Relation (Normalize a) (Normalize b)
fromFRel' f =
  let minA         = minBound @a
      maxA         = maxBound @a
      minB         = minBound @b
      maxB         = maxBound @b
      ccols        = fromInteger $ natVal (Proxy :: Proxy (Count (Normalize a)))
      rrows        = fromInteger $ natVal (Proxy :: Proxy (Count (Normalize b)))
      elementsA    = take ccols [minA .. maxA]
      elementsB    = take rrows [minB .. maxB]
      combinations = (,) <$> elementsA <*> elementsB
      combAp       = map snd . sort . map (\(a, b) -> if f a == b
                                                         then ((fromEnum a, fromEnum b), nat 1)
                                                         else ((fromEnum a, fromEnum b), nat 0)) $ combinations
      mList        = buildList combAp rrows
   in tr $ fromLists mList
  where
    buildList [] _ = []
    buildList l r  = take r l : buildList (drop r l) r

-- | Lifts a relation function to a Boolean Matrix
toRel ::
      forall a b.
      ( Bounded a,
        Bounded b,
        Enum a,
        Enum b,
        Eq b,
        CountableDimensionsN a b,
        FromListsN Boolean b a
      )
      => (a -> b -> Bool) -> Relation (Normalize a) (Normalize b)
toRel f =
  let minA         = minBound @a
      maxA         = maxBound @a
      minB         = minBound @b
      maxB         = maxBound @b
      ccols        = fromInteger $ natVal (Proxy :: Proxy (Count (Normalize a)))
      rrows        = fromInteger $ natVal (Proxy :: Proxy (Count (Normalize b)))
      elementsA    = take ccols [minA .. maxA]
      elementsB    = take rrows [minB .. maxB]
      combinations = (,) <$> elementsA <*> elementsB
      combAp       = map snd . sort . map (\(a, b) -> if uncurry f (a, b)
                                                         then ((fromEnum a, fromEnum b), nat 1)
                                                         else ((fromEnum a, fromEnum b), nat 0)) $ combinations
      mList        = buildList combAp rrows
   in tr $ fromLists mList
  where
    buildList [] _ = []
    buildList l r  = take r l : buildList (drop r l) r