module Test.StateMachine.Z where
import qualified Data.List as List
union :: Eq a => [a] -> [a] -> [a]
union = List.union
intersect :: Eq a => [a] -> [a] -> [a]
intersect = List.intersect
isSubsetOf :: Eq a => [a] -> [a] -> Bool
r `isSubsetOf` s = r == r `intersect` s
(~=) :: Eq a => [a] -> [a] -> Bool
xs ~= ys = xs `isSubsetOf` ys && ys `isSubsetOf` xs
type Rel a b = [(a, b)]
type Fun a b = Rel a b
empty :: Rel a b
empty = []
identity :: [a] -> Rel a a
identity xs = [ (x, x) | x <- xs ]
singleton :: a -> b -> Rel a b
singleton x y = [(x, y)]
domain :: Rel a b -> [a]
domain xys = [ x | (x, _) <- xys ]
codomain :: Rel a b -> [b]
codomain xys = [ y | (_, y) <- xys ]
compose :: Eq b => Rel b c -> Rel a b -> Rel a c
compose yzs xys =
[ (x, z)
| (x, y) <- xys
, (y', z) <- yzs
, y == y'
]
fcompose :: Eq b => Rel a b -> Rel b c -> Rel a c
fcompose r s = compose s r
inverse :: Rel a b -> Rel b a
inverse xys = [ (y, x) | (x, y) <- xys ]
lookupDom :: Eq a => a -> Rel a b -> [b]
lookupDom x xys = xys >>= \(x', y) -> [ y | x == x' ]
lookupCod :: Eq b => b -> Rel a b -> [a]
lookupCod y xys = xys >>= \(x, y') -> [ x | y == y' ]
(<|) :: Eq a => [a] -> Rel a b -> Rel a b
xs <| xys = [ (x, y) | (x, y) <- xys, x `elem` xs ]
(|>) :: Eq b => Rel a b -> [b] -> Rel a b
xys |> ys = [ (x, y) | (x, y) <- xys, y `elem` ys ]
(<-|) :: Eq a => [a] -> Rel a b -> Rel a b
xs <-| xys = [ (x, y) | (x, y) <- xys, x `notElem` xs ]
(|->) :: Eq b => Rel a b -> [b] -> Rel a b
xys |-> ys = [ (x, y) | (x, y) <- xys, y `notElem` ys ]
image :: Eq a => Rel a b -> [a] -> [b]
image r xs = codomain (xs <| r)
(<+) :: (Eq a, Eq b) => Rel a b -> Rel a b -> Rel a b
r <+ s = domain s <-| r `union` s
(<**>) :: Eq a => Rel a b -> Rel a c -> Rel a (b, c)
xys <**> xzs =
[ (x, (y, z))
| (x , y) <- xys
, (x', z) <- xzs
, x == x'
]
(<||>) :: Rel a c -> Rel b d -> Rel (a, b) (c, d)
acs <||> bds =
[ ((a, b), (c, d))
| (a, c) <- acs
, (b, d) <- bds
]
isTotalRel :: Eq a => Rel a b -> [a] -> Bool
isTotalRel r xs = domain r ~= xs
isSurjRel :: Eq b => Rel a b -> [b] -> Bool
isSurjRel r ys = codomain r ~= ys
isTotalSurjRel :: (Eq a, Eq b) => Rel a b -> [a] -> [b] -> Bool
isTotalSurjRel r xs ys = isTotalRel r xs && isSurjRel r ys
isPartialFun :: (Eq a, Eq b) => Rel a b -> Bool
isPartialFun f = (f `compose` inverse f) ~= identity (codomain f)
isTotalFun :: (Eq a, Eq b) => Rel a b -> [a] -> Bool
isTotalFun r xs = isPartialFun r && isTotalRel r xs
isPartialInj :: (Eq a, Eq b) => Rel a b -> Bool
isPartialInj r = isPartialFun r && isPartialFun (inverse r)
isTotalInj :: (Eq a, Eq b) => Rel a b -> [a] -> Bool
isTotalInj r xs = isTotalFun r xs && isPartialFun (inverse r)
isPartialSurj :: (Eq a, Eq b) => Rel a b -> [b] -> Bool
isPartialSurj r ys = isPartialFun r && isSurjRel r ys
isTotalSurj :: (Eq a, Eq b) => Rel a b -> [a] -> [b] -> Bool
isTotalSurj r xs ys = isTotalFun r xs && isSurjRel r ys
isBijection :: (Eq a, Eq b) => Rel a b -> [a] -> [b] -> Bool
isBijection r xs ys = isTotalInj r xs && isTotalSurj r xs ys
(!) :: Eq a => Rel a b -> a -> Maybe b
xys ! x = lookup x xys
(.!) :: Rel a b -> a -> (Rel a b, a)
f .! x = (f, x)
(.=) :: (Eq a, Eq b) => (Rel a b, a) -> b -> Rel a b
(f, x) .= y = f <+ singleton x y