{-# LANGUAGE ExistentialQuantification #-} {-# LANGUAGE StandaloneDeriving #-} ----------------------------------------------------------------------------- -- | -- Module : Test.StateMachine.Logic -- Copyright : (C) 2017, ATS Advanced Telematic Systems GmbH -- License : BSD-style (see the file LICENSE) -- -- Maintainer : Stevan Andjelkovic -- Stability : provisional -- Portability : non-portable (GHC extensions) -- -- This module defines a predicate logic-like language and its counterexample -- semantics. -- ----------------------------------------------------------------------------- module Test.StateMachine.Logic ( Logic(..) , Predicate(..) , dual , strongNeg , Counterexample(..) , Value(..) , boolean , logic , predicate , (.==) , (./=) , (.<) , (.<=) , (.>) , (.>=) , elem , notElem , (.//) , (.&&) , (.||) , (.=>) , forall , exists ) where import Prelude hiding (elem, notElem) import qualified Prelude ------------------------------------------------------------------------ data Logic = Bot | Top | Logic :&& Logic | Logic :|| Logic | Logic :=> Logic | Not Logic | Predicate Predicate | forall a. Show a => Forall [a] (a -> Logic) | forall a. Show a => Exists [a] (a -> Logic) | Boolean Bool | Annotate String Logic data Predicate = forall a. (Eq a, Show a) => a :== a | forall a. (Eq a, Show a) => a :/= a | forall a. (Ord a, Show a) => a :< a | forall a. (Ord a, Show a) => a :<= a | forall a. (Ord a, Show a) => a :> a | forall a. (Ord a, Show a) => a :>= a | forall a. (Eq a, Show a) => Elem a [a] | forall a. (Eq a, Show a) => NotElem a [a] deriving instance Show Predicate dual :: Predicate -> Predicate dual p = case p of x :== y -> x :/= y x :/= y -> x :== y x :< y -> x :>= y x :<= y -> x :> y x :> y -> x :<= y x :>= y -> x :< y x `Elem` xs -> x `NotElem` xs x `NotElem` xs -> x `Elem` xs -- See Yuri Gurevich's "Intuitionistic logic with strong negation" (1977). strongNeg :: Logic -> Logic strongNeg l0 = case l0 of Bot -> Top Top -> Bot l :&& r -> strongNeg l :|| strongNeg r l :|| r -> strongNeg l :&& strongNeg r l :=> r -> l :&& strongNeg r Not l -> l Predicate p -> Predicate (dual p) Forall xs p -> Exists xs (strongNeg . p) Exists xs p -> Forall xs (strongNeg . p) Boolean b -> Boolean (not b) Annotate s l -> Annotate s (strongNeg l) data Counterexample = BotC | Fst Counterexample | Snd Counterexample | EitherC Counterexample Counterexample | ImpliesC Counterexample | NotC Counterexample | PredicateC Predicate | forall a. Show a => ForallC a Counterexample | forall a. Show a => ExistsC [a] [Counterexample] | BooleanC | AnnotateC String Counterexample deriving instance Show Counterexample data Value = VFalse Counterexample | VTrue deriving Show boolean :: Logic -> Bool boolean l = case logic l of VFalse _ -> False VTrue -> True logic :: Logic -> Value logic Bot = VFalse BotC logic Top = VTrue logic (l :&& r) = case logic l of VFalse ce -> VFalse (Fst ce) VTrue -> case logic r of VFalse ce' -> VFalse (Snd ce') VTrue -> VTrue logic (l :|| r) = case logic l of VTrue -> VTrue VFalse ce -> case logic r of VTrue -> VTrue VFalse ce' -> VFalse (EitherC ce ce') logic (l :=> r) = case logic l of VFalse _ -> VTrue VTrue -> case logic r of VTrue -> VTrue VFalse ce -> VFalse (ImpliesC ce) logic (Not l) = case logic (strongNeg l) of VTrue -> VTrue VFalse ce -> VFalse (NotC ce) logic (Predicate p) = predicate p logic (Forall xs0 p) = go xs0 where go [] = VTrue go (x : xs) = case logic (p x) of VTrue -> go xs VFalse ce -> VFalse (ForallC x ce) logic (Exists xs0 p) = go xs0 [] where go [] ces = VFalse (ExistsC xs0 (reverse ces)) go (x : xs) ces = case logic (p x) of VTrue -> VTrue VFalse ce -> go xs (ce : ces) logic (Boolean b) = if b then VTrue else VFalse BooleanC logic (Annotate s l) = case logic l of VTrue -> VTrue VFalse ce -> VFalse (AnnotateC s ce) predicate :: Predicate -> Value predicate p0 = let b = go p0 in case p0 of x :== y -> b (x == y) x :/= y -> b (x /= y) x :< y -> b (x < y) x :<= y -> b (x <= y) x :> y -> b (x > y) x :>= y -> b (x >= y) x `Elem` xs -> b (x `Prelude.elem` xs) x `NotElem` xs -> b (x `Prelude.notElem` xs) where go :: Predicate -> Bool -> Value go _ True = VTrue go p False = VFalse (PredicateC (dual p)) ------------------------------------------------------------------------ infix 5 .== infix 5 ./= infix 5 .< infix 5 .<= infix 5 .> infix 5 .>= infix 8 `elem` infix 8 `notElem` infixl 4 .// infixr 3 .&& infixr 2 .|| infixr 1 .=> (.==) :: (Eq a, Show a) => a -> a -> Logic x .== y = Predicate (x :== y) (./=) :: (Eq a, Show a) => a -> a -> Logic x ./= y = Predicate (x :/= y) (.<) :: (Ord a, Show a) => a -> a -> Logic x .< y = Predicate (x :< y) (.<=) :: (Ord a, Show a) => a -> a -> Logic x .<= y = Predicate (x :<= y) (.>) :: (Ord a, Show a) => a -> a -> Logic x .> y = Predicate (x :> y) (.>=) :: (Ord a, Show a) => a -> a -> Logic x .>= y = Predicate (x :>= y) elem :: (Eq a, Show a) => a -> [a] -> Logic elem x xs = Predicate (Elem x xs) notElem :: (Eq a, Show a) => a -> [a] -> Logic notElem x xs = Predicate (NotElem x xs) (.//) :: Logic -> String -> Logic l .// s = Annotate s l (.&&) :: Logic -> Logic -> Logic (.&&) = (:&&) (.||) :: Logic -> Logic -> Logic (.||) = (:||) (.=>) :: Logic -> Logic -> Logic (.=>) = (:=>) forall :: Show a => [a] -> (a -> Logic) -> Logic forall = Forall exists :: Show a => [a] -> (a -> Logic) -> Logic exists = Exists