{-# LANGUAGE DataKinds #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE TypeApplications #-} -- The following warning is disabled due to a necessary instance of SatResult -- defined in this module. {-# OPTIONS_GHC -fno-warn-orphans #-} -- | Test copilot-theorem:Copilot.Theorem.What4. module Test.Copilot.Theorem.What4 where -- External imports import Control.Exception (Exception, try) import Data.Int (Int8) import Data.Proxy (Proxy (..)) import Data.Typeable (typeRep) import Data.Word (Word32) import Test.Framework (Test, testGroup) import Test.Framework.Providers.QuickCheck2 (testProperty) import Test.HUnit (Assertion, assertBool, assertFailure) import Test.QuickCheck (Arbitrary (arbitrary), Property, arbitrary, forAll) import Test.QuickCheck.Monadic (monadicIO, run) -- External imports: Copilot import Copilot.Core.Expr (Expr (Const, Drop, Op1, Op2), Id) import Copilot.Core.Operators (Op1 (..), Op2 (..)) import Copilot.Core.Spec (Spec (..), Stream (..)) import qualified Copilot.Core.Spec as Copilot import Copilot.Core.Type (Field (..), Struct (toValues, typeName), Type (Struct), Typed (typeOf), Value (..)) -- Internal imports: Modules being tested import Copilot.Theorem.What4 (CounterExample (..), ProveException (..), SatResult (..), SatResultCex (..), Solver (..), prove, proveWithCounterExample) -- * Constants -- | Unit tests for copilot-theorem:Copilot.Theorem.What4. tests :: Test.Framework.Test tests = testGroup "Copilot.Theorem.What4" [ testProperty "Prove via Z3 that true is valid" testProveZ3True , testProperty "Prove via Z3 that false is invalid" testProveZ3False , testProperty "Prove via Z3 that x == x is valid" testProveZ3EqConst , testProperty "Prove via Z3 that a struct update is valid" testProveZ3StructUpdate , testProperty "Counterexample with invalid base case" testCounterExampleBaseCase , testProperty "Counterexample with invalid induction step" testCounterExampleInductionStep , testProperty "Check that the What4 backend rejects existential quantification" testWhat4ExistsException ] -- * Individual tests -- | Test that Z3 is able to prove the following expression valid: -- @ -- constant True -- @ testProveZ3True :: Property testProveZ3True = monadicIO $ run $ checkResult Z3 propName spec Valid where propName :: String propName = "prop" spec :: Spec spec = forallPropSpec propName [] $ Const typeOf True -- | Test that Z3 is able to prove the following expression invalid: -- @ -- constant False -- @ testProveZ3False :: Property testProveZ3False = monadicIO $ run $ checkResult Z3 propName spec Invalid where propName :: String propName = "prop" spec :: Spec spec = forallPropSpec propName [] $ Const typeOf False -- | Test that Z3 is able to prove the following expresion valid: -- @ -- for all (x :: Int8), constant x == constant x -- @ testProveZ3EqConst :: Property testProveZ3EqConst = forAll arbitrary $ \x -> monadicIO $ run $ checkResult Z3 propName (spec x) Valid where propName :: String propName = "prop" spec :: Int8 -> Spec spec x = forallPropSpec propName [] $ Op2 (Eq typeOf) (Const typeOf x) (Const typeOf x) -- | Test that Z3 is able to prove the following expresion valid: -- @ -- for all (s :: MyStruct), -- ((s ## testField =$ (+1)) # testField) == ((s # testField) + 1) -- @ testProveZ3StructUpdate :: Property testProveZ3StructUpdate = forAll arbitrary $ \x -> monadicIO $ run $ checkResult Z3 propName (spec x) Valid where propName :: String propName = "prop" spec :: TestStruct -> Spec spec s = forallPropSpec propName [] $ Op2 (Eq typeOf) (getField (Op2 (UpdateField typeOf typeOf testField) sExpr (add1 (getField sExpr)))) (add1 (getField sExpr)) where sExpr :: Expr TestStruct sExpr = Const typeOf s getField :: Expr TestStruct -> Expr Word32 getField = Op1 (GetField typeOf typeOf testField) add1 :: Expr Word32 -> Expr Word32 add1 x = Op2 (Add typeOf) x (Const typeOf 1) -- | Test that Z3 is able to produce a counterexample to the following property, -- where the base case is proved invalid: -- -- @ -- let s :: Stream Bool -- s = [False] ++ constant True -- in forAll s -- @ testCounterExampleBaseCase :: Property testCounterExampleBaseCase = monadicIO $ run $ checkCounterExample Z3 propName spec $ \cex -> pure $ not $ and $ baseCases cex where propName :: String propName = "prop" -- s = [False] ++ constant True s :: Stream s = Stream { streamId = sId , streamBuffer = [False] , streamExpr = Const typeOf True , streamExprType = typeOf } sId :: Id sId = 0 spec :: Spec spec = forallPropSpec propName [s] $ Drop typeOf 0 sId -- | Test that Z3 is able to produce a counterexample to the following property, -- where the induction step is proved invalid: -- -- @ -- let s :: Stream Bool -- s = [True] ++ constant False -- in forAll s -- @ testCounterExampleInductionStep :: Property testCounterExampleInductionStep = monadicIO $ run $ checkCounterExample Z3 propName spec $ \cex -> pure $ not $ inductionStep cex where propName :: String propName = "prop" -- s = [True] ++ constant False s :: Stream s = Stream { streamId = sId , streamBuffer = [True] , streamExpr = Const typeOf False , streamExprType = typeOf } sId :: Id sId = 0 spec :: Spec spec = forallPropSpec propName [s] $ Drop typeOf 0 sId -- | Test that @copilot-theorem@'s @what4@ backend will throw an exception if it -- attempts to prove an existentially quantified proposition. testWhat4ExistsException :: Property testWhat4ExistsException = monadicIO $ run $ checkException (prove Z3 spec) isUnexpectedExistentialProposition where isUnexpectedExistentialProposition :: ProveException -> Bool isUnexpectedExistentialProposition UnexpectedExistentialProposition = True propName :: String propName = "prop" spec :: Spec spec = existsPropSpec propName [] $ Const typeOf True -- | A simple data type with a 'Struct' instance and a 'Field'. This is only -- used as part of 'testProveZ3StructUpdate'. newtype TestStruct = TestStruct { testField :: Field "testField" Word32 } instance Arbitrary TestStruct where arbitrary = do w32 <- arbitrary return (TestStruct (Field w32)) instance Struct TestStruct where typeName _ = "testStruct" toValues s = [Value typeOf (testField s)] instance Typed TestStruct where typeOf = Struct (TestStruct (Field 0)) -- | Check that the solver's satisfiability result for the given property in -- the given spec matches the expectation. checkResult :: Solver -> String -> Spec -> SatResult -> IO Bool checkResult solver propName spec expectation = do results <- prove solver spec -- Find the satisfiability result for propName. let propResult = lookup propName results -- The following check also works for the case in which the property name -- does not exist in the results, in which case the lookup returns 'Nothing'. return $ propResult == Just expectation -- | Check that the solver produces an invalid result for the given property and -- that the resulting 'CounterExample' satifies the given predicate. checkCounterExample :: Solver -> String -> Spec -> (CounterExample -> IO Bool) -> IO Bool checkCounterExample solver propName spec cexPred = do results <- proveWithCounterExample solver spec -- Find the satisfiability result for propName. If the property name does not -- exist in the results, raise an assertion failure. propResult <- case lookup propName results of Just propResult -> pure propResult Nothing -> assertFailure $ "Could not find property in results: " ++ propName -- Assert that the solver returned an invalid result and pass the -- counterexample to the predicate. If the result is anything other than -- invalid, raise an assertion failure. case propResult of InvalidCex cex -> cexPred cex ValidCex {} -> assertFailure "Expected invalid result, but result was valid" UnknownCex {} -> assertFailure "Expected invalid result, but result was unknown" -- | Check that the given 'IO' action throws a particular exception. This is -- largely taken from the implementation of @shouldThrow@ in -- @hspec-expectations@ (note that this test suite uses @test-framework@ instead -- of @hspec@). checkException :: forall e a. Exception e => IO a -> (e -> Bool) -> Assertion checkException action p = do r <- try action case r of Right _ -> assertFailure $ "did not get expected exception: " ++ exceptionType Left e -> assertBool ("predicate failed on expected exception: " ++ exceptionType ++ "\n" ++ show e) (p e) where -- String representation of the expected exception's type exceptionType = show $ typeRep $ Proxy @e -- * Auxiliary -- | Build a 'Spec' that contains one property with the given name, which -- contains the given streams, and is defined by the given boolean expression, -- which is universally quantified. forallPropSpec :: String -> [Stream] -> Expr Bool -> Spec forallPropSpec propName propStreams propExpr = Spec propStreams [] [] [Copilot.Property propName (Copilot.Forall propExpr)] -- | Build a 'Spec' that contains one property with the given name, which -- contains the given streams, and is defined by the given boolean expression, -- which is existentially quantified. existsPropSpec :: String -> [Stream] -> Expr Bool -> Spec existsPropSpec propName propStreams propExpr = Spec propStreams [] [] [Copilot.Property propName (Copilot.Exists propExpr)] -- | Equality for 'SatResult'. -- -- This is an orphan instance, so we suppress the warning that GHC would -- normally produce with a GHC option at the top. instance Eq SatResult where Valid == Valid = True Invalid == Invalid = True Unknown == Unknown = True _ == _ = False