{-# OPTIONS_HADDOCK hide #-} -- | Combinators for constructing properties. {-# LANGUAGE CPP #-} #ifndef NO_TYPEABLE {-# LANGUAGE DeriveDataTypeable #-} #endif #ifndef NO_SAFE_HASKELL {-# LANGUAGE Safe #-} #endif module Test.QuickCheck.Property where -------------------------------------------------------------------------- -- imports import Test.QuickCheck.Gen import Test.QuickCheck.Gen.Unsafe import Test.QuickCheck.Arbitrary import Test.QuickCheck.Text( isOneLine, putLine ) import Test.QuickCheck.Exception import Test.QuickCheck.State( State(terminal), Confidence(..) ) #ifndef NO_TIMEOUT import System.Timeout(timeout) #endif import Data.Maybe import Control.Applicative import Control.Monad import qualified Data.Map as Map import Data.Map(Map) import qualified Data.Set as Set import Data.Set(Set) #ifndef NO_DEEPSEQ import Control.DeepSeq #endif #ifndef NO_TYPEABLE import Data.Typeable (Typeable) #endif import Data.Maybe -------------------------------------------------------------------------- -- fixities infixr 0 ==> infixr 1 .&. infixr 1 .&&. infixr 1 .||. -- The story for exception handling: -- -- To avoid insanity, we have rules about which terms can throw -- exceptions when we evaluate them: -- * A rose tree must evaluate to WHNF without throwing an exception -- * The 'ok' component of a Result must evaluate to Just True or -- Just False or Nothing rather than raise an exception -- * IORose _ must never throw an exception when executed -- -- Both rose trees and Results may loop when we evaluate them, though, -- so we have to be careful not to force them unnecessarily. -- -- We also have to be careful when we use fmap or >>= in the Rose -- monad that the function we supply is total, or else use -- protectResults afterwards to install exception handlers. The -- mapResult function on Properties installs an exception handler for -- us, though. -- -- Of course, the user is free to write "error "ha ha" :: Result" if -- they feel like it. We have to make sure that any user-supplied Rose -- Results or Results get wrapped in exception handlers, which we do by: -- * Making the 'property' function install an exception handler -- round its argument. This function always gets called in the -- right places, because all our Property-accepting functions are -- actually polymorphic over the Testable class so they have to -- call 'property'. -- * Installing an exception handler round a Result before we put it -- in a rose tree (the only place Results can end up). -------------------------------------------------------------------------- -- * Property and Testable types -- | The type of properties. newtype Property = MkProperty { unProperty :: Gen Prop } #ifndef NO_TYPEABLE deriving (Typeable) #endif -- | The class of properties, i.e., types which QuickCheck knows how to test. -- Typically a property will be a function returning 'Bool' or 'Property'. -- -- If a property does no quantification, i.e. has no -- parameters and doesn't use 'forAll', it will only be tested once. -- This may not be what you want if your property is an @IO Bool@. -- You can change this behaviour using the 'again' combinator. class Testable prop where -- | Convert the thing to a property. property :: prop -> Property -- | If a property returns 'Discard', the current test case is discarded, -- the same as if a precondition was false. -- -- An example is the definition of '==>': -- -- > (==>) :: Testable prop => Bool -> prop -> Property -- > False ==> _ = property Discard -- > True ==> p = property p data Discard = Discard instance Testable Discard where property _ = property rejected -- This instance is here to make it easier to turn IO () into a Property. instance Testable () where property = property . liftUnit where -- N.B. the unit gets forced only inside 'property', -- so that we turn exceptions into test failures liftUnit () = succeeded instance Testable Bool where property = property . liftBool instance Testable Result where property = MkProperty . return . MkProp . protectResults . return instance Testable Prop where property (MkProp r) = MkProperty . return . MkProp . ioRose . return $ r instance Testable prop => Testable (Gen prop) where property mp = MkProperty $ do p <- mp; unProperty (again p) instance Testable Property where property (MkProperty mp) = MkProperty $ do p <- mp; unProperty (property p) -- | Do I/O inside a property. {-# DEPRECATED morallyDubiousIOProperty "Use 'ioProperty' instead" #-} morallyDubiousIOProperty :: Testable prop => IO prop -> Property morallyDubiousIOProperty = ioProperty -- | Do I/O inside a property. -- -- Warning: any random values generated inside of the argument to @ioProperty@ -- will not currently be shrunk. For best results, generate all random values -- before calling @ioProperty@, or use 'idempotentIOProperty' if that is safe. -- -- Note: if your property does no quantification, it will only be tested once. -- To test it repeatedly, use 'again'. ioProperty :: Testable prop => IO prop -> Property ioProperty prop = idempotentIOProperty (fmap noShrinking prop) -- | Do I/O inside a property. -- -- Warning: during shrinking, the I/O may not always be re-executed. -- Instead, the I/O may be executed once and then its result retained. -- If this is not acceptable, use 'ioProperty' instead. idempotentIOProperty :: Testable prop => IO prop -> Property idempotentIOProperty = MkProperty . fmap (MkProp . ioRose . fmap unProp) . promote . fmap (unProperty . property) instance (Arbitrary a, Show a, Testable prop) => Testable (a -> prop) where property f = forAllShrink arbitrary shrink f -- ** Exception handling protect :: (AnException -> a) -> IO a -> IO a protect f x = either f id `fmap` tryEvaluateIO x -------------------------------------------------------------------------- -- ** Type Prop newtype Prop = MkProp{ unProp :: Rose Result } -- ** type Rose data Rose a = MkRose a [Rose a] | IORose (IO (Rose a)) -- Only use IORose if you know that the argument is not going to throw an exception! -- Otherwise, try ioRose. ioRose :: IO (Rose Result) -> Rose Result ioRose = IORose . protectRose joinRose :: Rose (Rose a) -> Rose a joinRose (IORose rs) = IORose (fmap joinRose rs) joinRose (MkRose (IORose rm) rs) = IORose $ do r <- rm; return (joinRose (MkRose r rs)) joinRose (MkRose (MkRose x ts) tts) = -- first shrinks outer quantification; makes most sense MkRose x (map joinRose tts ++ ts) -- first shrinks inner quantification: terrible --MkRose x (ts ++ map joinRose tts) instance Functor Rose where -- f must be total fmap f (IORose rs) = IORose (fmap (fmap f) rs) fmap f (MkRose x rs) = MkRose (f x) [ fmap f r | r <- rs ] instance Applicative Rose where pure = return -- f must be total (<*>) = liftM2 ($) instance Monad Rose where return x = MkRose x [] -- k must be total m >>= k = joinRose (fmap k m) -- | Execute the "IORose" bits of a rose tree, returning a tree -- constructed by MkRose. reduceRose :: Rose Result -> IO (Rose Result) reduceRose r@(MkRose _ _) = return r reduceRose (IORose m) = m >>= reduceRose -- | Apply a function to the outermost MkRose constructor of a rose tree. -- The function must be total! onRose :: (a -> [Rose a] -> Rose a) -> Rose a -> Rose a onRose f (MkRose x rs) = f x rs onRose f (IORose m) = IORose (fmap (onRose f) m) -- | Wrap a rose tree in an exception handler. protectRose :: IO (Rose Result) -> IO (Rose Result) protectRose = protect (return . exception "Exception") -- | Wrap all the Results in a rose tree in exception handlers. protectResults :: Rose Result -> Rose Result protectResults = onRose $ \x rs -> IORose $ do y <- protectResult (return x) return (MkRose y (map protectResults rs)) -- ** Result type -- | Different kinds of callbacks data Callback = PostTest CallbackKind (State -> Result -> IO ()) -- ^ Called just after a test | PostFinalFailure CallbackKind (State -> Result -> IO ()) -- ^ Called with the final failing test-case data CallbackKind = Counterexample -- ^ Affected by the 'verbose' combinator | NotCounterexample -- ^ Not affected by the 'verbose' combinator -- | The result of a single test. data Result = MkResult { ok :: Maybe Bool -- ^ result of the test case; Nothing = discard , expect :: Bool -- ^ indicates what the expected result of the property is , reason :: String -- ^ a message indicating what went wrong , theException :: Maybe AnException -- ^ the exception thrown, if any , abort :: Bool -- ^ if True, the test should not be repeated , maybeNumTests :: Maybe Int -- ^ stop after this many tests , maybeCheckCoverage :: Maybe Confidence -- ^ required coverage confidence , labels :: [String] -- ^ test case labels , classes :: [String] -- ^ test case classes , tables :: [(String, String)] -- ^ test case tables , requiredCoverage :: [(Maybe String, String, Double)] -- ^ required coverage , callbacks :: [Callback] -- ^ the callbacks for this test case , testCase :: [String] -- ^ the generated test case } exception :: String -> AnException -> Result exception msg err | isDiscard err = rejected | otherwise = failed{ reason = formatException msg err, theException = Just err } formatException :: String -> AnException -> String formatException msg err = msg ++ ":" ++ format (show err) where format xs | isOneLine xs = " '" ++ xs ++ "'" | otherwise = "\n" ++ unlines [ " " ++ l | l <- lines xs ] protectResult :: IO Result -> IO Result protectResult = protect (exception "Exception") succeeded, failed, rejected :: Result (succeeded, failed, rejected) = (result{ ok = Just True }, result{ ok = Just False }, result{ ok = Nothing }) where result = MkResult { ok = undefined , expect = True , reason = "" , theException = Nothing , abort = True , maybeNumTests = Nothing , maybeCheckCoverage = Nothing , labels = [] , classes = [] , tables = [] , requiredCoverage = [] , callbacks = [] , testCase = [] } -------------------------------------------------------------------------- -- ** Lifting and mapping functions liftBool :: Bool -> Result liftBool True = succeeded liftBool False = failed { reason = "Falsifiable" } mapResult :: Testable prop => (Result -> Result) -> prop -> Property mapResult f = mapRoseResult (protectResults . fmap f) mapTotalResult :: Testable prop => (Result -> Result) -> prop -> Property mapTotalResult f = mapRoseResult (fmap f) -- f here mustn't throw an exception (rose tree invariant). mapRoseResult :: Testable prop => (Rose Result -> Rose Result) -> prop -> Property mapRoseResult f = mapProp (\(MkProp t) -> MkProp (f t)) mapProp :: Testable prop => (Prop -> Prop) -> prop -> Property mapProp f = MkProperty . fmap f . unProperty . property -------------------------------------------------------------------------- -- ** Property combinators -- | Adjust the test case size for a property, by transforming it with the given -- function. mapSize :: Testable prop => (Int -> Int) -> prop -> Property mapSize f = property . scale f . unProperty . property -- | Shrinks the argument to a property if it fails. Shrinking is done -- automatically for most types. This function is only needed when you want to -- override the default behavior. shrinking :: Testable prop => (a -> [a]) -- ^ 'shrink'-like function. -> a -- ^ The original argument -> (a -> prop) -> Property shrinking shrinker x0 pf = MkProperty (fmap (MkProp . joinRose . fmap unProp) (promote (props x0))) where props x = MkRose (unProperty (property (pf x))) [ props x' | x' <- shrinker x ] -- | Disables shrinking for a property altogether. -- Only quantification /inside/ the call to 'noShrinking' is affected. noShrinking :: Testable prop => prop -> Property noShrinking = mapRoseResult (onRose (\res _ -> MkRose res [])) -- | Adds a callback callback :: Testable prop => Callback -> prop -> Property callback cb = mapTotalResult (\res -> res{ callbacks = cb : callbacks res }) -- | Adds the given string to the counterexample if the property fails. counterexample :: Testable prop => String -> prop -> Property counterexample s = mapTotalResult (\res -> res{ testCase = s:testCase res }) . callback (PostFinalFailure Counterexample $ \st _res -> do s <- showCounterexample s putLine (terminal st) s) showCounterexample :: String -> IO String showCounterexample s = do let force [] = return () force (x:xs) = x `seq` force xs res <- tryEvaluateIO (force s) return $ case res of Left err -> formatException "Exception thrown while showing test case" err Right () -> s -- | Adds the given string to the counterexample if the property fails. {-# DEPRECATED printTestCase "Use counterexample instead" #-} printTestCase :: Testable prop => String -> prop -> Property printTestCase = counterexample -- | Performs an 'IO' action after the last failure of a property. whenFail :: Testable prop => IO () -> prop -> Property whenFail m = callback $ PostFinalFailure NotCounterexample $ \_st _res -> m -- | Performs an 'IO' action every time a property fails. Thus, -- if shrinking is done, this can be used to keep track of the -- failures along the way. whenFail' :: Testable prop => IO () -> prop -> Property whenFail' m = callback $ PostTest NotCounterexample $ \_st res -> if ok res == Just False then m else return () -- | Prints out the generated testcase every time the property is tested. -- Only variables quantified over /inside/ the 'verbose' are printed. verbose :: Testable prop => prop -> Property verbose = mapResult (\res -> res { callbacks = newCallback (callbacks res):callbacks res }) where newCallback cbs = PostTest Counterexample $ \st res -> do putLine (terminal st) (status res ++ ":") sequence_ [ f st res | PostFinalFailure Counterexample f <- cbs ] putLine (terminal st) "" status MkResult{ok = Just True} = "Passed" status MkResult{ok = Just False} = "Failed" status MkResult{ok = Nothing} = "Skipped (precondition false)" -- | Prints out the generated testcase every time the property fails, including during shrinking. -- Only variables quantified over /inside/ the 'verboseShrinking' are printed. verboseShrinking :: Testable prop => prop -> Property verboseShrinking = mapResult (\res -> res { callbacks = newCallback (callbacks res):callbacks res }) where newCallback cbs = PostTest Counterexample $ \st res -> when (ok res == Just False) $ do putLine (terminal st) "Failed:" sequence_ [ f st res | PostFinalFailure Counterexample f <- cbs ] putLine (terminal st) "" -- | Indicates that a property is supposed to fail. -- QuickCheck will report an error if it does not fail. expectFailure :: Testable prop => prop -> Property expectFailure = mapTotalResult (\res -> res{ expect = False }) -- | Modifies a property so that it only will be tested once. -- Opposite of 'again'. once :: Testable prop => prop -> Property once = mapTotalResult (\res -> res{ abort = True }) -- | Modifies a property so that it will be tested repeatedly. -- Opposite of 'once'. again :: Testable prop => prop -> Property again = mapTotalResult (\res -> res{ abort = False }) -- | Configures how many times a property will be tested. -- -- For example, -- -- > quickCheck (withMaxSuccess 1000 p) -- -- will test @p@ up to 1000 times. withMaxSuccess :: Testable prop => Int -> prop -> Property withMaxSuccess n = n `seq` mapTotalResult (\res -> res{ maybeNumTests = Just n }) -- | Check that all coverage requirements defined by 'cover' and 'coverTable' -- are met, using a statistically sound test, and fail if they are not met. -- -- Ordinarily, a failed coverage check does not cause the property to fail. -- This is because the coverage requirement is not tested in a statistically -- sound way. If you use 'cover' to express that a certain value must appear 20% -- of the time, QuickCheck will warn you if the value only appears in 19 out of -- 100 test cases - but since the coverage varies randomly, you may have just -- been unlucky, and there may not be any real problem with your test -- generation. -- -- When you use 'checkCoverage', QuickCheck uses a statistical test to account -- for the role of luck in coverage failures. It will run as many tests as -- needed until it is sure about whether the coverage requirements are met. If a -- coverage requirement is not met, the property fails. -- -- Example: -- -- > quickCheck (checkCoverage prop_foo) checkCoverage :: Testable prop => prop -> Property checkCoverage = checkCoverageWith stdConfidence -- | Check coverage requirements using a custom confidence level. -- See 'stdConfidence'. -- -- An example of making the statistical test less stringent in order to improve -- performance: -- -- > quickCheck (checkCoverageWith stdConfidence{certainty = 10^6} prop_foo) checkCoverageWith :: Testable prop => Confidence -> prop -> Property checkCoverageWith confidence = certainty confidence `seq` tolerance confidence `seq` mapTotalResult (\res -> res{ maybeCheckCoverage = Just confidence }) -- | The standard parameters used by 'checkCoverage': @certainty = 10^9@, -- @tolerance = 0.9@. See 'Confidence' for the meaning of the parameters. stdConfidence :: Confidence stdConfidence = Confidence { certainty = 10^9, tolerance = 0.9 } -- | Attaches a label to a test case. This is used for reporting -- test case distribution. -- -- For example: -- -- > prop_reverse_reverse :: [Int] -> Property -- > prop_reverse_reverse xs = -- > label ("length of input is " ++ show (length xs)) $ -- > reverse (reverse xs) === xs -- -- >>> quickCheck prop_reverse_reverse -- +++ OK, passed 100 tests: -- 7% length of input is 7 -- 6% length of input is 3 -- 5% length of input is 4 -- 4% length of input is 6 -- ... -- -- Each use of 'label' in your property results in a separate -- table of test case distribution in the output. If this is -- not what you want, use 'tabulate'. label :: Testable prop => String -> prop -> Property label s = s `deepseq` mapTotalResult $ \res -> res { labels = s:labels res } -- | Attaches a label to a test case. This is used for reporting -- test case distribution. -- -- > collect x = label (show x) -- -- For example: -- -- > prop_reverse_reverse :: [Int] -> Property -- > prop_reverse_reverse xs = -- > collect (length xs) $ -- > reverse (reverse xs) === xs -- -- >>> quickCheck prop_reverse_reverse -- +++ OK, passed 100 tests: -- 7% 7 -- 6% 3 -- 5% 4 -- 4% 6 -- ... -- -- Each use of 'collect' in your property results in a separate -- table of test case distribution in the output. If this is -- not what you want, use 'tabulate'. collect :: (Show a, Testable prop) => a -> prop -> Property collect x = label (show x) -- | Reports how many test cases satisfy a given condition. -- -- For example: -- -- > prop_sorted_sort :: [Int] -> Property -- > prop_sorted_sort xs = -- > sorted xs ==> -- > classify (length xs > 1) "non-trivial" $ -- > sort xs === xs -- -- >>> quickCheck prop_sorted_sort -- +++ OK, passed 100 tests (22% non-trivial). classify :: Testable prop => Bool -- ^ @True@ if the test case should be labelled. -> String -- ^ Label. -> prop -> Property classify False _ = property classify True s = s `deepseq` mapTotalResult $ \res -> res { classes = s:classes res } -- | Checks that at least the given proportion of /successful/ test -- cases belong to the given class. Discarded tests (i.e. ones -- with a false precondition) do not affect coverage. -- -- __Note:__ If the coverage check fails, QuickCheck prints out a warning, but -- the property does /not/ fail. To make the property fail, use 'checkCoverage'. -- -- For example: -- -- > prop_sorted_sort :: [Int] -> Property -- > prop_sorted_sort xs = -- > sorted xs ==> -- > cover 50 (length xs > 1) "non-trivial" $ -- > sort xs === xs -- -- >>> quickCheck prop_sorted_sort -- +++ OK, passed 100 tests; 135 discarded (26% non-trivial). -- <BLANKLINE> -- Only 26% non-trivial, but expected 50% cover :: Testable prop => Double -- ^ The required percentage (0-100) of test cases. -> Bool -- ^ @True@ if the test case belongs to the class. -> String -- ^ Label for the test case class. -> prop -> Property cover p x s = mapTotalResult f . classify x s where f res = res { requiredCoverage = (Nothing, s, p/100):requiredCoverage res } -- | Collects information about test case distribution into a table. -- The arguments to 'tabulate' are the table's name and a list of values -- associated with the current test case. After testing, QuickCheck prints the -- frequency of all collected values. The frequencies are expressed as a -- percentage of the total number of values collected. -- -- You should prefer 'tabulate' to 'label' when each test case is associated -- with a varying number of values. Here is a (not terribly useful) example, -- where the test data is a list of integers and we record all values that -- occur in the list: -- -- > prop_sorted_sort :: [Int] -> Property -- > prop_sorted_sort xs = -- > sorted xs ==> -- > tabulate "List elements" (map show xs) $ -- > sort xs === xs -- -- >>> quickCheck prop_sorted_sort -- +++ OK, passed 100 tests; 1684 discarded. -- <BLANKLINE> -- List elements (109 in total): -- 3.7% 0 -- 3.7% 17 -- 3.7% 2 -- 3.7% 6 -- 2.8% -6 -- 2.8% -7 -- -- Here is a more useful example. We are testing a chatroom, where the user can -- log in, log out, or send a message: -- -- > data Command = LogIn | LogOut | SendMessage String deriving (Data, Show) -- > instance Arbitrary Command where ... -- -- There are some restrictions on command sequences; for example, the user must -- log in before doing anything else. The function @valid :: [Command] -> Bool@ -- checks that a command sequence is allowed. Our property then has the form: -- -- > prop_chatroom :: [Command] -> Property -- > prop_chatroom cmds = -- > valid cmds ==> -- > ... -- -- The use of '==>' may skew test case distribution. We use 'collect' to see the -- length of the command sequences, and 'tabulate' to get the frequencies of the -- individual commands: -- -- > prop_chatroom :: [Command] -> Property -- > prop_chatroom cmds = -- > wellFormed cmds LoggedOut ==> -- > 'collect' (length cmds) $ -- > 'tabulate' "Commands" (map (show . 'Data.Data.toConstr') cmds) $ -- > ... -- -- >>> quickCheckWith stdArgs{maxDiscardRatio = 1000} prop_chatroom -- +++ OK, passed 100 tests; 2775 discarded: -- 60% 0 -- 20% 1 -- 15% 2 -- 3% 3 -- 1% 4 -- 1% 5 -- <BLANKLINE> -- Commands (68 in total): -- 62% LogIn -- 22% SendMessage -- 16% LogOut tabulate :: Testable prop => String -> [String] -> prop -> Property tabulate key values = key `deepseq` values `deepseq` mapTotalResult $ \res -> res { tables = [(key, value) | value <- values] ++ tables res } -- | Checks that the values in a given 'table' appear a certain proportion of -- the time. A call to 'coverTable' @table@ @[(x1, p1), ..., (xn, pn)]@ asserts -- that of the values in @table@, @x1@ should appear at least @p1@ percent of -- the time, @x2@ at least @p2@ percent of the time, and so on. -- -- __Note:__ If the coverage check fails, QuickCheck prints out a warning, but -- the property does /not/ fail. To make the property fail, use 'checkCoverage'. -- -- Continuing the example from the 'tabular' combinator... -- -- > data Command = LogIn | LogOut | SendMessage String deriving (Data, Show) -- > prop_chatroom :: [Command] -> Property -- > prop_chatroom cmds = -- > wellFormed cmds LoggedOut ==> -- > 'tabulate' "Commands" (map (show . 'Data.Data.toConstr') cmds) $ -- > ... -- -- ...we can add a coverage requirement as follows, which checks that @LogIn@, -- @LogOut@ and @SendMessage@ each occur at least 25% of the time: -- -- > prop_chatroom :: [Command] -> Property -- > prop_chatroom cmds = -- > wellFormed cmds LoggedOut ==> -- > coverTable "Commands" [("LogIn", 25), ("LogOut", 25), ("SendMessage", 25)] $ -- > 'tabulate' "Commands" (map (show . 'Data.Data.toConstr') cmds) $ -- > ... property goes here ... -- -- >>> quickCheck prop_chatroom -- +++ OK, passed 100 tests; 2909 discarded: -- 56% 0 -- 17% 1 -- 10% 2 -- 6% 3 -- 5% 4 -- 3% 5 -- 3% 7 -- <BLANKLINE> -- Commands (111 in total): -- 51.4% LogIn -- 30.6% SendMessage -- 18.0% LogOut -- <BLANKLINE> -- Table 'Commands' had only 18.0% LogOut, but expected 25.0% coverTable :: Testable prop => String -> [(String, Double)] -> prop -> Property coverTable table xs = tables `deepseq` xs `deepseq` mapTotalResult $ \res -> res { requiredCoverage = ys ++ requiredCoverage res } where ys = [(Just table, x, p/100) | (x, p) <- xs] -- | Implication for properties: The resulting property holds if -- the first argument is 'False' (in which case the test case is discarded), -- or if the given property holds. Note that using implication carelessly can -- severely skew test case distribution: consider using 'cover' to make sure -- that your test data is still good quality. (==>) :: Testable prop => Bool -> prop -> Property False ==> _ = property Discard True ==> p = property p -- | Considers a property failed if it does not complete within -- the given number of microseconds. within :: Testable prop => Int -> prop -> Property within n = mapRoseResult f where f rose = ioRose $ do let m `orError` x = fmap (fromMaybe x) m MkRose res roses <- timeout n (reduceRose rose) `orError` return timeoutResult res' <- timeout n (protectResult (return res)) `orError` timeoutResult return (MkRose res' (map f roses)) timeoutResult = failed { reason = "Timeout" } #ifdef NO_TIMEOUT timeout _ = fmap Just #endif -- | Explicit universal quantification: uses an explicitly given -- test case generator. forAll :: (Show a, Testable prop) => Gen a -> (a -> prop) -> Property forAll gen pf = forAllShrink gen (\_ -> []) pf -- | Like 'forAll', but with an explicitly given show function. forAllShow :: Testable prop => Gen a -> (a -> String) -> (a -> prop) -> Property forAllShow gen shower pf = forAllShrinkShow gen (\_ -> []) shower pf -- | Like 'forAll', but without printing the generated value. forAllBlind :: Testable prop => Gen a -> (a -> prop) -> Property forAllBlind gen pf = forAllShrinkBlind gen (\_ -> []) pf -- | Like 'forAll', but tries to shrink the argument for failing test cases. forAllShrink :: (Show a, Testable prop) => Gen a -> (a -> [a]) -> (a -> prop) -> Property forAllShrink gen shrinker = forAllShrinkShow gen shrinker show -- | Like 'forAllShrink', but with an explicitly given show function. forAllShrinkShow :: Testable prop => Gen a -> (a -> [a]) -> (a -> String) -> (a -> prop) -> Property forAllShrinkShow gen shrinker shower pf = forAllShrinkBlind gen shrinker (\x -> counterexample (shower x) (pf x)) -- | Like 'forAllShrink', but without printing the generated value. forAllShrinkBlind :: Testable prop => Gen a -> (a -> [a]) -> (a -> prop) -> Property forAllShrinkBlind gen shrinker pf = again $ MkProperty $ gen >>= \x -> unProperty $ shrinking shrinker x pf -- | Nondeterministic choice: 'p1' '.&.' 'p2' picks randomly one of -- 'p1' and 'p2' to test. If you test the property 100 times it -- makes 100 random choices. (.&.) :: (Testable prop1, Testable prop2) => prop1 -> prop2 -> Property p1 .&. p2 = again $ MkProperty $ arbitrary >>= \b -> unProperty $ counterexample (if b then "LHS" else "RHS") $ if b then property p1 else property p2 -- | Conjunction: 'p1' '.&&.' 'p2' passes if both 'p1' and 'p2' pass. (.&&.) :: (Testable prop1, Testable prop2) => prop1 -> prop2 -> Property p1 .&&. p2 = conjoin [property p1, property p2] -- | Take the conjunction of several properties. conjoin :: Testable prop => [prop] -> Property conjoin ps = again $ MkProperty $ do roses <- mapM (fmap unProp . unProperty . property) ps return (MkProp (conj id roses)) where conj k [] = MkRose (k succeeded) [] conj k (p : ps) = IORose $ do rose@(MkRose result _) <- reduceRose p case ok result of _ | not (expect result) -> return (return failed { reason = "expectFailure may not occur inside a conjunction" }) Just True -> return (conj (addLabels result . addCallbacksAndCoverage result . k) ps) Just False -> return rose Nothing -> do rose2@(MkRose result2 _) <- reduceRose (conj (addCallbacksAndCoverage result . k) ps) return $ -- Nasty work to make sure we use the right callbacks case ok result2 of Just True -> MkRose (result2 { ok = Nothing }) [] Just False -> rose2 Nothing -> rose2 addCallbacksAndCoverage result r = r { callbacks = callbacks result ++ callbacks r, requiredCoverage = requiredCoverage result ++ requiredCoverage r } addLabels result r = r { labels = labels result ++ labels r, classes = classes result ++ classes r, tables = tables result ++ tables r } -- | Disjunction: 'p1' '.||.' 'p2' passes unless 'p1' and 'p2' simultaneously fail. (.||.) :: (Testable prop1, Testable prop2) => prop1 -> prop2 -> Property p1 .||. p2 = disjoin [property p1, property p2] -- | Take the disjunction of several properties. disjoin :: Testable prop => [prop] -> Property disjoin ps = again $ MkProperty $ do roses <- mapM (fmap unProp . unProperty . property) ps return (MkProp (foldr disj (MkRose failed []) roses)) where disj :: Rose Result -> Rose Result -> Rose Result disj p q = do result1 <- p case ok result1 of _ | not (expect result1) -> return expectFailureError Just False -> do result2 <- q return $ case ok result2 of _ | not (expect result2) -> expectFailureError Just True -> addCoverage result1 result2 Just False -> MkResult { ok = Just False, expect = True, reason = sep (reason result1) (reason result2), theException = theException result1 `mplus` theException result2, -- The following few fields are not important because the -- test case has failed anyway abort = False, maybeNumTests = Nothing, maybeCheckCoverage = Nothing, labels = [], classes = [], tables = [], requiredCoverage = [], callbacks = callbacks result1 ++ [PostFinalFailure Counterexample $ \st _res -> putLine (terminal st) ""] ++ callbacks result2, testCase = testCase result1 ++ testCase result2 } Nothing -> result2 -- The "obvious" semantics of .||. has: -- discard .||. true = true -- discard .||. discard = discard -- but this implementation gives discard .||. true = discard. -- This is reasonable because evaluating result2 in the case -- that result1 discards is just busy-work - it won't ever -- cause the property to fail. On the other hand, discarding -- instead of returning true causes us to execute one more -- test case - but assuming that preconditions are cheap to -- evaluate, this is no more work than evaluating result2 -- would be, while (unlike evaluating result2) it might catch -- a bug. _ -> return result1 expectFailureError = failed { reason = "expectFailure may not occur inside a disjunction" } sep [] s = s sep s [] = s sep s s' = s ++ ", " ++ s' addCoverage result r = r { requiredCoverage = requiredCoverage result ++ requiredCoverage r } -- | Like '==', but prints a counterexample when it fails. infix 4 === (===) :: (Eq a, Show a) => a -> a -> Property x === y = counterexample (show x ++ interpret res ++ show y) res where res = x == y interpret True = " == " interpret False = " /= " -- | Like '/=', but prints a counterexample when it fails. infix 4 =/= (=/=) :: (Eq a, Show a) => a -> a -> Property x =/= y = counterexample (show x ++ interpret res ++ show y) res where res = x /= y interpret True = " /= " interpret False = " == " #ifndef NO_DEEPSEQ -- | Checks that a value is total, i.e., doesn't crash when evaluated. total :: NFData a => a -> Property total x = property (rnf x) #endif -------------------------------------------------------------------------- -- the end.