{-# LANGUAGE CPP, GeneralizedNewtypeDeriving #-} -- | Tests for the 'Data.HashMap.Lazy' module. We test functions by -- comparing them to a simpler model, an association list. module Main (main) where import Control.Monad ( guard ) import qualified Data.Foldable as Foldable import Data.Function (on) import Data.Hashable (Hashable(hashWithSalt)) import qualified Data.List as L import Data.Ord (comparing) #if defined(STRICT) import qualified Data.HashMap.Strict as HM #else import qualified Data.HashMap.Lazy as HM #endif import qualified Data.Map as M import Test.QuickCheck (Arbitrary, Property, (==>), (===)) import Test.Framework (Test, defaultMain, testGroup) import Test.Framework.Providers.QuickCheck2 (testProperty) -- Key type that generates more hash collisions. newtype Key = K { unK :: Int } deriving (Arbitrary, Eq, Ord, Read, Show) instance Hashable Key where hashWithSalt salt k = hashWithSalt salt (unK k) `mod` 20 ------------------------------------------------------------------------ -- * Properties ------------------------------------------------------------------------ -- ** Instances pEq :: [(Key, Int)] -> [(Key, Int)] -> Bool pEq xs = (M.fromList xs ==) `eq` (HM.fromList xs ==) pNeq :: [(Key, Int)] -> [(Key, Int)] -> Bool pNeq xs = (M.fromList xs /=) `eq` (HM.fromList xs /=) -- We cannot compare to `Data.Map` as ordering is different. pOrd1 :: [(Key, Int)] -> Bool pOrd1 xs = compare x x == EQ where x = HM.fromList xs pOrd2 :: [(Key, Int)] -> [(Key, Int)] -> [(Key, Int)] -> Bool pOrd2 xs ys zs = case (compare x y, compare y z) of (EQ, o) -> compare x z == o (o, EQ) -> compare x z == o (LT, LT) -> compare x z == LT (GT, GT) -> compare x z == GT (LT, GT) -> True -- ys greater than xs and zs. (GT, LT) -> True where x = HM.fromList xs y = HM.fromList ys z = HM.fromList zs pOrd3 :: [(Key, Int)] -> [(Key, Int)] -> Bool pOrd3 xs ys = case (compare x y, compare y x) of (EQ, EQ) -> True (LT, GT) -> True (GT, LT) -> True _ -> False where x = HM.fromList xs y = HM.fromList ys pOrdEq :: [(Key, Int)] -> [(Key, Int)] -> Bool pOrdEq xs ys = case (compare x y, x == y) of (EQ, True) -> True (LT, False) -> True (GT, False) -> True _ -> False where x = HM.fromList xs y = HM.fromList ys pReadShow :: [(Key, Int)] -> Bool pReadShow xs = M.fromList xs == read (show (M.fromList xs)) pFunctor :: [(Key, Int)] -> Bool pFunctor = fmap (+ 1) `eq_` fmap (+ 1) pFoldable :: [(Int, Int)] -> Bool pFoldable = (L.sort . Foldable.foldr (:) []) `eq` (L.sort . Foldable.foldr (:) []) pHashable :: [(Key, Int)] -> [Int] -> Int -> Property pHashable xs is salt = x == y ==> hashWithSalt salt x === hashWithSalt salt y where xs' = L.nubBy (\(k,_) (k',_) -> k == k') xs ys = shuffle is xs' x = HM.fromList xs' y = HM.fromList ys -- Shuffle the list using indexes in the second shuffle :: [Int] -> [a] -> [a] shuffle idxs = L.map snd . L.sortBy (comparing fst) . L.zip (idxs ++ [L.maximum (0:is) + 1 ..]) ------------------------------------------------------------------------ -- ** Basic interface pSize :: [(Key, Int)] -> Bool pSize = M.size `eq` HM.size pMember :: Key -> [(Key, Int)] -> Bool pMember k = M.member k `eq` HM.member k pLookup :: Key -> [(Key, Int)] -> Bool pLookup k = M.lookup k `eq` HM.lookup k pInsert :: Key -> Int -> [(Key, Int)] -> Bool pInsert k v = M.insert k v `eq_` HM.insert k v pDelete :: Key -> [(Key, Int)] -> Bool pDelete k = M.delete k `eq_` HM.delete k newtype AlwaysCollide = AC Int deriving (Arbitrary, Eq, Ord, Show) instance Hashable AlwaysCollide where hashWithSalt _ _ = 1 -- White-box test that tests the case of deleting one of two keys from -- a map, where the keys' hash values collide. pDeleteCollision :: AlwaysCollide -> AlwaysCollide -> AlwaysCollide -> Int -> Property pDeleteCollision k1 k2 k3 idx = (k1 /= k2) && (k2 /= k3) && (k1 /= k3) ==> HM.member toKeep $ HM.delete toDelete $ HM.fromList [(k1, 1 :: Int), (k2, 2), (k3, 3)] where which = idx `mod` 3 toDelete | which == 0 = k1 | which == 1 = k2 | which == 2 = k3 | otherwise = error "Impossible" toKeep | which == 0 = k2 | which == 1 = k3 | which == 2 = k1 | otherwise = error "Impossible" pInsertWith :: Key -> [(Key, Int)] -> Bool pInsertWith k = M.insertWith (+) k 1 `eq_` HM.insertWith (+) k 1 pAdjust :: Key -> [(Key, Int)] -> Bool pAdjust k = M.adjust succ k `eq_` HM.adjust succ k pUpdateAdjust :: Key -> [(Key, Int)] -> Bool pUpdateAdjust k = M.update (Just . succ) k `eq_` HM.update (Just . succ) k pUpdateDelete :: Key -> [(Key, Int)] -> Bool pUpdateDelete k = M.update (const Nothing) k `eq_` HM.update (const Nothing) k pAlterAdjust :: Key -> [(Key, Int)] -> Bool pAlterAdjust k = M.alter (fmap succ) k `eq_` HM.alter (fmap succ) k pAlterInsert :: Key -> [(Key, Int)] -> Bool pAlterInsert k = M.alter (const $ Just 3) k `eq_` HM.alter (const $ Just 3) k pAlterDelete :: Key -> [(Key, Int)] -> Bool pAlterDelete k = M.alter (const Nothing) k `eq_` HM.alter (const Nothing) k ------------------------------------------------------------------------ -- ** Combine pUnion :: [(Key, Int)] -> [(Key, Int)] -> Bool pUnion xs ys = M.union (M.fromList xs) `eq_` HM.union (HM.fromList xs) $ ys pUnionWith :: [(Key, Int)] -> [(Key, Int)] -> Bool pUnionWith xs ys = M.unionWith (-) (M.fromList xs) `eq_` HM.unionWith (-) (HM.fromList xs) $ ys pUnionWithKey :: [(Key, Int)] -> [(Key, Int)] -> Bool pUnionWithKey xs ys = M.unionWithKey go (M.fromList xs) `eq_` HM.unionWithKey go (HM.fromList xs) $ ys where go :: Key -> Int -> Int -> Int go (K k) i1 i2 = k - i1 + i2 pUnions :: [[(Key, Int)]] -> Bool pUnions xss = M.toAscList (M.unions (map M.fromList xss)) == toAscList (HM.unions (map HM.fromList xss)) ------------------------------------------------------------------------ -- ** Transformations pMap :: [(Key, Int)] -> Bool pMap = M.map (+ 1) `eq_` HM.map (+ 1) ------------------------------------------------------------------------ -- ** Difference and intersection pDifference :: [(Key, Int)] -> [(Key, Int)] -> Bool pDifference xs ys = M.difference (M.fromList xs) `eq_` HM.difference (HM.fromList xs) $ ys pDifferenceWith :: [(Key, Int)] -> [(Key, Int)] -> Bool pDifferenceWith xs ys = M.differenceWith f (M.fromList xs) `eq_` HM.differenceWith f (HM.fromList xs) $ ys where f x y = if x == 0 then Nothing else Just (x - y) pIntersection :: [(Key, Int)] -> [(Key, Int)] -> Bool pIntersection xs ys = M.intersection (M.fromList xs) `eq_` HM.intersection (HM.fromList xs) $ ys pIntersectionWith :: [(Key, Int)] -> [(Key, Int)] -> Bool pIntersectionWith xs ys = M.intersectionWith (-) (M.fromList xs) `eq_` HM.intersectionWith (-) (HM.fromList xs) $ ys pIntersectionWithKey :: [(Key, Int)] -> [(Key, Int)] -> Bool pIntersectionWithKey xs ys = M.intersectionWithKey go (M.fromList xs) `eq_` HM.intersectionWithKey go (HM.fromList xs) $ ys where go :: Key -> Int -> Int -> Int go (K k) i1 i2 = k - i1 - i2 ------------------------------------------------------------------------ -- ** Folds pFoldr :: [(Int, Int)] -> Bool pFoldr = (L.sort . M.fold (:) []) `eq` (L.sort . HM.foldr (:) []) pFoldrWithKey :: [(Int, Int)] -> Bool pFoldrWithKey = (sortByKey . M.foldrWithKey f []) `eq` (sortByKey . HM.foldrWithKey f []) where f k v z = (k, v) : z pFoldl' :: Int -> [(Int, Int)] -> Bool pFoldl' z0 = foldlWithKey'Map (\ z _ v -> v + z) z0 `eq` HM.foldl' (+) z0 foldlWithKey'Map :: (b -> k -> a -> b) -> b -> M.Map k a -> b #if MIN_VERSION_containers(4,2,0) foldlWithKey'Map = M.foldlWithKey' #else -- Equivalent except for bottoms, which we don't test. foldlWithKey'Map = M.foldlWithKey #endif ------------------------------------------------------------------------ -- ** Filter pMapMaybeWithKey :: [(Key, Int)] -> Bool pMapMaybeWithKey = M.mapMaybeWithKey f `eq_` HM.mapMaybeWithKey f where f k v = guard (odd (unK k + v)) >> Just (v + 1) pMapMaybe :: [(Key, Int)] -> Bool pMapMaybe = M.mapMaybe f `eq_` HM.mapMaybe f where f v = guard (odd v) >> Just (v + 1) pFilter :: [(Key, Int)] -> Bool pFilter = M.filter odd `eq_` HM.filter odd pFilterWithKey :: [(Key, Int)] -> Bool pFilterWithKey = M.filterWithKey p `eq_` HM.filterWithKey p where p k v = odd (unK k + v) ------------------------------------------------------------------------ -- ** Conversions -- 'eq_' already calls fromList. pFromList :: [(Key, Int)] -> Bool pFromList = id `eq_` id pFromListWith :: [(Key, Int)] -> Bool pFromListWith kvs = (M.toAscList $ M.fromListWith (+) kvs) == (toAscList $ HM.fromListWith (+) kvs) pToList :: [(Key, Int)] -> Bool pToList = M.toAscList `eq` toAscList pElems :: [(Key, Int)] -> Bool pElems = (L.sort . M.elems) `eq` (L.sort . HM.elems) pKeys :: [(Key, Int)] -> Bool pKeys = (L.sort . M.keys) `eq` (L.sort . HM.keys) ------------------------------------------------------------------------ -- * Test list tests :: [Test] tests = [ -- Instances testGroup "instances" [ testProperty "==" pEq , testProperty "/=" pNeq , testProperty "compare reflexive" pOrd1 , testProperty "compare transitive" pOrd2 , testProperty "compare antisymmetric" pOrd3 , testProperty "Ord => Eq" pOrdEq , testProperty "Read/Show" pReadShow , testProperty "Functor" pFunctor , testProperty "Foldable" pFoldable , testProperty "Hashable" pHashable ] -- Basic interface , testGroup "basic interface" [ testProperty "size" pSize , testProperty "member" pMember , testProperty "lookup" pLookup , testProperty "insert" pInsert , testProperty "delete" pDelete , testProperty "deleteCollision" pDeleteCollision , testProperty "insertWith" pInsertWith , testProperty "adjust" pAdjust , testProperty "updateAdjust" pUpdateAdjust , testProperty "updateDelete" pUpdateDelete , testProperty "alterAdjust" pAlterAdjust , testProperty "alterInsert" pAlterInsert , testProperty "alterDelete" pAlterDelete ] -- Combine , testProperty "union" pUnion , testProperty "unionWith" pUnionWith , testProperty "unionWithKey" pUnionWithKey , testProperty "unions" pUnions -- Transformations , testProperty "map" pMap -- Folds , testGroup "folds" [ testProperty "foldr" pFoldr , testProperty "foldrWithKey" pFoldrWithKey , testProperty "foldl'" pFoldl' ] , testGroup "difference and intersection" [ testProperty "difference" pDifference , testProperty "differenceWith" pDifferenceWith , testProperty "intersection" pIntersection , testProperty "intersectionWith" pIntersectionWith , testProperty "intersectionWithKey" pIntersectionWithKey ] -- Filter , testGroup "filter" [ testProperty "filter" pFilter , testProperty "filterWithKey" pFilterWithKey , testProperty "mapMaybe" pMapMaybe , testProperty "mapMaybeWithKey" pMapMaybeWithKey ] -- Conversions , testGroup "conversions" [ testProperty "elems" pElems , testProperty "keys" pKeys , testProperty "fromList" pFromList , testProperty "fromListWith" pFromListWith , testProperty "toList" pToList ] ] ------------------------------------------------------------------------ -- * Model type Model k v = M.Map k v -- | Check that a function operating on a 'HashMap' is equivalent to -- one operating on a 'Model'. eq :: (Eq a, Eq k, Hashable k, Ord k) => (Model k v -> a) -- ^ Function that modifies a 'Model' -> (HM.HashMap k v -> a) -- ^ Function that modified a 'HashMap' in the same -- way -> [(k, v)] -- ^ Initial content of the 'HashMap' and 'Model' -> Bool -- ^ True if the functions are equivalent eq f g xs = g (HM.fromList xs) == f (M.fromList xs) eq_ :: (Eq k, Eq v, Hashable k, Ord k) => (Model k v -> Model k v) -- ^ Function that modifies a 'Model' -> (HM.HashMap k v -> HM.HashMap k v) -- ^ Function that modified a -- 'HashMap' in the same way -> [(k, v)] -- ^ Initial content of the 'HashMap' -- and 'Model' -> Bool -- ^ True if the functions are -- equivalent eq_ f g = (M.toAscList . f) `eq` (toAscList . g) ------------------------------------------------------------------------ -- * Test harness main :: IO () main = defaultMain tests ------------------------------------------------------------------------ -- * Helpers sortByKey :: Ord k => [(k, v)] -> [(k, v)] sortByKey = L.sortBy (compare `on` fst) toAscList :: Ord k => HM.HashMap k v -> [(k, v)] toAscList = L.sortBy (compare `on` fst) . HM.toList