Decimal-0.4.1: tests/Main.hs
module Main where
import Data.Decimal
import Data.Ratio
import Data.Word
import Test.HUnit
import Control.Applicative
import Test.QuickCheck
import Test.Framework as TF (defaultMain, testGroup, Test)
import Test.Framework.Providers.HUnit
import Test.Framework.Providers.QuickCheck2 (testProperty)
instance (Integral i, Arbitrary i) => Arbitrary (DecimalRaw i) where
arbitrary = Decimal <$> arbitrary <*> arbitrary
-- arbitrary = do
-- e <- sized (\n -> resize (n `div` 10) arbitrary) :: Gen Int
-- m <- sized (\n -> resize (n * 10) arbitrary)
-- return $ Decimal (fromIntegral $ abs e) m
instance (Integral i, Arbitrary i) => CoArbitrary (DecimalRaw i) where
coarbitrary (Decimal e m) = variant (v:: Integer)
where v = fromIntegral e + fromIntegral m
-- | "read" is the inverse of "show".
--
-- > read (show n) == n
prop_readShow :: Decimal -> Bool
prop_readShow d = read (show d) == d
-- | Read and show preserve decimal places.
--
-- > decimalPlaces (read (show n)) == decimalPlaces n
prop_readShowPrecision :: Decimal -> Bool
prop_readShowPrecision d = decimalPlaces (read (show d) :: Decimal)
== decimalPlaces d
-- | "fromInteger" definition.
--
-- > decimalPlaces (fromInteger n) == 0 &&
-- > decimalMantissa (fromInteger n) == n
prop_fromIntegerZero :: Integer -> Bool
prop_fromIntegerZero n = decimalPlaces (fromInteger n :: Decimal) == 0 &&
decimalMantissa (fromInteger n :: Decimal) == n
-- | Increased precision does not affect equality.
--
-- > decimalPlaces d < maxBound ==> roundTo (decimalPlaces d + 1) d == d
prop_increaseDecimals :: Decimal -> Property
prop_increaseDecimals d =
decimalPlaces d < maxBound ==> roundTo (decimalPlaces d + 1) d == d
-- | Decreased precision can make two decimals equal, but it can never change
-- their order.
--
-- > forAll d1, d2 :: Decimal -> legal beforeRound afterRound
-- > where
-- > beforeRound = compare d1 d2
-- > afterRound = compare (roundTo 0 d1) (roundTo 0 d2)
-- > legal GT x = x `elem` [GT, EQ]
-- > legal EQ x = x `elem` [EQ]
-- > legal LT x = x `elem` [LT, EQ]
prop_decreaseDecimals :: Decimal -> Decimal -> Bool
prop_decreaseDecimals d1 d2 = legal beforeRound afterRound
where
beforeRound = compare d1 d2
afterRound = compare (roundTo 0 d1) (roundTo 0 d2)
legal GT x = x `elem` [GT, EQ]
legal EQ x = x `elem` [EQ]
legal LT x = x `elem` [LT, EQ]
-- | > (x + y) - y == x
prop_inverseAdd :: Decimal -> Decimal -> Bool
prop_inverseAdd x y = (x + y) - y == x
-- | Multiplication is repeated addition.
--
-- > forall d, NonNegative i : (sum $ replicate i d) == d * fromIntegral (max i 0)
prop_repeatedAdd :: Decimal -> Word8 -> Bool
prop_repeatedAdd d i = (sum $ replicate (fromIntegral i) d) == d * fromIntegral (max i 0)
-- | Division produces the right number of parts.
--
-- > forall d, Positive i : (sum $ map fst $ divide d i) == i
prop_divisionParts :: Decimal -> Positive Int -> Property
prop_divisionParts d (Positive i) = i > 0 ==> (sum $ map fst $ divide d i) == i
-- | Division doesn't drop any units.
--
-- > forall d, Positive i : (sum $ map (\(n,d1) -> fromIntegral n * d1) $ divide d i) == d
prop_divisionUnits :: Decimal -> Positive Int -> Bool
prop_divisionUnits d (Positive i) =
(sum $ map (\(n,d1) -> fromIntegral n * d1) $ divide d i) == d
-- | Allocate produces the right number of parts.
--
-- > sum ps /= 0 ==> length ps == length (allocate d ps)
prop_allocateParts :: Decimal -> [Integer] -> Property
prop_allocateParts d ps =
sum ps /= 0 ==> length ps == length (allocate d ps)
-- | Allocate doesn't drop any units.
--
-- > sum ps /= 0 ==> sum (allocate d ps) == d
prop_allocateUnits :: Decimal -> [Integer] -> Property
prop_allocateUnits d ps =
sum ps /= 0 ==> sum (allocate d ps) == d
-- | Absolute value definition
--
-- > decimalPlaces a == decimalPlaces d &&
-- > decimalMantissa a == abs (decimalMantissa d)
-- > where a = abs d
prop_abs :: Decimal -> Bool
prop_abs d = decimalPlaces a == decimalPlaces d &&
decimalMantissa a == abs (decimalMantissa d)
where a = abs d
-- | Sign number defintion
--
-- > signum d == (fromInteger $ signum $ decimalMantissa d)
prop_signum :: Decimal -> Bool
prop_signum d = signum d == (fromInteger $ signum $ decimalMantissa d)
-- | The addition is valid
prop_sumValid :: Decimal -> Decimal -> Property
prop_sumValid a b = (decimalPlaces a < maxBound && decimalPlaces b < maxBound) ==>
(toRational (a + b) == (toRational a) + (toRational b))
prop_mulValid :: Decimal -> Decimal -> Property
prop_mulValid a b = ((ad + bd) < fromIntegral (maxBound :: Word8)) ==>
(toRational (a * b) == (toRational a) * (toRational b))
where
ad, bd :: Integer
ad = fromIntegral $ decimalPlaces a
bd = fromIntegral $ decimalPlaces b
prop_eitherFromRational :: Decimal -> Bool
prop_eitherFromRational d = (Right d) == (eitherFromRational $ toRational d)
prop_normalizeDecimal :: Decimal -> Bool
prop_normalizeDecimal d = d == (normalizeDecimal d)
-- | Division is the inverted multiplication
prop_divisionMultiplication :: Decimal -> Decimal -> Property
prop_divisionMultiplication a b = ((ad + bd) < fromIntegral (maxBound :: Word8) && a /= 0 && b /= 0) ==>
(c / a == b) .&&. (c / b == a)
where
ad :: Integer
ad = fromIntegral $ decimalPlaces a
bd = fromIntegral $ decimalPlaces b
c = a * b
prop_fromRational :: Decimal -> Bool
prop_fromRational a = a == (fromRational $ toRational a)
prop_properFraction :: Decimal -> Bool
prop_properFraction a = a == (fromIntegral b + d)
where
b :: Integer
(b, d) = properFraction a
main :: IO ()
main = defaultMain tests
-- Monomorphic variations on polymorphic themes to avoid type default warnings.
dec :: Word8 -> Integer -> Decimal
dec = Decimal
dec1 :: Word8 -> Int -> DecimalRaw Int
dec1 = Decimal
piD :: Double
piD = pi
tests :: [TF.Test]
tests = [
testGroup "QuickCheck Data.Decimal" [
testProperty "readShow" prop_readShow,
testProperty "readShowPrecision" prop_readShowPrecision,
testProperty "fromIntegerZero" prop_fromIntegerZero,
testProperty "increaseDecimals" prop_increaseDecimals,
testProperty "decreaseDecimals" prop_decreaseDecimals,
testProperty "inverseAdd" prop_inverseAdd,
testProperty "repeatedAdd" prop_repeatedAdd,
testProperty "divisionParts" prop_divisionParts,
testProperty "divisionUnits" prop_divisionUnits,
testProperty "allocateParts" prop_allocateParts,
testProperty "allocateUnits" prop_allocateUnits,
testProperty "abs" prop_abs,
testProperty "signum" prop_signum,
testProperty "sumvalid" prop_sumValid,
testProperty "mulValid" prop_mulValid,
testProperty "eitherFromRational" prop_eitherFromRational,
testProperty "normalizeDecimal" prop_normalizeDecimal,
testProperty "divisionMultiplication" prop_divisionMultiplication,
testProperty "fromRational" prop_fromRational,
testProperty "properFraction" prop_properFraction
],
testGroup "Point tests Data.Decimal" [
testCase "pi to 3dp" (dec 3 3142 @=? realFracToDecimal 3 piD),
testCase "pi to 2dp" (dec 2 314 @=? realFracToDecimal 2 piD),
testCase "100*pi to 2dp" (dec 2 31416 @=? realFracToDecimal 2 (100 * piD)),
testCase "1.0 * pi" (dec 1 31 @=? dec 1 10 *. piD),
testCase "1.23 * pi" (dec 2 386 @=? dec 2 123 *. piD),
testCase "Decimal to DecimalRaw Int"
(decimalConvert (dec 2 123) @=? Just (dec1 2 123)),
testCase "decimalConvert overflow prevention"
(decimalConvert (1/3) @=? (Nothing :: Maybe (DecimalRaw Int))),
testCase "1.234 to rational" (1234 % 1000 @=? toRational (dec 3 1234)),
testCase "fromRational (1%10) for DecimalRaw Int" -- Fixed bug #3
(let v :: DecimalRaw Int
v = fromRational (1%10)
in toRational v @=? 1%10)
]
]