{-# LANGUAGE CPP #-} {-# LANGUAGE Rank2Types #-} {-# LANGUAGE DeriveDataTypeable #-} #if __GLASGOW_HASKELL__ >= 704 {-# LANGUAGE DeriveGeneric #-} #endif {-# OPTIONS_HADDOCK not-home #-} ----------------------------------------------------------------------------- -- | -- Module : Numeric.Interval.NonEmpty.Internal -- Copyright : (c) Edward Kmett 2010-2014 -- License : BSD3 -- Maintainer : ekmett@gmail.com -- Stability : experimental -- Portability : DeriveDataTypeable -- -- Interval arithmetic ----------------------------------------------------------------------------- module Numeric.Interval.NonEmpty.Internal ( Interval(..) , (...) , interval , whole , singleton , member , notMember , elem , notElem , inf , sup , singular , width , midpoint , distance , intersection , hull , bisect , bisectIntegral , magnitude , mignitude , contains , isSubsetOf , certainly, (<!), (<=!), (==!), (>=!), (>!) , possibly, (<?), (<=?), (==?), (>=?), (>?) , clamp , inflate, deflate , scale, symmetric , idouble , ifloat , iquot , irem , idiv , imod ) where import Control.Exception as Exception import Data.Data import Data.Foldable hiding (minimum, maximum, elem, notElem) import Data.Monoid #if __GLASGOW_HASKELL__ >= 704 import GHC.Generics #endif import Numeric.Interval.Exception import Prelude hiding (null, elem, notElem) -- $setup -- >>> import Test.QuickCheck.Arbitrary -- >>> import Test.QuickCheck.Gen hiding (scale) -- >>> import Test.QuickCheck.Property -- >>> import Control.Applicative -- >>> :set -XNoMonomorphismRestriction -- >>> :set -XExtendedDefaultRules -- >>> default (Integer,Double) -- >>> instance (Ord a, Arbitrary a) => Arbitrary (Interval a) where arbitrary = (...) <$> arbitrary <*> arbitrary -- >>> let memberOf xs = sized $ \n -> case n of { 0 -> pure $ inf xs; 1 -> pure $ sup xs; _ -> choose (inf xs, sup xs); } -- >>> let conservative sf f xs = forAll (choose (inf xs, sup xs)) $ \x -> (sf x) `member` (f xs) -- >>> let conservative2 sf f xs ys = forAll ((,) <$> choose (inf xs, sup xs) <*> choose (inf ys, sup ys)) $ \(x,y) -> (sf x y) `member` (f xs ys) -- >>> let conservativeExceptNaN sf f xs = forAll (choose (inf xs, sup xs)) $ \x -> isNaN (sf x) || (sf x) `member` (f xs) -- >>> let compose2 = fmap . fmap -- >>> let commutative op a b = (a `op` b) == (b `op` a) data Interval a = I !a !a deriving ( Eq, Ord , Data , Typeable #if __GLASGOW_HASKELL__ >= 704 , Generic #if __GLASGOW_HASKELL__ >= 706 , Generic1 #endif #endif ) instance Foldable Interval where foldMap f (I a b) = f a `mappend` f b {-# INLINE foldMap #-} infix 3 ... negInfinity :: Fractional a => a negInfinity = (-1)/0 {-# INLINE negInfinity #-} posInfinity :: Fractional a => a posInfinity = 1/0 {-# INLINE posInfinity #-} -- the sign of a number, but as an Ordering so that we can pattern match over it. -- GT means greater than zero, etc. signum' :: (Ord a, Num a) => a -> Ordering signum' x = compare x 0 -- arguments are period, range, derivative, function, and interval -- we require that each period of the function include precisely one local minimum and one local maximum periodic :: (Num a, Ord a) => a -> Interval a -> (a -> Ordering) -> (a -> a) -> Interval a -> Interval a periodic p r _ _ x | width x > p = r periodic _ r d f (I a b) = periodic' r (d a) (d b) (f a) (f b) -- arguments are global range, derivatives at endpoints, values at endpoints periodic' :: (Ord a) => Interval a -> Ordering -> Ordering -> a -> a -> Interval a periodic' r GT GT a b | a <= b = I a b -- stays in increasing zone | otherwise = r -- goes from increasing zone, all the way through decreasing zone, and back to increasing zone periodic' r LT LT a b | a >= b = I b a -- stays in decreasing zone | otherwise = r -- goes from decreasing zone, all the way through increasing zone, and back to decreasing zone periodic' r GT _ a b = I (min a b) (sup r) -- was going up, started going down periodic' r LT _ a b = I (inf r) (max a b) -- was going down, started going up periodic' r EQ GT a b | a < b = I a b -- stays in increasing zone | otherwise = r -- goes from increasing zone, all the way through decreasing zone, and back to increasing zone periodic' r EQ LT a b | a > b = I b a -- stays in decreasing zone | otherwise = r -- goes from decreasing zone, all the way through increasing zone, and back to decreasing zone periodic' _ _ _ a b = a ... b -- precisely begins and ends at local extremes, so it's either a singleton or whole -- | Create a non-empty interval, turning it around if necessary (...) :: Ord a => a -> a -> Interval a a ... b | a <= b = I a b | otherwise = I b a {-# INLINE (...) #-} -- | Try to create a non-empty interval. interval :: Ord a => a -> a -> Maybe (Interval a) interval a b | a <= b = Just $ I a b | otherwise = Nothing -- | The whole real number line -- -- >>> whole -- -Infinity ... Infinity -- -- prop> (x :: Double) `elem` whole whole :: Fractional a => Interval a whole = I negInfinity posInfinity {-# INLINE whole #-} -- | A singleton point -- -- >>> singleton 1 -- 1 ... 1 -- -- prop> x `elem` (singleton x) -- prop> x /= y ==> y `notElem` (singleton x) singleton :: a -> Interval a singleton a = I a a {-# INLINE singleton #-} -- | The infinumum (lower bound) of an interval -- -- >>> inf (1 ... 20) -- 1 -- -- prop> min x y == inf (x ... y) -- prop> inf x <= sup x inf :: Interval a -> a inf (I a _) = a {-# INLINE inf #-} -- | The supremum (upper bound) of an interval -- -- >>> sup (1 ... 20) -- 20 -- -- prop> sup x `elem` x -- prop> max x y == sup (x ... y) -- prop> inf x <= sup x sup :: Interval a -> a sup (I _ b) = b {-# INLINE sup #-} -- | Is the interval a singleton point? -- N.B. This is fairly fragile and likely will not hold after -- even a few operations that only involve singletons -- -- >>> singular (singleton 1) -- True -- -- >>> singular (1.0 ... 20.0) -- False singular :: Ord a => Interval a -> Bool singular (I a b) = a == b {-# INLINE singular #-} instance Show a => Show (Interval a) where showsPrec n (I a b) = showParen (n > 3) $ showsPrec 3 a . showString " ... " . showsPrec 3 b -- | Calculate the width of an interval. -- -- >>> width (1 ... 20) -- 19 -- -- >>> width (singleton 1) -- 0 -- -- prop> 0 <= width x width :: Num a => Interval a -> a width (I a b) = b - a {-# INLINE width #-} -- | Magnitude -- -- >>> magnitude (1 ... 20) -- 20 -- -- >>> magnitude (-20 ... 10) -- 20 -- -- >>> magnitude (singleton 5) -- 5 -- -- prop> 0 <= magnitude x magnitude :: (Num a, Ord a) => Interval a -> a magnitude = sup . abs {-# INLINE magnitude #-} -- | \"mignitude\" -- -- >>> mignitude (1 ... 20) -- 1 -- -- >>> mignitude (-20 ... 10) -- 0 -- -- >>> mignitude (singleton 5) -- 5 -- -- prop> 0 <= mignitude x mignitude :: (Num a, Ord a) => Interval a -> a mignitude = inf . abs {-# INLINE mignitude #-} -- | Num instance for intervals. -- -- prop> conservative2 ((+) :: Double -> Double -> Double) (+) -- prop> conservative2 ((-) :: Double -> Double -> Double) (-) -- prop> conservative2 ((*) :: Double -> Double -> Double) (*) -- prop> conservative (abs :: Double -> Double) abs instance (Num a, Ord a) => Num (Interval a) where I a b + I a' b' = (a + a') ... (b + b') {-# INLINE (+) #-} I a b - I a' b' = (a - b') ... (b - a') {-# INLINE (-) #-} I a b * I a' b' = minimum [a * a', a * b', b * a', b * b'] ... maximum [a * a', a * b', b * a', b * b'] {-# INLINE (*) #-} abs x@(I a b) | a >= 0 = x | b <= 0 = negate x | otherwise = 0 ... max (- a) b {-# INLINE abs #-} signum = increasing signum {-# INLINE signum #-} fromInteger i = singleton (fromInteger i) {-# INLINE fromInteger #-} -- | Bisect an interval at its midpoint. -- -- >>> bisect (10.0 ... 20.0) -- (10.0 ... 15.0,15.0 ... 20.0) -- -- >>> bisect (singleton 5.0) -- (5.0 ... 5.0,5.0 ... 5.0) -- -- prop> let (a, b) = bisect (x :: Interval Double) in sup a == inf b -- prop> let (a, b) = bisect (x :: Interval Double) in inf a == inf x -- prop> let (a, b) = bisect (x :: Interval Double) in sup b == sup x bisect :: Fractional a => Interval a -> (Interval a, Interval a) bisect (I a b) = (I a m, I m b) where m = a + (b - a) / 2 {-# INLINE bisect #-} bisectIntegral :: Integral a => Interval a -> (Interval a, Interval a) bisectIntegral (I a b) | a == m || b == m = (I a a, I b b) | otherwise = (I a m, I m b) where m = a + (b - a) `div` 2 {-# INLINE bisectIntegral #-} -- | Nearest point to the midpoint of the interval. -- -- >>> midpoint (10.0 ... 20.0) -- 15.0 -- -- >>> midpoint (singleton 5.0) -- 5.0 -- -- prop> midpoint x `elem` (x :: Interval Double) midpoint :: Fractional a => Interval a -> a midpoint (I a b) = a + (b - a) / 2 {-# INLINE midpoint #-} -- | Hausdorff distance between intervals. -- -- >>> distance (1 ... 7) (6 ... 10) -- 0 -- -- >>> distance (1 ... 7) (15 ... 24) -- 8 -- -- >>> distance (1 ... 7) (-10 ... -2) -- 3 -- -- prop> commutative (distance :: Interval Double -> Interval Double -> Double) -- prop> 0 <= distance x y distance :: (Num a, Ord a) => Interval a -> Interval a -> a distance i1 i2 = mignitude (i1 - i2) -- | Determine if a point is in the interval. -- -- >>> member 3.2 (1.0 ... 5.0) -- True -- -- >>> member 5 (1.0 ... 5.0) -- True -- -- >>> member 1 (1.0 ... 5.0) -- True -- -- >>> member 8 (1.0 ... 5.0) -- False member :: Ord a => a -> Interval a -> Bool member x (I a b) = x >= a && x <= b {-# INLINE member #-} -- | Determine if a point is not included in the interval -- -- >>> notMember 8 (1.0 ... 5.0) -- True -- -- >>> notMember 1.4 (1.0 ... 5.0) -- False notMember :: Ord a => a -> Interval a -> Bool notMember x xs = not (member x xs) {-# INLINE notMember #-} -- | Determine if a point is in the interval. -- -- >>> elem 3.2 (1.0 ... 5.0) -- True -- -- >>> elem 5 (1.0 ... 5.0) -- True -- -- >>> elem 1 (1.0 ... 5.0) -- True -- -- >>> elem 8 (1.0 ... 5.0) -- False elem :: Ord a => a -> Interval a -> Bool elem = member {-# INLINE elem #-} {-# DEPRECATED elem "Use `member` instead." #-} -- | Determine if a point is not included in the interval -- -- >>> notElem 8 (1.0 ... 5.0) -- True -- -- >>> notElem 1.4 (1.0 ... 5.0) -- False notElem :: Ord a => a -> Interval a -> Bool notElem = notMember {-# INLINE notElem #-} {-# DEPRECATED notElem "Use `notMember` instead." #-} -- | 'realToFrac' will use the midpoint instance Real a => Real (Interval a) where toRational (I ra rb) = a + (b - a) / 2 where a = toRational ra b = toRational rb {-# INLINE toRational #-} -- @'divNonZero' X Y@ assumes @0 `'notElem'` Y@ divNonZero :: (Fractional a, Ord a) => Interval a -> Interval a -> Interval a divNonZero (I a b) (I a' b') = minimum [a / a', a / b', b / a', b / b'] ... maximum [a / a', a / b', b / a', b / b'] -- @'divPositive' X y@ assumes y > 0, and divides @X@ by [0 ... y] divPositive :: (Fractional a, Ord a) => Interval a -> a -> Interval a divPositive x@(I a b) y | a == 0 && b == 0 = x -- b < 0 || isNegativeZero b = negInfinity ... ( b / y) | b < 0 = negInfinity ... (b / y) | a < 0 = whole | otherwise = (a / y) ... posInfinity {-# INLINE divPositive #-} -- divNegative assumes y < 0 and divides the interval @X@ by [y ... 0] divNegative :: (Fractional a, Ord a) => Interval a -> a -> Interval a divNegative x@(I a b) y | a == 0 && b == 0 = - x -- flip negative zeros -- b < 0 || isNegativeZero b = (b / y) ... posInfinity | b < 0 = (b / y) ... posInfinity | a < 0 = whole | otherwise = negInfinity ... (a / y) {-# INLINE divNegative #-} divZero :: (Fractional a, Ord a) => Interval a -> Interval a divZero x@(I a b) | a == 0 && b == 0 = x | otherwise = whole {-# INLINE divZero #-} -- | Fractional instance for intervals. -- -- prop> ys /= singleton 0 ==> conservative2 ((/) :: Double -> Double -> Double) (/) xs ys -- prop> xs /= singleton 0 ==> conservative (recip :: Double -> Double) recip xs instance (Fractional a, Ord a) => Fractional (Interval a) where -- TODO: check isNegativeZero properly x / y@(I a b) | 0 `notElem` y = divNonZero x y | iz && sz = Exception.throw DivideByZero | iz = divPositive x a | sz = divNegative x b | otherwise = divZero x where iz = a == 0 sz = b == 0 fromRational r = let r' = fromRational r in I r' r' {-# INLINE fromRational #-} instance RealFrac a => RealFrac (Interval a) where properFraction x = (b, x - fromIntegral b) where b = truncate (midpoint x) {-# INLINE properFraction #-} ceiling x = ceiling (sup x) {-# INLINE ceiling #-} floor x = floor (inf x) {-# INLINE floor #-} round x = round (midpoint x) {-# INLINE round #-} truncate x = truncate (midpoint x) {-# INLINE truncate #-} -- | Transcendental functions for intervals. -- -- prop> conservative (exp :: Double -> Double) exp -- prop> conservativeExceptNaN (log :: Double -> Double) log -- prop> conservative (sin :: Double -> Double) sin -- prop> conservative (cos :: Double -> Double) cos -- prop> conservative (tan :: Double -> Double) tan -- prop> conservativeExceptNaN (asin :: Double -> Double) asin -- prop> conservativeExceptNaN (acos :: Double -> Double) acos -- prop> conservative (atan :: Double -> Double) atan -- prop> conservative (sinh :: Double -> Double) sinh -- prop> conservative (cosh :: Double -> Double) cosh -- prop> conservative (tanh :: Double -> Double) tanh -- prop> conservativeExceptNaN (asinh :: Double -> Double) asinh -- prop> conservativeExceptNaN (acosh :: Double -> Double) acosh -- prop> conservativeExceptNaN (atanh :: Double -> Double) atanh -- -- >>> cos (0 ... (pi + 0.1)) -- -1.0 ... 1.0 instance (RealFloat a, Ord a) => Floating (Interval a) where pi = singleton pi {-# INLINE pi #-} exp = increasing exp {-# INLINE exp #-} log (I a b) = (if a > 0 then log a else negInfinity) ... (if b > 0 then log b else negInfinity) {-# INLINE log #-} sin = periodic (2 * pi) (symmetric 1) (signum' . cos) sin cos = periodic (2 * pi) (symmetric 1) (signum' . negate . sin) cos tan = periodic pi whole (const GT) tan -- derivative only has to have correct sign asin (I a b) = (asin' a) ... (asin' b) where asin' x | x >= 1 = halfPi | x <= -1 = -halfPi | otherwise = asin x halfPi = pi / 2 {-# INLINE asin #-} acos (I a b) = (acos' a) ... (acos' b) where acos' x | x >= 1 = 0 | x <= -1 = pi | otherwise = acos x {-# INLINE acos #-} atan = increasing atan {-# INLINE atan #-} sinh = increasing sinh {-# INLINE sinh #-} cosh x@(I a b) | b < 0 = decreasing cosh x | a >= 0 = increasing cosh x | otherwise = I 0 $ cosh $ if - a > b then a else b {-# INLINE cosh #-} tanh = increasing tanh {-# INLINE tanh #-} asinh = increasing asinh {-# INLINE asinh #-} acosh (I a b) = (acosh' a) ... (acosh' b) where acosh' x | x <= 1 = 0 | otherwise = acosh x {-# INLINE acosh #-} atanh (I a b) = (atanh' a) ... (atanh' b) where atanh' x | x <= -1 = negInfinity | x >= 1 = posInfinity | otherwise = atanh x {-# INLINE atanh #-} -- | lift a monotone increasing function over a given interval increasing :: (a -> b) -> Interval a -> Interval b increasing f (I a b) = I (f a) (f b) -- | lift a monotone decreasing function over a given interval decreasing :: (a -> b) -> Interval a -> Interval b decreasing f (I a b) = I (f b) (f a) -- | We have to play some semantic games to make these methods make sense. -- Most compute with the midpoint of the interval. instance RealFloat a => RealFloat (Interval a) where floatRadix = floatRadix . midpoint floatDigits = floatDigits . midpoint floatRange = floatRange . midpoint decodeFloat = decodeFloat . midpoint encodeFloat m e = singleton (encodeFloat m e) exponent = exponent . midpoint significand x = min a b ... max a b where (_ ,em) = decodeFloat (midpoint x) (mi,ei) = decodeFloat (inf x) (ms,es) = decodeFloat (sup x) a = encodeFloat mi (ei - em - floatDigits x) b = encodeFloat ms (es - em - floatDigits x) scaleFloat n (I a b) = I (scaleFloat n a) (scaleFloat n b) isNaN (I a b) = isNaN a || isNaN b isInfinite (I a b) = isInfinite a || isInfinite b isDenormalized (I a b) = isDenormalized a || isDenormalized b -- contains negative zero isNegativeZero (I a b) = not (a > 0) && not (b < 0) && ( (b == 0 && (a < 0 || isNegativeZero a)) || (a == 0 && isNegativeZero a) || (a < 0 && b >= 0)) isIEEE _ = False atan2 = error "unimplemented" -- TODO: (^), (^^) to give tighter bounds -- | Calculate the intersection of two intervals. -- -- >>> intersection (1 ... 10 :: Interval Double) (5 ... 15 :: Interval Double) -- Just (5.0 ... 10.0) intersection :: Ord a => Interval a -> Interval a -> Maybe (Interval a) intersection x@(I a b) y@(I a' b') | x /=! y = Nothing | otherwise = Just $ I (max a a') (min b b') {-# INLINE intersection #-} -- | Calculate the convex hull of two intervals -- -- >>> hull (0 ... 10 :: Interval Double) (5 ... 15 :: Interval Double) -- 0.0 ... 15.0 -- -- >>> hull (15 ... 85 :: Interval Double) (0 ... 10 :: Interval Double) -- 0.0 ... 85.0 -- -- prop> conservative2 const hull -- prop> conservative2 (flip const) hull hull :: Ord a => Interval a -> Interval a -> Interval a hull (I a b) (I a' b') = I (min a a') (max b b') {-# INLINE hull #-} -- | For all @x@ in @X@, @y@ in @Y@. @x '<' y@ -- -- >>> (5 ... 10 :: Interval Double) <! (20 ... 30 :: Interval Double) -- True -- -- >>> (5 ... 10 :: Interval Double) <! (10 ... 30 :: Interval Double) -- False -- -- >>> (20 ... 30 :: Interval Double) <! (5 ... 10 :: Interval Double) -- False (<!) :: Ord a => Interval a -> Interval a -> Bool I _ bx <! I ay _ = bx < ay {-# INLINE (<!) #-} -- | For all @x@ in @X@, @y@ in @Y@. @x '<=' y@ -- -- >>> (5 ... 10 :: Interval Double) <=! (20 ... 30 :: Interval Double) -- True -- -- >>> (5 ... 10 :: Interval Double) <=! (10 ... 30 :: Interval Double) -- True -- -- >>> (20 ... 30 :: Interval Double) <=! (5 ... 10 :: Interval Double) -- False (<=!) :: Ord a => Interval a -> Interval a -> Bool I _ bx <=! I ay _ = bx <= ay {-# INLINE (<=!) #-} -- | For all @x@ in @X@, @y@ in @Y@. @x '==' y@ -- -- Only singleton intervals or empty intervals can return true -- -- >>> (singleton 5 :: Interval Double) ==! (singleton 5 :: Interval Double) -- True -- -- >>> (5 ... 10 :: Interval Double) ==! (5 ... 10 :: Interval Double) -- False (==!) :: Eq a => Interval a -> Interval a -> Bool I ax bx ==! I ay by = bx == ay && ax == by {-# INLINE (==!) #-} -- | For all @x@ in @X@, @y@ in @Y@. @x '/=' y@ -- -- >>> (5 ... 15 :: Interval Double) /=! (20 ... 40 :: Interval Double) -- True -- -- >>> (5 ... 15 :: Interval Double) /=! (15 ... 40 :: Interval Double) -- False (/=!) :: Ord a => Interval a -> Interval a -> Bool I ax bx /=! I ay by = bx < ay || ax > by {-# INLINE (/=!) #-} -- | For all @x@ in @X@, @y@ in @Y@. @x '>' y@ -- -- >>> (20 ... 40 :: Interval Double) >! (10 ... 19 :: Interval Double) -- True -- -- >>> (5 ... 20 :: Interval Double) >! (15 ... 40 :: Interval Double) -- False (>!) :: Ord a => Interval a -> Interval a -> Bool I ax _ >! I _ by = ax > by {-# INLINE (>!) #-} -- | For all @x@ in @X@, @y@ in @Y@. @x '>=' y@ -- -- >>> (20 ... 40 :: Interval Double) >=! (10 ... 20 :: Interval Double) -- True -- -- >>> (5 ... 20 :: Interval Double) >=! (15 ... 40 :: Interval Double) -- False (>=!) :: Ord a => Interval a -> Interval a -> Bool I ax _ >=! I _ by = ax >= by {-# INLINE (>=!) #-} -- | For all @x@ in @X@, @y@ in @Y@. @x `op` y@ certainly :: Ord a => (forall b. Ord b => b -> b -> Bool) -> Interval a -> Interval a -> Bool certainly cmp l r | lt && eq && gt = True | lt && eq = l <=! r | lt && gt = l /=! r | lt = l <! r | eq && gt = l >=! r | eq = l ==! r | gt = l >! r | otherwise = False where lt = cmp False True eq = cmp True True gt = cmp True False {-# INLINE certainly #-} -- | Check if interval @X@ totally contains interval @Y@ -- -- >>> (20 ... 40 :: Interval Double) `contains` (25 ... 35 :: Interval Double) -- True -- -- >>> (20 ... 40 :: Interval Double) `contains` (15 ... 35 :: Interval Double) -- False contains :: Ord a => Interval a -> Interval a -> Bool contains (I ax bx) (I ay by) = ax <= ay && by <= bx {-# INLINE contains #-} -- | Flipped version of `contains`. Check if interval @X@ a subset of interval @Y@ -- -- >>> (25 ... 35 :: Interval Double) `isSubsetOf` (20 ... 40 :: Interval Double) -- True -- -- >>> (20 ... 40 :: Interval Double) `isSubsetOf` (15 ... 35 :: Interval Double) -- False isSubsetOf :: Ord a => Interval a -> Interval a -> Bool isSubsetOf = flip contains {-# INLINE isSubsetOf #-} -- | Does there exist an @x@ in @X@, @y@ in @Y@ such that @x '<' y@? (<?) :: Ord a => Interval a -> Interval a -> Bool I ax _ <? I _ by = ax < by {-# INLINE (<?) #-} -- | Does there exist an @x@ in @X@, @y@ in @Y@ such that @x '<=' y@? (<=?) :: Ord a => Interval a -> Interval a -> Bool I ax _ <=? I _ by = ax <= by {-# INLINE (<=?) #-} -- | Does there exist an @x@ in @X@, @y@ in @Y@ such that @x '==' y@? (==?) :: Ord a => Interval a -> Interval a -> Bool I ax bx ==? I ay by = ax <= by && bx >= ay {-# INLINE (==?) #-} -- | Does there exist an @x@ in @X@, @y@ in @Y@ such that @x '/=' y@? (/=?) :: Eq a => Interval a -> Interval a -> Bool I ax bx /=? I ay by = ax /= by || bx /= ay {-# INLINE (/=?) #-} -- | Does there exist an @x@ in @X@, @y@ in @Y@ such that @x '>' y@? (>?) :: Ord a => Interval a -> Interval a -> Bool I _ bx >? I ay _ = bx > ay {-# INLINE (>?) #-} -- | Does there exist an @x@ in @X@, @y@ in @Y@ such that @x '>=' y@? (>=?) :: Ord a => Interval a -> Interval a -> Bool I _ bx >=? I ay _ = bx >= ay {-# INLINE (>=?) #-} -- | Does there exist an @x@ in @X@, @y@ in @Y@ such that @x `op` y@? possibly :: Ord a => (forall b. Ord b => b -> b -> Bool) -> Interval a -> Interval a -> Bool possibly cmp l r | lt && eq && gt = True | lt && eq = l <=? r | lt && gt = l /=? r | lt = l <? r | eq && gt = l >=? r | eq = l ==? r | gt = l >? r | otherwise = False where lt = cmp LT EQ eq = cmp EQ EQ gt = cmp GT EQ {-# INLINE possibly #-} -- | The nearest value to that supplied which is contained in the interval. -- -- prop> (clamp xs y) `elem` xs clamp :: Ord a => Interval a -> a -> a clamp (I a b) x | x < a = a | x > b = b | otherwise = x -- | Inflate an interval by enlarging it at both ends. -- -- >>> inflate 3 (-1 ... 7) -- -4 ... 10 -- -- >>> inflate (-2) (0 ... 4) -- -2 ... 6 -- -- prop> inflate x i `contains` i inflate :: (Num a, Ord a) => a -> Interval a -> Interval a inflate x y = symmetric x + y -- | Deflate an interval by shrinking it from both ends. -- Note that in cases that would result in an empty interval, the result is a singleton interval at the midpoint. -- -- >>> deflate 3.0 (-4.0 ... 10.0) -- -1.0 ... 7.0 -- -- >>> deflate 2.0 (-1.0 ... 1.0) -- 0.0 ... 0.0 deflate :: (Fractional a, Ord a) => a -> Interval a -> Interval a deflate x i@(I a b) | a' <= b' = I a' b' | otherwise = singleton m where a' = a + x b' = b - x m = midpoint i -- | Scale an interval about its midpoint. -- -- >>> scale 1.1 (-6.0 ... 4.0) -- -6.5 ... 4.5 -- -- >>> scale (-2.0) (-1.0 ... 1.0) -- -2.0 ... 2.0 -- -- prop> abs x >= 1 ==> (scale (x :: Double) i) `contains` i -- prop> forAll (choose (0,1)) $ \x -> abs x <= 1 ==> i `contains` (scale (x :: Double) i) scale :: (Fractional a, Ord a) => a -> Interval a -> Interval a scale x i = a ... b where h = x * width i / 2 mid = midpoint i a = mid - h b = mid + h -- | Construct a symmetric interval. -- -- >>> symmetric 3 -- -3 ... 3 -- -- >>> symmetric (-2) -- -2 ... 2 -- -- prop> x `elem` symmetric x -- prop> 0 `elem` symmetric x symmetric :: (Num a, Ord a) => a -> Interval a symmetric x = negate x ... x -- | id function. Useful for type specification -- -- >>> :t idouble (1 ... 3) -- idouble (1 ... 3) :: Interval Double idouble :: Interval Double -> Interval Double idouble = id -- | id function. Useful for type specification -- -- >>> :t ifloat (1 ... 3) -- ifloat (1 ... 3) :: Interval Float ifloat :: Interval Float -> Interval Float ifloat = id -- Bugs: -- sin 1 :: Interval Double default (Integer,Double) -- | an interval containing all x `quot` y -- prop> forAll (memberOf xs) $ \ x -> forAll (memberOf ys) $ \ y -> 0 `notMember` ys ==> (x `quot` y) `member` (xs `iquot` ys) -- prop> 0 `member` ys ==> ioProperty $ do z <- try (evaluate (xs `iquot` ys)); return $ z === Left DivideByZero iquot :: Integral a => Interval a -> Interval a -> Interval a iquot (I l u) (I l' u') = if l' <= 0 && 0 <= u' then throw DivideByZero else I (minimum [a `quot` b | a <- [l,u], b <- [l',u']]) (maximum [a `quot` b | a <- [l,u], b <- [l',u']]) -- | an interval containing all x `rem` y -- prop> forAll (memberOf xs) $ \ x -> forAll (memberOf ys) $ \ y -> 0 `notMember` ys ==> (x `rem` y) `member` (xs `irem` ys) -- prop> 0 `member` ys ==> ioProperty $ do z <- try (evaluate (xs `irem` ys)); return $ z === Left DivideByZero irem :: Integral a => Interval a -> Interval a -> Interval a irem (I l u) (I l' u') = if l' <= 0 && 0 <= u' then throw DivideByZero else I (minimum [0, signum l * (abs u' - 1), signum l * (abs l' - 1)]) (maximum [0, signum u * (abs u' - 1), signum u * (abs l' - 1)]) -- | an interval containing all x `div` y -- prop> forAll (memberOf xs) $ \ x -> forAll (memberOf ys) $ \ y -> 0 `notMember` ys ==> (x `div` y) `member` (xs `idiv` ys) -- prop> 0 `member` ys ==> ioProperty $ do z <- try (evaluate (xs `idiv` ys)); return $ z === Left DivideByZero idiv :: Integral a => Interval a -> Interval a -> Interval a idiv (I l u) (I l' u') = if l' <= 0 && 0 <= u' then throw DivideByZero else I (min (l `Prelude.div` max 1 l') (u `Prelude.div` min (-1) u')) (max (u `Prelude.div` max 1 l') (l `Prelude.div` min (-1) u')) -- | an interval containing all x `mod` y -- prop> forAll (memberOf xs) $ \ x -> forAll (memberOf ys) $ \ y -> 0 `notMember` ys ==> (x `mod` y) `member` (xs `imod` ys) -- prop> 0 `member` ys ==> ioProperty $ do z <- try (evaluate (xs `imod` ys)); return $ z === Left DivideByZero imod :: Integral a => Interval a -> Interval a -> Interval a imod _ (I l' u') = if l' <= 0 && 0 <= u' then throw DivideByZero else I (min (l'+1) 0) (max 0 (u'-1))