intervals-0.9.2: Interval Arithmetic
Copyright(c) Edward Kmett 2010-2014
LicenseBSD3
Maintainerekmett@gmail.com
Stabilityexperimental
PortabilityDeriveDataTypeable
Safe HaskellSafe-Inferred
LanguageHaskell2010

Numeric.Interval.NonEmpty.Internal

Description

Interval arithmetic

Synopsis

Documentation

data Interval a Source #

Constructors

I !a !a 

Instances

Instances details
Eq a => Eq (Interval a) Source # 
Instance details

Defined in Numeric.Interval.NonEmpty.Internal

Methods

(==) :: Interval a -> Interval a -> Bool #

(/=) :: Interval a -> Interval a -> Bool #

(RealFloat a, Ord a) => Floating (Interval a) Source #

Transcendental functions for intervals.

conservative (exp :: Double -> Double) exp
conservativeExceptNaN (log :: Double -> Double) log
conservative (sin :: Double -> Double) sin
conservative (cos :: Double -> Double) cos
conservative (tan :: Double -> Double) tan
conservativeExceptNaN (asin :: Double -> Double) asin
conservativeExceptNaN (acos :: Double -> Double) acos
conservative (atan :: Double -> Double) atan
conservative (sinh :: Double -> Double) sinh
conservative (cosh :: Double -> Double) cosh
conservative (tanh :: Double -> Double) tanh
conservativeExceptNaN (asinh :: Double -> Double) asinh
conservativeExceptNaN (acosh :: Double -> Double) acosh
conservativeExceptNaN (atanh :: Double -> Double) atanh
>>> cos (0 ... (pi + 0.1))
-1.0 ... 1.0
Instance details

Defined in Numeric.Interval.NonEmpty.Internal

(Fractional a, Ord a) => Fractional (Interval a) Source #

Fractional instance for intervals.

ys /= singleton 0 ==> conservative2 ((/) :: Double -> Double -> Double) (/) xs ys
xs /= singleton 0 ==> conservative (recip :: Double -> Double) recip xs
Instance details

Defined in Numeric.Interval.NonEmpty.Internal

Data a => Data (Interval a) Source # 
Instance details

Defined in Numeric.Interval.NonEmpty.Internal

Methods

gfoldl :: (forall d b. Data d => c (d -> b) -> d -> c b) -> (forall g. g -> c g) -> Interval a -> c (Interval a) #

gunfold :: (forall b r. Data b => c (b -> r) -> c r) -> (forall r. r -> c r) -> Constr -> c (Interval a) #

toConstr :: Interval a -> Constr #

dataTypeOf :: Interval a -> DataType #

dataCast1 :: Typeable t => (forall d. Data d => c (t d)) -> Maybe (c (Interval a)) #

dataCast2 :: Typeable t => (forall d e. (Data d, Data e) => c (t d e)) -> Maybe (c (Interval a)) #

gmapT :: (forall b. Data b => b -> b) -> Interval a -> Interval a #

gmapQl :: (r -> r' -> r) -> r -> (forall d. Data d => d -> r') -> Interval a -> r #

gmapQr :: forall r r'. (r' -> r -> r) -> r -> (forall d. Data d => d -> r') -> Interval a -> r #

gmapQ :: (forall d. Data d => d -> u) -> Interval a -> [u] #

gmapQi :: Int -> (forall d. Data d => d -> u) -> Interval a -> u #

gmapM :: Monad m => (forall d. Data d => d -> m d) -> Interval a -> m (Interval a) #

gmapMp :: MonadPlus m => (forall d. Data d => d -> m d) -> Interval a -> m (Interval a) #

gmapMo :: MonadPlus m => (forall d. Data d => d -> m d) -> Interval a -> m (Interval a) #

(Num a, Ord a) => Num (Interval a) Source #

Num instance for intervals.

conservative2 ((+) :: Double -> Double -> Double) (+)
conservative2 ((-) :: Double -> Double -> Double) (-)
conservative2 ((*) :: Double -> Double -> Double) (*)
conservative (abs :: Double -> Double) abs
Instance details

Defined in Numeric.Interval.NonEmpty.Internal

Ord a => Ord (Interval a) Source # 
Instance details

Defined in Numeric.Interval.NonEmpty.Internal

Methods

compare :: Interval a -> Interval a -> Ordering #

(<) :: Interval a -> Interval a -> Bool #

(<=) :: Interval a -> Interval a -> Bool #

(>) :: Interval a -> Interval a -> Bool #

(>=) :: Interval a -> Interval a -> Bool #

max :: Interval a -> Interval a -> Interval a #

min :: Interval a -> Interval a -> Interval a #

Real a => Real (Interval a) Source #

realToFrac will use the midpoint

Instance details

Defined in Numeric.Interval.NonEmpty.Internal

Methods

toRational :: Interval a -> Rational #

RealFloat a => RealFloat (Interval a) Source #

We have to play some semantic games to make these methods make sense. Most compute with the midpoint of the interval.

Instance details

Defined in Numeric.Interval.NonEmpty.Internal

RealFrac a => RealFrac (Interval a) Source # 
Instance details

Defined in Numeric.Interval.NonEmpty.Internal

Methods

properFraction :: Integral b => Interval a -> (b, Interval a) #

truncate :: Integral b => Interval a -> b #

round :: Integral b => Interval a -> b #

ceiling :: Integral b => Interval a -> b #

floor :: Integral b => Interval a -> b #

Show a => Show (Interval a) Source # 
Instance details

Defined in Numeric.Interval.NonEmpty.Internal

Methods

showsPrec :: Int -> Interval a -> ShowS #

show :: Interval a -> String #

showList :: [Interval a] -> ShowS #

Generic (Interval a) Source # 
Instance details

Defined in Numeric.Interval.NonEmpty.Internal

Associated Types

type Rep (Interval a) :: Type -> Type #

Methods

from :: Interval a -> Rep (Interval a) x #

to :: Rep (Interval a) x -> Interval a #

Ord a => Semigroup (Interval a) Source #

<> is hull

Instance details

Defined in Numeric.Interval.NonEmpty.Internal

Methods

(<>) :: Interval a -> Interval a -> Interval a #

sconcat :: NonEmpty (Interval a) -> Interval a #

stimes :: Integral b => b -> Interval a -> Interval a #

Generic1 Interval Source # 
Instance details

Defined in Numeric.Interval.NonEmpty.Internal

Associated Types

type Rep1 Interval :: k -> Type #

Methods

from1 :: forall (a :: k). Interval a -> Rep1 Interval a #

to1 :: forall (a :: k). Rep1 Interval a -> Interval a #

type Rep (Interval a) Source # 
Instance details

Defined in Numeric.Interval.NonEmpty.Internal

type Rep (Interval a) = D1 ('MetaData "Interval" "Numeric.Interval.NonEmpty.Internal" "intervals-0.9.2-1k1J4X7ThQ1BbP07DOiHWI" 'False) (C1 ('MetaCons "I" 'PrefixI 'False) (S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'SourceStrict 'DecidedStrict) (Rec0 a) :*: S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'SourceStrict 'DecidedStrict) (Rec0 a)))
type Rep1 Interval Source # 
Instance details

Defined in Numeric.Interval.NonEmpty.Internal

type Rep1 Interval = D1 ('MetaData "Interval" "Numeric.Interval.NonEmpty.Internal" "intervals-0.9.2-1k1J4X7ThQ1BbP07DOiHWI" 'False) (C1 ('MetaCons "I" 'PrefixI 'False) (S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'SourceStrict 'DecidedStrict) Par1 :*: S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'SourceStrict 'DecidedStrict) Par1))

(...) :: Ord a => a -> a -> Interval a infix 3 Source #

Create a non-empty interval, turning it around if necessary

interval :: Ord a => a -> a -> Maybe (Interval a) Source #

Try to create a non-empty interval.

whole :: Fractional a => Interval a Source #

The whole real number line

>>> whole
-Infinity ... Infinity
(x :: Double) `elem` whole

singleton :: a -> Interval a Source #

A singleton point

>>> singleton 1
1 ... 1
x `elem` (singleton x)
x /= y ==> y `notElem` (singleton x)

member :: Ord a => a -> Interval a -> Bool Source #

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

notMember :: Ord a => a -> Interval a -> Bool Source #

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

elem :: Ord a => a -> Interval a -> Bool Source #

Deprecated: Use member instead.

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

notElem :: Ord a => a -> Interval a -> Bool Source #

Deprecated: Use notMember 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

inf :: Interval a -> a Source #

The infinumum (lower bound) of an interval

>>> inf (1 ... 20)
1
min x y == inf (x ... y)
inf x <= sup x

sup :: Interval a -> a Source #

The supremum (upper bound) of an interval

>>> sup (1 ... 20)
20
sup x `elem` x
max x y == sup (x ... y)
inf x <= sup x

singular :: Ord a => Interval a -> Bool Source #

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

width :: Num a => Interval a -> a Source #

Calculate the width of an interval.

>>> width (1 ... 20)
19
>>> width (singleton 1)
0
0 <= width x

midpoint :: Fractional a => Interval a -> a Source #

Nearest point to the midpoint of the interval.

>>> midpoint (10.0 ... 20.0)
15.0
>>> midpoint (singleton 5.0)
5.0
midpoint x `elem` (x :: Interval Double)

distance :: (Num a, Ord a) => Interval a -> Interval a -> a Source #

Hausdorff distance between intervals.

>>> distance (1 ... 7) (6 ... 10)
0
>>> distance (1 ... 7) (15 ... 24)
8
>>> distance (1 ... 7) (-10 ... -2)
3
commutative (distance :: Interval Double -> Interval Double -> Double)
0 <= distance x y

intersection :: Ord a => Interval a -> Interval a -> Maybe (Interval a) Source #

Calculate the intersection of two intervals.

>>> intersection (1 ... 10 :: Interval Double) (5 ... 15 :: Interval Double)
Just (5.0 ... 10.0)

hull :: Ord a => Interval a -> Interval a -> Interval a Source #

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
conservative2 const hull
conservative2 (flip const) hull

bisect :: Fractional a => Interval a -> (Interval a, Interval a) Source #

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)
let (a, b) = bisect (x :: Interval Double) in sup a == inf b
let (a, b) = bisect (x :: Interval Double) in inf a == inf x
let (a, b) = bisect (x :: Interval Double) in sup b == sup x

magnitude :: (Num a, Ord a) => Interval a -> a Source #

Magnitude

>>> magnitude (1 ... 20)
20
>>> magnitude (-20 ... 10)
20
>>> magnitude (singleton 5)
5
0 <= magnitude x

mignitude :: (Num a, Ord a) => Interval a -> a Source #

"mignitude"

>>> mignitude (1 ... 20)
1
>>> mignitude (-20 ... 10)
0
>>> mignitude (singleton 5)
5
0 <= mignitude x

contains :: Ord a => Interval a -> Interval a -> Bool Source #

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

isSubsetOf :: Ord a => Interval a -> Interval a -> Bool Source #

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

certainly :: Ord a => (forall b. Ord b => b -> b -> Bool) -> Interval a -> Interval a -> Bool Source #

For all x in X, y in Y. x op y

(<!) :: Ord a => Interval a -> Interval a -> Bool Source #

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 Source #

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

(==!) :: Eq a => Interval a -> Interval a -> Bool Source #

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

(/=!) :: Ord a => Interval a -> Interval a -> Bool Source #

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 Source #

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 Source #

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

possibly :: Ord a => (forall b. Ord b => b -> b -> Bool) -> Interval a -> Interval a -> Bool Source #

Does there exist an x in X, y in Y such that x op y?

(<?) :: Ord a => Interval a -> Interval a -> Bool Source #

Does there exist an x in X, y in Y such that x < y?

(<=?) :: Ord a => Interval a -> Interval a -> Bool Source #

Does there exist an x in X, y in Y such that x <= y?

(==?) :: Ord a => Interval a -> Interval a -> Bool Source #

Does there exist an x in X, y in Y such that x == y?

(/=?) :: Eq a => Interval a -> Interval a -> Bool Source #

Does there exist an x in X, y in Y such that x /= y?

(>=?) :: Ord a => Interval a -> Interval a -> Bool Source #

Does there exist an x in X, y in Y such that x >= y?

(>?) :: Ord a => Interval a -> Interval a -> Bool Source #

Does there exist an x in X, y in Y such that x > y?

clamp :: Ord a => Interval a -> a -> a Source #

The nearest value to that supplied which is contained in the interval.

(clamp xs y) `elem` xs

inflate :: (Num a, Ord a) => a -> Interval a -> Interval a Source #

Inflate an interval by enlarging it at both ends.

>>> inflate 3 (-1 ... 7)
-4 ... 10
>>> inflate (-2) (0 ... 4)
-2 ... 6
inflate x i `contains` i

deflate :: (Fractional a, Ord a) => a -> Interval a -> Interval a Source #

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

scale :: (Fractional a, Ord a) => a -> Interval a -> Interval a Source #

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
abs x >= 1 ==> (scale (x :: Double) i) `contains` i
forAll (choose (0,1)) $ \x -> abs x <= 1 ==> i `contains` (scale (x :: Double) i)

symmetric :: (Num a, Ord a) => a -> Interval a Source #

Construct a symmetric interval.

>>> symmetric 3
-3 ... 3
>>> symmetric (-2)
-2 ... 2
x `elem` symmetric x
0 `elem` symmetric x

idouble :: Interval Double -> Interval Double Source #

id function. Useful for type specification

>>> :t idouble (1 ... 3)
idouble (1 ... 3) :: Interval Double

ifloat :: Interval Float -> Interval Float Source #

id function. Useful for type specification

>>> :t ifloat (1 ... 3)
ifloat (1 ... 3) :: Interval Float

iquot :: Integral a => Interval a -> Interval a -> Interval a Source #

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

irem :: Integral a => Interval a -> Interval a -> Interval a Source #

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

idiv :: Integral a => Interval a -> Interval a -> Interval a Source #

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

imod :: Integral a => Interval a -> Interval a -> Interval a Source #

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