module Numeric.LAPACK.Scalar (
RealOf,
ComplexOf,
zero,
one,
minusOne,
isZero,
selectReal,
selectFloating,
fromReal,
absolute,
absoluteSquared,
norm1,
realPart,
conjugate,
) where
import Numeric.LAPACK.Wrapper (Flip(Flip, getFlip))
import qualified Numeric.Netlib.Class as Class
import Data.Functor.Identity (Identity(Identity, runIdentity))
import qualified Data.Complex as Complex
import Data.Complex (Complex((:+)))
import Data.Monoid (Endo(Endo,appEndo))
type family RealOf x
type instance RealOf Float = Float
type instance RealOf Double = Double
type instance RealOf (Complex a) = a
type ComplexOf x = Complex (RealOf x)
zero, one, minusOne :: Class.Floating a => a
zero = selectFloating 0 0 0 0
one = selectFloating 1 1 1 1
minusOne = selectFloating (1) (1) (1) (1)
selectReal :: (Class.Real a) => Float -> Double -> a
selectReal rf rd =
runIdentity $ Class.switchReal (Identity rf) (Identity rd)
selectFloating ::
(Class.Floating a) =>
Float -> Double -> Complex Float -> Complex Double -> a
selectFloating rf rd cf cd =
runIdentity $
Class.switchFloating
(Identity rf) (Identity rd) (Identity cf) (Identity cd)
isZero :: Class.Floating a => a -> Bool
isZero =
getFlip $
Class.switchFloating
(Flip (0==)) (Flip (0==))
(Flip (0==)) (Flip (0==))
newtype FromReal a = FromReal {getFromReal :: RealOf a -> a}
fromReal :: (Class.Floating a) => RealOf a -> a
fromReal =
getFromReal $
Class.switchFloating
(FromReal id)
(FromReal id)
(FromReal (:+0))
(FromReal (:+0))
newtype ToReal a = ToReal {getToReal :: a -> RealOf a}
realPart :: (Class.Floating a) => a -> RealOf a
realPart =
getToReal $
Class.switchFloating
(ToReal id)
(ToReal id)
(ToReal Complex.realPart)
(ToReal Complex.realPart)
absolute :: (Class.Floating a) => a -> RealOf a
absolute =
getToReal $
Class.switchFloating
(ToReal abs)
(ToReal abs)
(ToReal Complex.magnitude)
(ToReal Complex.magnitude)
norm1 :: (Class.Floating a) => a -> RealOf a
norm1 =
getToReal $
Class.switchFloating
(ToReal abs)
(ToReal abs)
(ToReal norm1Complex)
(ToReal norm1Complex)
norm1Complex :: (Class.Real a) => Complex a -> a
norm1Complex (r:+i) = abs r + abs i
absoluteSquared :: (Class.Floating a) => a -> RealOf a
absoluteSquared =
getToReal $
Class.switchFloating
(ToReal absoluteSquaredReal)
(ToReal absoluteSquaredReal)
(ToReal absoluteSquaredComplex)
(ToReal absoluteSquaredComplex)
absoluteSquaredReal :: (Class.Real a) => a -> a
absoluteSquaredReal a = a*a
absoluteSquaredComplex :: (Class.Real a) => Complex a -> a
absoluteSquaredComplex (r:+i) = r*r+i*i
conjugate :: (Class.Floating a) => a -> a
conjugate =
appEndo $
Class.switchFloating
(Endo id) (Endo id) (Endo Complex.conjugate) (Endo Complex.conjugate)