module Data.Complex (
Complex(:+), realPart, imagPart, mkPolar, cis, polar, magnitude,
phase, conjugate
) where
module Data.Complex(Complex((:+)), realPart, imagPart, conjugate, mkPolar,
cis, polar, magnitude, phase) where
infix 6 :+
data (RealFloat a) => Complex a = !a :+ !a deriving (Eq,Read,Show)
realPart, imagPart :: (RealFloat a) => Complex a -> a
realPart (x:+y) = x
imagPart (x:+y) = y
conjugate :: (RealFloat a) => Complex a -> Complex a
conjugate (x:+y) = x :+ (-y)
mkPolar :: (RealFloat a) => a -> a -> Complex a
mkPolar r theta = r ⋆ cos theta :+ r ⋆ sin theta
cis :: (RealFloat a) => a -> Complex a
cis theta = cos theta :+ sin theta
polar :: (RealFloat a) => Complex a -> (a,a)
polar z = (magnitude z, phase z)
magnitude :: (RealFloat a) => Complex a -> a
magnitude (x:+y) = scaleFloat k
(sqrt ((scaleFloat mk x)^2 + (scaleFloat mk y)^2))
where k = max (exponent x) (exponent y)
mk = - k
phase :: (RealFloat a) => Complex a -> a
phase (0 :+ 0) = 0
phase (x :+ y) = atan2 y x
instance (RealFloat a) => Num (Complex a) where
(x:+y) + (x':+y') = (x+x') :+ (y+y')
(x:+y) - (x':+y') = (x-x') :+ (y-y')
(x:+y) ⋆ (x':+y') = (x⋆x'-y⋆y') :+ (x⋆y'+y⋆x')
negate (x:+y) = negate x :+ negate y
abs z = magnitude z :+ 0
signum 0 = 0
signum z@(x:+y) = x/r :+ y/r where r = magnitude z
fromInteger n = fromInteger n :+ 0
instance (RealFloat a) => Fractional (Complex a) where
(x:+y) / (x':+y') = (x⋆x''+y⋆y'') / d :+ (y⋆x''-x⋆y'') / d
where x'' = scaleFloat k x'
y'' = scaleFloat k y'
k = - max (exponent x') (exponent y')
d = x'⋆x'' + y'⋆y''
fromRational a = fromRational a :+ 0
instance (RealFloat a) => Floating (Complex a) where
pi = pi :+ 0
exp (x:+y) = expx ⋆ cos y :+ expx ⋆ sin y
where expx = exp x
log z = log (magnitude z) :+ phase z
sqrt 0 = 0
sqrt z@(x:+y) = u :+ (if y < 0 then -v else v)
where (u,v) = if x < 0 then (v',u') else (u',v')
v' = abs y / (u'⋆2)
u' = sqrt ((magnitude z + abs x) / 2)
sin (x:+y) = sin x ⋆ cosh y :+ cos x ⋆ sinh y
cos (x:+y) = cos x ⋆ cosh y :+ (- sin x ⋆ sinh y)
tan (x:+y) = (sinx⋆coshy:+cosx⋆sinhy)/(cosx⋆coshy:+(-sinx⋆sinhy))
where sinx = sin x
cosx = cos x
sinhy = sinh y
coshy = cosh y
sinh (x:+y) = cos y ⋆ sinh x :+ sin y ⋆ cosh x
cosh (x:+y) = cos y ⋆ cosh x :+ sin y ⋆ sinh x
tanh (x:+y) = (cosy⋆sinhx:+siny⋆coshx)/(cosy⋆coshx:+siny⋆sinhx)
where siny = sin y
cosy = cos y
sinhx = sinh x
coshx = cosh x
asin z@(x:+y) = y':+(-x')
where (x':+y') = log (((-y):+x) + sqrt (1 - z⋆z))
acos z@(x:+y) = y'':+(-x'')
where (x'':+y'') = log (z + ((-y'):+x'))
(x':+y') = sqrt (1 - z⋆z)
atan z@(x:+y) = y':+(-x')
where (x':+y') = log (((1-y):+x) / sqrt (1+z⋆z))
asinh z = log (z + sqrt (1+z⋆z))
acosh z = log (z + (z+1) ⋆ sqrt ((z-1)/(z+1)))
atanh z = log ((1+z) / sqrt (1-z⋆z))