module Complex(Floating(..)) where import DComplex import Magnitude import Phase import Fractional_Complex import Num_Complex 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))