Data/Colour/CIE.hs

{-
Copyright (c) 2008, 2009
Russell O'Connor

Permission is hereby granted, free of charge, to any person obtaining a copy
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The above copyright notice and this permission notice shall be included in
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THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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-}
-- |Colour operations defined by the International Commission on 
-- Illumination (CIE).
module Data.Colour.CIE
 (Colour
 ,cieXYZ, cieXYZView, luminance
 ,toCIEXYZ -- depricated

 ,Chromaticity
 ,mkChromaticity, chromaCoords
 ,chromaX, chromaY, chromaZ
 ,chromaConvert
 ,chromaColour

 ,lightness, cieLABView, cieLAB --cieLuv
 )
where

import Data.List
import Data.Colour
import Data.Colour.RGB
import Data.Colour.SRGB.Linear
import Data.Colour.CIE.Chromaticity
import Data.Colour.Matrix

-- |Construct a 'Colour' from XYZ coordinates for the 2&#176; standard
-- (colourimetric) observer.
cieXYZ :: (Fractional a) => a -> a -> a -> Colour a
cieXYZ x y z = rgb r g b
 where
  [r,g,b] = mult matrix [x,y,z]
  matrix = map (map fromRational) xyz2rgb709

-- |Returns the XYZ colour coordinates for the 2&#176; standard
-- (colourimetric) observer.
cieXYZView :: (Fractional a) => Colour a -> (a,a,a)
cieXYZView c = (x,y,z)
 where
  RGB r g b = toRGB c
  [x,y,z] = mult matrix [r,g,b]
  matrix = map (map fromRational) rgb7092xyz

{-# DEPRECATED toCIEXYZ "`toCIEXYZ' has been renamed `cieXYZView'" #-}
toCIEXYZ x = cieXYZView x

{- CIE luminance -}
-- |Returns the Y colour coordinate (luminance) for the 2&#176; standard
-- (colourimetric) observer.
luminance :: (Fractional a) => Colour a -> a
luminance c = y
 where
  (x,y,z) = toCIEXYZ c

instance AffineSpace Chromaticity where
 affineCombo l z =
   foldl1' chromaAdd [chromaScale w a | (w,a) <- (1-total,z):l]
  where
   total = sum $ map fst l
   (Chroma x0 y0) `chromaAdd` (Chroma x1 y1) = Chroma (x0+x1) (y0+y1)
   s `chromaScale` (Chroma x y) = Chroma (s*x) (s*y)

-- |Constructs a colour from the given 'Chromaticity' and 'luminance'.
chromaColour :: (Fractional a) =>
                Chromaticity a
             -> a              -- ^ 'luminance'
             -> Colour a
chromaColour ch y = cieXYZ (s*ch_x) y (s*ch_z)
 where
  (ch_x, ch_y, ch_z) = chromaCoords ch
  s = y/ch_y

-- |Returns the lightness of a colour with respect to a given white point.
-- Lightness is a perceptually uniform measure.
lightness :: (Ord a, Floating a) => Chromaticity a -- ^White point
                                 -> Colour a -> a
lightness white_ch c | (6/29)^3 < y' = 116*y'**(1/3) - 16
                     | otherwise = (29/3)^3*y'
 where
  white = chromaColour white_ch 1.0
  y' = (luminance c/luminance white)

-- |Returns the CIELAB coordinates of a colour, which is a
-- perceptually uniform colour space.
-- The first coordinate is 'lightness'.
-- If you don't know what white point to use, use
-- 'Data.Colour.CIE.Illuminant.d65'.
cieLABView :: (Ord a, Floating a) => Chromaticity a -- ^White point
                              -> Colour a -> (a,a,a)
cieLABView white_ch c = (lightness white_ch c, a, b)
 where
  white = chromaColour white_ch 1.0
  (x,y,z) = toCIEXYZ c
  (xn,yn,zn) = toCIEXYZ white
  (fx, fy, fz) = (f (x/xn), f (y/yn), f (z/zn))
  a = 500*(fx - fy)
  b = 200*(fy - fz)
  f x | (6/29)^3 < x = x**(1/3)
      | otherwise = 841/108*x + 4/29

-- |Returns the colour for given CIELAB coordinates, which is a
-- perceptually uniform colour space.
-- If you don't know what white point to use, use
-- 'Data.Colour.CIE.Illuminant.d65'.
cieLAB :: (Ord a, Floating a) => Chromaticity a -- ^White point
                              -> a              -- ^L* coordinate (lightness)
                              -> a              -- ^a* coordinate
                              -> a              -- ^b* coordinate
                              -> Colour a
cieLAB white_ch l a b = cieXYZ (xn*transform fx)
                               (yn*transform fy)
                               (zn*transform fz)
 where
  white = chromaColour white_ch 1.0
  (xn,yn,zn) = toCIEXYZ white
  fx = fy + a/500
  fy = (l + 16)/116
  fz = fy - b/200
  delta = 6/29
  transform fa | fa > delta = fa^3
               | otherwise = (fa - 16/116)*3*delta^2

-- |Returns the CIELUV coordinates of a colour, which is a
-- perceptually uniform colour space.
-- If you don't know what white point to use, use
-- 'Data.Colour.CIE.Illuminant.d65'.
cieLuv :: (Ord a, Floating a) => Chromaticity a -- ^White point
                              -> Colour a -> (a,a,a)
cieLuv white_ch c = (l, 13*l*(u'-un'), 13*l*(v'-vn'))
 where
  white = chromaColour white_ch 1.0
  (u', v') = u'v' c
  (un', vn') = u'v' white
  l = lightness white_ch c
--------------------------------------------------------------------------
{- not for export -}
u'v' :: (Ord a, Floating a) => Colour a -> (a,a)
u'v' c = (4*x/(x+15*y+3*z), 9*y/(x+15*y+3*z))
 where
  (x,y,z) = toCIEXYZ c

rgb7092xyz = (rgb2xyz sRGBGamut)

xyz2rgb709 = inverse rgb7092xyz