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emacs/lisp/color.el
2011-01-15 00:35:35 +00:00

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;;; color.el --- Color manipulation laboratory routines -*- coding: utf-8; -*-
;; Copyright (C) 2010, 2011 Free Software Foundation, Inc.
;; Author: Julien Danjou <julien@danjou.info>
;; Keywords: html
;; This file is part of GNU Emacs.
;; GNU Emacs is free software: you can redistribute it and/or modify
;; it under the terms of the GNU General Public License as published by
;; the Free Software Foundation, either version 3 of the License, or
;; (at your option) any later version.
;; GNU Emacs is distributed in the hope that it will be useful,
;; but WITHOUT ANY WARRANTY; without even the implied warranty of
;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
;; GNU General Public License for more details.
;; You should have received a copy of the GNU General Public License
;; along with GNU Emacs. If not, see <http://www.gnu.org/licenses/>.
;;; Commentary:
;; This package provides color manipulation functions.
;;; Code:
(eval-when-compile
(require 'cl))
;; Emacs < 23.3
(eval-and-compile
(unless (boundp 'float-pi)
(defconst float-pi (* 4 (atan 1)) "The value of Pi (3.1415926...).")))
(defun color-rgb->hex (red green blue)
"Return hexadecimal notation for RED GREEN BLUE color.
RED GREEN BLUE must be values between 0 and 1 inclusively."
(format "#%02x%02x%02x"
(* red 255) (* green 255) (* blue 255)))
(defun color-complement (color)
"Return the color that is the complement of COLOR."
(let ((color (color-rgb->normalize color)))
(list (- 1.0 (car color))
(- 1.0 (cadr color))
(- 1.0 (caddr color)))))
(defun color-complement-hex (color)
"Return the color that is the complement of COLOR, in hexadecimal format."
(apply 'color-rgb->hex (color-complement color)))
(defun color-rgb->hsv (red green blue)
"Convert RED GREEN BLUE values to HSV representation.
Hue is in radians. Saturation and values are between 0 and 1
inclusively."
(let* ((r (float red))
(g (float green))
(b (float blue))
(max (max r g b))
(min (min r g b)))
(list
(/ (* 2 float-pi
(cond ((and (= r g) (= g b)) 0)
((and (= r max)
(>= g b))
(* 60 (/ (- g b) (- max min))))
((and (= r max)
(< g b))
(+ 360 (* 60 (/ (- g b) (- max min)))))
((= max g)
(+ 120 (* 60 (/ (- b r) (- max min)))))
((= max b)
(+ 240 (* 60 (/ (- r g) (- max min)))))))
360)
(if (= max 0)
0
(- 1 (/ min max)))
(/ max 255.0))))
(defun color-rgb->hsl (red green blue)
"Convert RED GREEN BLUE colors to their HSL representation.
RED, GREEN and BLUE must be between 0 and 1 inclusively."
(let* ((r red)
(g green)
(b blue)
(max (max r g b))
(min (min r g b))
(delta (- max min))
(l (/ (+ max min) 2.0)))
(list
(if (= max min)
0
(* 2 float-pi
(/ (cond ((= max r)
(+ (/ (- g b) delta) (if (< g b) 6 0)))
((= max g)
(+ (/ (- b r) delta) 2))
(t
(+ (/ (- r g) delta) 4)))
6)))
(if (= max min)
0
(if (> l 0.5)
(/ delta (- 2 (+ max min)))
(/ delta (+ max min))))
l)))
(defun color-srgb->xyz (red green blue)
"Converts RED GREEN BLUE colors from the sRGB color space to CIE XYZ.
RED, BLUE and GREEN must be between 0 and 1 inclusively."
(let ((r (if (<= red 0.04045)
(/ red 12.95)
(expt (/ (+ red 0.055) 1.055) 2.4)))
(g (if (<= green 0.04045)
(/ green 12.95)
(expt (/ (+ green 0.055) 1.055) 2.4)))
(b (if (<= blue 0.04045)
(/ blue 12.95)
(expt (/ (+ blue 0.055) 1.055) 2.4))))
(list (+ (* 0.4124564 r) (* 0.3575761 g) (* 0.1804375 b))
(+ (* 0.21266729 r) (* 0.7151522 g) (* 0.0721750 b))
(+ (* 0.0193339 r) (* 0.1191920 g) (* 0.9503041 b)))))
(defun color-xyz->srgb (X Y Z)
"Converts CIE X Y Z colors to sRGB color space."
(let ((r (+ (* 3.2404542 X) (* -1.5371385 Y) (* -0.4985314 Z)))
(g (+ (* -0.9692660 X) (* 1.8760108 Y) (* 0.0415560 Z)))
(b (+ (* 0.0556434 X) (* -0.2040259 Y) (* 1.0572252 Z))))
(list (if (<= r 0.0031308)
(* 12.92 r)
(- (* 1.055 (expt r (/ 1 2.4))) 0.055))
(if (<= g 0.0031308)
(* 12.92 g)
(- (* 1.055 (expt g (/ 1 2.4))) 0.055))
(if (<= b 0.0031308)
(* 12.92 b)
(- (* 1.055 (expt b (/ 1 2.4))) 0.055)))))
(defconst color-d65-xyz '(0.950455 1.0 1.088753)
"D65 white point in CIE XYZ.")
(defconst color-cie-ε (/ 216 24389.0))
(defconst color-cie-κ (/ 24389 27.0))
(defun color-xyz->lab (X Y Z &optional white-point)
"Converts CIE XYZ to CIE L*a*b*.
WHITE-POINT can be specified as (X Y Z) white point to use. If
none is set, `color-d65-xyz' is used."
(destructuring-bind (Xr Yr Zr) (or white-point color-d65-xyz)
(let* ((xr (/ X Xr))
(yr (/ Y Yr))
(zr (/ Z Zr))
(fx (if (> xr color-cie-ε)
(expt xr (/ 1 3.0))
(/ (+ (* color-cie-κ xr) 16) 116.0)))
(fy (if (> yr color-cie-ε)
(expt yr (/ 1 3.0))
(/ (+ (* color-cie-κ yr) 16) 116.0)))
(fz (if (> zr color-cie-ε)
(expt zr (/ 1 3.0))
(/ (+ (* color-cie-κ zr) 16) 116.0))))
(list
(- (* 116 fy) 16) ; L
(* 500 (- fx fy)) ; a
(* 200 (- fy fz)))))) ; b
(defun color-lab->xyz (L a b &optional white-point)
"Converts CIE L*a*b* to CIE XYZ.
WHITE-POINT can be specified as (X Y Z) white point to use. If
none is set, `color-d65-xyz' is used."
(destructuring-bind (Xr Yr Zr) (or white-point color-d65-xyz)
(let* ((fy (/ (+ L 16) 116.0))
(fz (- fy (/ b 200.0)))
(fx (+ (/ a 500.0) fy))
(xr (if (> (expt fx 3.0) color-cie-ε)
(expt fx 3.0)
(/ (- (* fx 116) 16) color-cie-κ)))
(yr (if (> L (* color-cie-κ color-cie-ε))
(expt (/ (+ L 16) 116.0) 3.0)
(/ L color-cie-κ)))
(zr (if (> (expt fz 3) color-cie-ε)
(expt fz 3.0)
(/ (- (* 116 fz) 16) color-cie-κ))))
(list (* xr Xr) ; X
(* yr Yr) ; Y
(* zr Zr))))) ; Z
(defun color-srgb->lab (red green blue)
"Converts RGB to CIE L*a*b*."
(apply 'color-xyz->lab (color-srgb->xyz red green blue)))
(defun color-rgb->normalize (color)
"Normalize a RGB color to values between 0 and 1 inclusively."
(mapcar (lambda (x) (/ x 65535.0)) (x-color-values color)))
(defun color-lab->srgb (L a b)
"Converts CIE L*a*b* to RGB."
(apply 'color-xyz->srgb (color-lab->xyz L a b)))
(defun color-cie-de2000 (color1 color2 &optional kL kC kH)
"Computes the CIEDE2000 color distance between COLOR1 and COLOR2.
Colors must be in CIE L*a*b* format."
(destructuring-bind (L a b) color1
(destructuring-bind (L a b) color2
(let* ((kL (or kL 1))
(kC (or kC 1))
(kH (or kH 1))
(C (sqrt (+ (expt a 2.0) (expt b 2.0))))
(C (sqrt (+ (expt a 2.0) (expt b 2.0))))
( (/ (+ C C) 2.0))
(G (* 0.5 (- 1 (sqrt (/ (expt 7.0) (+ (expt 7.0) (expt 25 7.0)))))))
(a (* (+ 1 G) a))
(a (* (+ 1 G) a))
(C (sqrt (+ (expt a 2.0) (expt b 2.0))))
(C (sqrt (+ (expt a 2.0) (expt b 2.0))))
(h (if (and (= b 0) (= a 0))
0
(let ((v (atan b a)))
(if (< v 0)
(+ v (* 2 float-pi))
v))))
(h (if (and (= b 0) (= a 0))
0
(let ((v (atan b a)))
(if (< v 0)
(+ v (* 2 float-pi))
v))))
(ΔL (- L L))
(ΔC (- C C))
(Δh (cond ((= (* C C) 0)
0)
((<= (abs (- h h)) float-pi)
(- h h))
((> (- h h) float-pi)
(- (- h h) (* 2 float-pi)))
((< (- h h) (- float-pi))
(+ (- h h) (* 2 float-pi)))))
(ΔH (* 2 (sqrt (* C C)) (sin (/ Δh 2.0))))
( (/ (+ L L) 2.0))
( (/ (+ C C) 2.0))
( (cond ((= (* C C) 0)
(+ h h))
((<= (abs (- h h)) float-pi)
(/ (+ h h) 2.0))
((< (+ h h) (* 2 float-pi))
(/ (+ h h (* 2 float-pi)) 2.0))
((>= (+ h h) (* 2 float-pi))
(/ (+ h h (* -2 float-pi)) 2.0))))
(T (+ 1
(- (* 0.17 (cos (- (degrees-to-radians 30)))))
(* 0.24 (cos (* 2)))
(* 0.32 (cos (+ (* 3) (degrees-to-radians 6))))
(- (* 0.20 (cos (- (* 4) (degrees-to-radians 63)))))))
(Δθ (* (degrees-to-radians 30) (exp (- (expt (/ (- (degrees-to-radians 275)) (degrees-to-radians 25)) 2.0)))))
(Rc (* 2 (sqrt (/ (expt 7.0) (+ (expt 7.0) (expt 25.0 7.0))))))
(Sl (+ 1 (/ (* 0.015 (expt (- 50) 2.0)) (sqrt (+ 20 (expt (- 50) 2.0))))))
(Sc (+ 1 (* 0.045)))
(Sh (+ 1 (* 0.015 T)))
(Rt (- (* (sin (* Δθ 2)) Rc))))
(sqrt (+ (expt (/ ΔL (* Sl kL)) 2.0)
(expt (/ ΔC (* Sc kC)) 2.0)
(expt (/ ΔH (* Sh kH)) 2.0)
(* Rt (/ ΔC (* Sc kC)) (/ ΔH (* Sh kH)))))))))
(provide 'color)
;;; color.el ends here