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/*************************************************************************
* Copyright (C) 2009-2010 Tavian Barnes <tavianator@gmail.com> *
* *
* This file is part of The Dimension Library. *
* *
* The Dimension Library is free software; you can redistribute it and/ *
* or modify it under the terms of the GNU Lesser General Public License *
* as published by the Free Software Foundation; either version 3 of the *
* License, or (at your option) any later version. *
* *
* The Dimension Library 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 *
* Lesser General Public License for more details. *
* *
* You should have received a copy of the GNU Lesser General Public *
* License along with this program. If not, see *
* <http://www.gnu.org/licenses/>. *
*************************************************************************/
#include "dimension.h"
#include <math.h> /* For pow(), sqrt() */
/* sRGB white point (CIE D50) */
const dmnsn_CIE_XYZ dmnsn_whitepoint = { .X = 0.9504060171449392,
.Y = 0.9999085943425312,
.Z = 1.089062231497274 };
/* Standard colors */
const dmnsn_color dmnsn_black = {
.R = 0.0,
.G = 0.0,
.B = 0.0,
.filter = 0.0,
.trans = 0.0
};
const dmnsn_color dmnsn_white = {
.R = 1.0,
.G = 1.0,
.B = 1.0,
.filter = 0.0,
.trans = 0.0
};
const dmnsn_color dmnsn_red = {
.R = 1.0,
.G = 0.0,
.B = 0.0,
.filter = 0.0,
.trans = 0.0
};
const dmnsn_color dmnsn_green = {
.R = 0.0,
.G = 1.0,
.B = 0.0,
.filter = 0.0,
.trans = 0.0
};
const dmnsn_color dmnsn_blue = {
.R = 0.0,
.G = 0.0,
.B = 1.0,
.filter = 0.0,
.trans = 0.0
};
const dmnsn_color dmnsn_magenta = {
.R = 1.0,
.G = 0.0,
.B = 1.0,
.filter = 0.0,
.trans = 0.0
};
const dmnsn_color dmnsn_yellow = {
.R = 1.0,
.G = 1.0,
.B = 0.0,
.filter = 0.0,
.trans = 0.0
};
const dmnsn_color dmnsn_cyan = {
.R = 0.0,
.G = 1.0,
.B = 1.0,
.filter = 0.0,
.trans = 0.0
};
bool
dmnsn_color_is_black(dmnsn_color color)
{
return color.R == 0.0 && color.G == 0.0 && color.B == 0.0;
}
/* sRGB's `C' function */
static double dmnsn_sRGB_C(double Clinear) {
/*
* If C represents R, G, and B, then the sRGB values are now found as follows:
*
* { 12.92*Clinear, Clinear <= 0.0031308
* Csrgb = { 1/2.4
* { (1.055)*Clinear - 0.055, Clinear > 0.0031308
*/
if (Clinear <= 0.0031308) {
return 12.92*Clinear;
} else {
return 1.055*pow(Clinear, 1.0/2.4) - 0.055;
}
}
/* Convert a CIE XYZ color to a dmnsn_color */
dmnsn_color
dmnsn_color_from_XYZ(dmnsn_CIE_XYZ XYZ)
{
dmnsn_color color = {
.R = 3.2410*XYZ.X - 1.5374*XYZ.Y - 0.4986*XYZ.Z,
.G = -0.9692*XYZ.X + 1.8760*XYZ.Y + 0.0416*XYZ.Z,
.B = 0.0556*XYZ.X - 0.2040*XYZ.Y + 1.0570*XYZ.Z,
.filter = 0.0,
.trans = 0.0
};
color.R = dmnsn_sRGB_C(color.R);
color.G = dmnsn_sRGB_C(color.G);
color.B = dmnsn_sRGB_C(color.B);
return color;
}
/* Convert a CIE xyY color to a dmnsn_color */
dmnsn_color
dmnsn_color_from_xyY(dmnsn_CIE_xyY xyY)
{
dmnsn_CIE_XYZ ret = {
.X = xyY.Y*xyY.x/xyY.y,
.Y = xyY.Y,
.Z = xyY.Y*(1.0 - xyY.x - xyY.y)/xyY.y,
};
return dmnsn_color_from_XYZ(ret);
}
/* Inverse function of CIE L*a*b*'s `f' function, for the reverse conversion */
static double dmnsn_Lab_finv(double t) {
if (t > 6.0/29.0) {
return t*t*t;
} else {
return 108.0*(t - 16.0/116.0)/841.0;
}
}
/* Convert a CIE L*a*b* color to a dmnsn_color, relative to the given
whitepoint. */
dmnsn_color
dmnsn_color_from_Lab(dmnsn_CIE_Lab Lab, dmnsn_CIE_XYZ white)
{
double fx, fy, fz;
dmnsn_CIE_XYZ ret;
fy = (Lab.L + 16.0)/116.0;
fx = fy + Lab.a/500.0;
fz = fy - Lab.b/200.0;
ret.X = white.X*dmnsn_Lab_finv(fx);
ret.Y = white.Y*dmnsn_Lab_finv(fy);
ret.Z = white.Z*dmnsn_Lab_finv(fz);
return dmnsn_color_from_XYZ(ret);
}
/* Convert a CIE L*u*v* color to a dmnsn_color, relative to the given
whitepoint. */
dmnsn_color
dmnsn_color_from_Luv(dmnsn_CIE_Luv Luv, dmnsn_CIE_XYZ white)
{
double fy;
double uprime, unprime, vprime, vnprime;
dmnsn_CIE_XYZ ret;
fy = (Luv.L + 16.0)/116.0;
unprime = 4.0*white.X/(white.X + 15.0*white.Y + 3.0*white.Z);
uprime = Luv.u/Luv.L/13.0 + unprime;
vnprime = 9.0*white.Y/(white.X + 15.0*white.Y + 3.0*white.Z);
vprime = Luv.v/Luv.L/13.0 + vnprime;
ret.Y = white.Y*dmnsn_Lab_finv(fy);
ret.X = ret.Y*9.0*uprime/vprime/4.0;
ret.Z = ret.Y*(12.0 - 3*uprime - 20*vprime)/vprime/4.0;
return dmnsn_color_from_XYZ(ret);
}
/* Convert an sRGB color to a dmnsn_color (actually a no-op) */
dmnsn_color
dmnsn_color_from_sRGB(dmnsn_sRGB sRGB)
{
dmnsn_color ret = {
.R = sRGB.R,
.G = sRGB.G,
.B = sRGB.B,
.filter = 0.0,
.trans = 0.0
};
return ret;
}
/* Inverse function of sRGB's `C' function, for the reverse conversion */
static double dmnsn_sRGB_Cinv(double CsRGB) {
/*
* If C represents R, G, and B, then the Clinear values are now found as
* follows:
*
* { Csrgb/12.92, Csrgb <= 0.04045
* Clinear = { 1/2.4
* { ((Csrgb + 0.055)/1.055) , Csrgb > 0.04045
*/
if (CsRGB <= 0.040449936) {
return CsRGB/12.92;
} else {
return pow((CsRGB + 0.055)/1.055, 2.4);
}
}
/* Convert a dmnsn_color to a CIE XYZ color */
dmnsn_CIE_XYZ
dmnsn_XYZ_from_color(dmnsn_color color)
{
color.R = dmnsn_sRGB_Cinv(color.R);
color.G = dmnsn_sRGB_Cinv(color.G);
color.B = dmnsn_sRGB_Cinv(color.B);
dmnsn_CIE_XYZ ret = {
.X = 0.4123808838268995*color.R + 0.3575728355732478*color.G
+ 0.1804522977447919*color.B,
.Y = 0.2126198631048975*color.R + 0.7151387878413206*color.G
+ 0.0721499433963131*color.B,
.Z = 0.0193434956789248*color.R + 0.1192121694056356*color.G
+ 0.9505065664127130*color.B,
};
return ret;
}
/* Convert a dmnsn_color to a CIE xyY color */
dmnsn_CIE_xyY
dmnsn_xyY_from_color(dmnsn_color color)
{
dmnsn_CIE_XYZ XYZ = dmnsn_XYZ_from_color(color);
dmnsn_CIE_xyY ret = {
.x = XYZ.X/(XYZ.X + XYZ.Y + XYZ.Z),
.y = XYZ.Y/(XYZ.X + XYZ.Y + XYZ.Z),
.Y = XYZ.Y
};
return ret;
}
/* CIE L*a*b*'s `f' function */
static double dmnsn_Lab_f(double t) {
if (t > 216.0/24389.0) {
return pow(t, 1.0/3.0);
} else {
return 841.0*t/108.0 + 4.0/29.0;
}
}
/* Convert a dmnsn_color to a CIE L*a*b* color, relative to the given
whitepoint */
dmnsn_CIE_Lab
dmnsn_Lab_from_color(dmnsn_color color, dmnsn_CIE_XYZ white)
{
dmnsn_CIE_XYZ XYZ = dmnsn_XYZ_from_color(color);
dmnsn_CIE_Lab ret;
ret.L = 116.0*dmnsn_Lab_f(XYZ.Y/white.Y) - 16.0;
ret.a = 500.0*(dmnsn_Lab_f(XYZ.X/white.X) - dmnsn_Lab_f(XYZ.Y/white.Y));
ret.b = 200.0*(dmnsn_Lab_f(XYZ.Y/white.Y) - dmnsn_Lab_f(XYZ.Z/white.Z));
return ret;
}
/* Convert a dmnsn_color to a CIE L*u*v* color, relative to the given
whitepoint */
dmnsn_CIE_Luv
dmnsn_Luv_from_color(dmnsn_color color, dmnsn_CIE_XYZ white)
{
dmnsn_CIE_XYZ XYZ = dmnsn_XYZ_from_color(color);
double uprime, unprime, vprime, vnprime;
dmnsn_CIE_Luv ret;
uprime = 4.0*XYZ.X / (XYZ.X + 15.0*XYZ.Y + 3.0*XYZ.Z);
unprime = 4.0*white.X / (white.X + 15.0*white.Y + 3.0*white.Z);
vprime = 9.0*XYZ.Y / (XYZ.X + 15.0*XYZ.Y + 3.0*XYZ.Z);
vnprime = 9.0*white.Y / (white.X + 15.0*white.Y + 3.0*white.Z);
ret.L = 116.0*dmnsn_Lab_f(XYZ.Y/white.Y) - 16.0;
ret.u = 13.0*ret.L*(uprime - unprime);
ret.v = 13.0*ret.L*(vprime - vnprime);
return ret;
}
/* Convert a dmnsn_color to an sRGB color (actually a no-op) */
dmnsn_sRGB
dmnsn_sRGB_from_color(dmnsn_color color)
{
dmnsn_sRGB sRGB = { .R = color.R, .G = color.G, .B = color.B };
return sRGB;
}
static double
dmnsn_color_intensity(dmnsn_color color)
{
dmnsn_sRGB sRGB = dmnsn_sRGB_from_color(color);
return 0.2126198631048975*sRGB.R + 0.7151387878413206*sRGB.G
+ 0.0721499433963131*sRGB.B;
}
/* Add two colors */
dmnsn_color
dmnsn_color_add(dmnsn_color c1, dmnsn_color c2)
{
dmnsn_sRGB sRGB1 = dmnsn_sRGB_from_color(c1);
dmnsn_sRGB sRGB2 = dmnsn_sRGB_from_color(c2);
dmnsn_sRGB sRGB = {
.R = sRGB1.R + sRGB2.R,
.G = sRGB1.G + sRGB2.G,
.B = sRGB1.B + sRGB2.B
};
dmnsn_color ret = dmnsn_color_from_sRGB(sRGB);
/* Weighted average of transparencies by intensity */
double L1 = dmnsn_color_intensity(c1)*(1.0 - c1.filter - c1.trans);
double L2 = dmnsn_color_intensity(c2)*(1.0 - c2.filter - c2.trans);
if (L1 + L2) {
ret.filter = (L1*c1.filter + L2*c2.filter)/(L1 + L2);
ret.trans = (L1*c1.trans + L2*c2.trans) /(L1 + L2);
}
return ret;
}
/* Multiply a color by a scalar */
dmnsn_color
dmnsn_color_mul(double n, dmnsn_color color)
{
dmnsn_sRGB sRGB = dmnsn_sRGB_from_color(color);
sRGB.R *= n;
sRGB.G *= n;
sRGB.B *= n;
dmnsn_color ret = dmnsn_color_from_sRGB(sRGB);
ret.filter = color.filter;
ret.trans = color.trans;
return ret;
}
/* For n in [0, 1] get the color in a gradient between c1 and c2 */
dmnsn_color
dmnsn_color_gradient(dmnsn_color c1, dmnsn_color c2, double n)
{
dmnsn_sRGB sRGB1 = dmnsn_sRGB_from_color(c1);
dmnsn_sRGB sRGB2 = dmnsn_sRGB_from_color(c2);
dmnsn_sRGB sRGB = {
.R = n*(sRGB2.R - sRGB1.R) + sRGB1.R,
.G = n*(sRGB2.G - sRGB1.G) + sRGB1.G,
.B = n*(sRGB2.B - sRGB1.B) + sRGB1.B
};
dmnsn_color ret = dmnsn_color_from_sRGB(sRGB);
ret.filter = n*(c2.filter - c1.filter) + c1.filter;
ret.trans = n*(c2.trans - c1.trans) + c1.trans;
return ret;
}
/* Filters `color' through `filter' */
dmnsn_color
dmnsn_color_filter(dmnsn_color color, dmnsn_color filter)
{
dmnsn_color transmitted = dmnsn_color_mul(filter.trans, color);
dmnsn_color filtered = dmnsn_color_mul(filter.filter,
dmnsn_color_illuminate(filter, color));
dmnsn_color ret = dmnsn_color_add(transmitted, filtered);
ret.filter = filter.filter*(color.filter + color.trans)/2
+ color.filter*(filter.filter + filter.trans)/2;
ret.trans = filter.trans*color.trans;
return ret;
}
/* Illuminates `color' with `light' */
dmnsn_color
dmnsn_color_illuminate(dmnsn_color light, dmnsn_color color)
{
/* We use the sRGB primaries */
dmnsn_sRGB sRGB1 = dmnsn_sRGB_from_color(light);
dmnsn_sRGB sRGB2 = dmnsn_sRGB_from_color(color);
dmnsn_sRGB sRGB = {
.R = sRGB1.R*sRGB2.R,
.G = sRGB1.G*sRGB2.G,
.B = sRGB1.B*sRGB2.B
};
dmnsn_color ret = dmnsn_color_from_sRGB(sRGB);
ret.filter = color.filter;
ret.trans = color.trans;
return ret;
}
/* Find the perceptual difference between two colors, using CIE L*a*b* */
double
dmnsn_color_difference(dmnsn_color color1, dmnsn_color color2)
{
dmnsn_CIE_Lab Lab1, Lab2;
Lab1 = dmnsn_Lab_from_color(color1, dmnsn_whitepoint);
Lab2 = dmnsn_Lab_from_color(color2, dmnsn_whitepoint);
return sqrt((Lab1.L - Lab2.L)*(Lab1.L - Lab2.L)
+ (Lab1.a - Lab2.a)*(Lab1.a - Lab2.a)
+ (Lab1.b - Lab2.b)*(Lab1.b - Lab2.b));
}
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