Просмотр исходного кода
color: implement HSV to RGB transformation and a CIEDE2000 distance
function for CIE L*a*b* values.legacy
sam
1 измененных файлов: 128 добавлений и 48 удалений
-
+128 -48src/lol/image/color.h
+ 128
- 48
src/lol/image/color.h
Просмотреть файл
| @@ -28,102 +28,182 @@ public: | |||
| /* | |||
| * Convert linear RGB to sRGB | |||
| */ | |||
| static vec3 LinearRGBTosRGB(vec3 c) | |||
| static vec3 LinearRGBTosRGB(vec3 src) | |||
| { | |||
| vec3 ret = 12.92f * c; | |||
| if (c.r > 0.0031308f) | |||
| ret.r = 1.055f * pow(c.r, 1.0f / 2.4f) - 0.055f; | |||
| if (c.g > 0.0031308f) | |||
| ret.g = 1.055f * pow(c.g, 1.0f / 2.4f) - 0.055f; | |||
| if (c.b > 0.0031308f) | |||
| ret.b = 1.055f * pow(c.b, 1.0f / 2.4f) - 0.055f; | |||
| vec3 ret = 12.92f * src; | |||
| if (src.r > 0.0031308f) | |||
| ret.r = 1.055f * pow(src.r, 1.0f / 2.4f) - 0.055f; | |||
| if (src.g > 0.0031308f) | |||
| ret.g = 1.055f * pow(src.g, 1.0f / 2.4f) - 0.055f; | |||
| if (src.b > 0.0031308f) | |||
| ret.b = 1.055f * pow(src.b, 1.0f / 2.4f) - 0.055f; | |||
| return ret; | |||
| } | |||
| static vec4 LinearRGBTosRGB(vec4 c) | |||
| static vec4 LinearRGBTosRGB(vec4 src) | |||
| { | |||
| return vec4(LinearRGBTosRGB(c.rgb), c.a); | |||
| return vec4(LinearRGBTosRGB(src.rgb), src.a); | |||
| } | |||
| /* | |||
| * Convert sRGB to linear RGB | |||
| */ | |||
| static vec3 sRGBToLinearRGB(vec3 c) | |||
| static vec3 sRGBToLinearRGB(vec3 src) | |||
| { | |||
| vec3 ret = 1.0f / 12.92f * c; | |||
| if (c.r > 0.04045f) | |||
| ret.r = pow(c.r + 0.055f, 2.4f) / pow(1.055f, 2.4f); | |||
| if (c.g > 0.04045f) | |||
| ret.g = pow(c.g + 0.055f, 2.4f) / pow(1.055f, 2.4f); | |||
| if (c.b > 0.04045f) | |||
| ret.b = pow(c.b + 0.055f, 2.4f) / pow(1.055f, 2.4f); | |||
| vec3 ret = 1.0f / 12.92f * src; | |||
| if (src.r > 0.04045f) | |||
| ret.r = pow(src.r + 0.055f, 2.4f) / pow(1.055f, 2.4f); | |||
| if (src.g > 0.04045f) | |||
| ret.g = pow(src.g + 0.055f, 2.4f) / pow(1.055f, 2.4f); | |||
| if (src.b > 0.04045f) | |||
| ret.b = pow(src.b + 0.055f, 2.4f) / pow(1.055f, 2.4f); | |||
| return ret; | |||
| } | |||
| static vec4 sRGBToLinearRGB(vec4 c) | |||
| static vec4 sRGBToLinearRGB(vec4 src) | |||
| { | |||
| return vec4(sRGBToLinearRGB(c.rgb), c.a); | |||
| return vec4(sRGBToLinearRGB(src.rgb), src.a); | |||
| } | |||
| /* | |||
| * Convert linear HSV to linear RGB | |||
| */ | |||
| static vec3 HSVToLinearRGB(vec3 src) | |||
| { | |||
| vec3 tmp = abs(fract(vec3(src.x) + vec3(3.f, 2.f, 1.f) / 3.f) * 6.f - vec3(3.f)); | |||
| return mix(vec3(1.f), clamp(tmp - vec3(1.f), 0.f, 1.f), src.y) * src.z; | |||
| } | |||
| static vec4 HSVToLinearRGB(vec4 src) | |||
| { | |||
| return vec4(HSVToLinearRGB(src.rgb), src.a); | |||
| } | |||
| /* | |||
| * Convert linear RGB to CIE XYZ | |||
| */ | |||
| static vec3 LinearRGBToCIEXYZ(vec3 c) | |||
| static vec3 LinearRGBToCIEXYZ(vec3 src) | |||
| { | |||
| mat3 m(vec3(3.2406f, -0.9689f, 0.0557f), | |||
| vec3(-1.5372f, 1.8758f, -0.2040f), | |||
| vec3(-0.4986f, 0.0415f, 1.0570f)); | |||
| return m * c; | |||
| return m * src; | |||
| } | |||
| static vec4 LinearRGBToCIEXYZ(vec4 c) | |||
| static vec4 LinearRGBToCIEXYZ(vec4 src) | |||
| { | |||
| return vec4(LinearRGBToCIEXYZ(c.rgb), c.a); | |||
| return vec4(LinearRGBToCIEXYZ(src.rgb), src.a); | |||
| } | |||
| /* | |||
| * Convert CIE XYZ to linear RGB | |||
| */ | |||
| static vec3 CIEXYZToLinearRGB(vec3 c) | |||
| static vec3 CIEXYZToLinearRGB(vec3 src) | |||
| { | |||
| mat3 m(vec3(0.4124f, 0.2126f, 0.0193f), | |||
| vec3(0.3576f, 0.7152f, 0.1192f), | |||
| vec3(0.1805f, 0.0722f, 0.9505f)); | |||
| return m * c; | |||
| return m * src; | |||
| } | |||
| static vec4 CIEXYZToLinearRGB(vec4 c) | |||
| static vec4 CIEXYZToLinearRGB(vec4 src) | |||
| { | |||
| return vec4(CIEXYZToLinearRGB(c.rgb), c.a); | |||
| return vec4(CIEXYZToLinearRGB(src.rgb), src.a); | |||
| } | |||
| /* | |||
| * Convert CIE XYZ to CIE L*a*b* | |||
| * Note: XYZ values should be normalised, ie. divided by the | |||
| * corresponding components for white. | |||
| */ | |||
| static vec3 CIEXYZToCIELab(vec3 col) | |||
| static vec3 CIEXYZToCIELab(vec3 src) | |||
| { | |||
| float const a = (6.0 * 6.0 * 6.0) / (29 * 29 * 29); | |||
| float const b = (29.0 * 29.0) / (3 * 6 * 6); | |||
| float const c = 4.0 / 29; | |||
| float const d = 1.0 / 3; | |||
| vec3 f = b * src + vec3(c); | |||
| if (src.x > a) | |||
| f.x = pow(src.x, d); | |||
| if (src.y > a) | |||
| f.y = pow(src.y, d); | |||
| if (src.z > a) | |||
| f.z = pow(src.z, d); | |||
| return vec3(116.f * f.y - 16.f, | |||
| 500.f * (f.x - f.y), | |||
| 200.f * (f.y - f.z)); | |||
| } | |||
| static vec4 CIEXYZToCIELab(vec4 src) | |||
| { | |||
| using std::pow; | |||
| float const a = 8.85645167903563081e-3; /* (6/29)^3 */ | |||
| float const b = 7.78703703703703703; /* 1/3 (29/6)^2 */ | |||
| float const c = 1.37931034482758620e-1; /* 4/29 */ | |||
| vec3 f = b * col + vec3(c); | |||
| if (col.x > a) | |||
| f.x = pow(col.x, 1.0 / 3.0); | |||
| if (col.y > a) | |||
| f.y = pow(col.y, 1.0 / 3.0); | |||
| if (col.z > a) | |||
| f.z = pow(col.z, 1.0 / 3.0); | |||
| return vec3(116.0 * f.y - 16.0, | |||
| 500.0 * (f.x - f.y), | |||
| 200.0 * (f.y - f.z)); | |||
| return vec4(CIEXYZToLinearRGB(src.rgb), src.a); | |||
| } | |||
| static vec4 CIEXYZToCIELab(vec4 c) | |||
| /* | |||
| * Return distance using the CIEDE2000 metric, | |||
| * input should be in CIE L*a*b*. | |||
| */ | |||
| static float DistanceCIEDE2000(vec3 lab1, vec3 lab2) | |||
| { | |||
| return vec4(CIEXYZToLinearRGB(c.rgb), c.a); | |||
| float const deg2rad = 6.28318530718f / 360.f; | |||
| float const rad2deg = 360.f / 6.28318530718f; | |||
| float C1 = length(lab1.yz); | |||
| float C2 = length(lab2.yz); | |||
| float C_ = 0.5f * (C1 + C2); | |||
| float L1 = lab1.x; | |||
| float L2 = lab2.x; | |||
| float dLp = L2 - L1; | |||
| float L_ = 0.5f * (L1 + L2); | |||
| float tmp1 = pow(C_, 7.f); | |||
| float tmp2 = 1.5f - 0.5f * sqrt(tmp1 / (tmp1 + pow(25.f, 7.f))); | |||
| float ap1 = lab1.y * tmp2; | |||
| float ap2 = lab2.y * tmp2; | |||
| float Cp1 = sqrt(ap1 * ap1 + lab1.z * lab1.z); | |||
| float Cp2 = sqrt(ap2 * ap2 + lab2.z * lab2.z); | |||
| float dCp = Cp2 - Cp1; | |||
| float Cp_ = 0.5f * (Cp1 + Cp2); | |||
| float hp1 = fmod(atan2(lab1.z, ap1) * rad2deg, 360.f); | |||
| if (hp1 < 0.f) | |||
| hp1 += 360.f; | |||
| float hp2 = fmod(atan2(lab2.z, ap2) * rad2deg, 360.f); | |||
| if (hp2 < 0.f) | |||
| hp2 += 360.f; | |||
| float dhp; | |||
| if (abs(hp1 - hp2) <= 180.f) | |||
| dhp = hp2 - hp1; | |||
| else if (hp2 <= hp1) | |||
| dhp = hp2 - hp1 + 360.f; | |||
| else | |||
| dhp = hp2 - hp1 - 360.f; | |||
| float dHp = 2.f * sqrt(Cp1 * Cp2) * sin(dhp / 2.f * deg2rad); | |||
| float Hp_; | |||
| if (abs(hp1 - hp2) > 180.f) | |||
| Hp_ = 0.5f * (hp1 + hp2 + 360.f); | |||
| else | |||
| Hp_ = 0.5f * (hp1 + hp2); | |||
| float T = 1.f - 0.17f * cos((Hp_ - 30.f) * deg2rad) | |||
| + 0.24f * cos(2 * Hp_ * deg2rad) | |||
| + 0.32f * cos((3.f * Hp_ + 6.f) * deg2rad) | |||
| - 0.20f * cos((4.f * Hp_ - 63.f) * deg2rad); | |||
| float SL = 1.f + 0.015f * (L_ - 50) * (L_ - 50) | |||
| / sqrt(20.f + (L_ - 50) * (L_ - 50)); | |||
| float SC = 1.f + 0.045f * Cp_; | |||
| float SH = 1.f + 0.015f * Cp_ * T; | |||
| float RT = -2.f * sqrt(pow(Cp_, 7.f) / (pow(Cp_, 7.f) + pow(25.f, 7.f))) | |||
| * sin(60.f * deg2rad * exp(-pow((Hp_ - 275.f) / 25.f, 2.f))); | |||
| dLp /= SL; | |||
| dCp /= SC; | |||
| dHp /= SH; | |||
| return sqrt(dLp * dLp + dCp * dCp + dHp * dHp + RT * dCp * dHp); | |||
| } | |||
| }; | |||