diff --git a/include/colorspace-tools.h b/include/colorspace-tools.h index 9c6a2c9..56800c8 100644 --- a/include/colorspace-tools.h +++ b/include/colorspace-tools.h @@ -64,8 +64,8 @@ vec3 srgb_linear(vec3 x) { #endif } -vec3 linear_to_sRGB(vec3 color, float gamma){ - +vec3 linear_to_sRGB(vec3 color, float gamma) +{ color = clamp(color, 0.0, 1.0); color.r = (color.r <= 0.00313066844250063) ? color.r * 12.92 : 1.055 * pow(color.r, 1.0 / gamma) - 0.055; @@ -77,8 +77,8 @@ vec3 linear_to_sRGB(vec3 color, float gamma){ return color.rgb; } -vec3 sRGB_to_linear(vec3 color, float gamma){ - +vec3 sRGB_to_linear(vec3 color, float gamma) +{ color = clamp(color, 0.0, 1.0); color.r = (color.r <= 0.04045) ? color.r / 12.92 : pow((color.r + 0.055) / (1.055), gamma); @@ -90,117 +90,165 @@ vec3 sRGB_to_linear(vec3 color, float gamma){ return color.rgb; } -//Conversion matrices +/*------------------------------------------------------------------------------ + [RGB TO GRAYSCALE / LUMA CODE SECTION] +------------------------------------------------------------------------------*/ + +// if you're already in linear gamma, definitely use this one ( Y = 0.2126R + 0.7152G + 0.0722B ) +// the Rec. 709 spec uses these same coefficients but with gamma-compressed components ( Y' = 0.2126R' + 0.7152G' + 0.0722B' ) +float luma(vec3 color) +{ + return dot(color, vec3(0.2126, 0.7152, 0.0722)); +} + +// for digital formats following CCIR 601 (that is, most digital standard def formats) +// expects gamma-compressed components and doesn't look very good +// ( Y' = 0.299R' + 0.587G' + 0.114B' ) +float luma_CCIR601(vec3 color) +{ + return dot(color, vec3(0.299, 0.587, 0.114)); +} + +// SMPTE 240M; used by some transitional 1035i HDTV signals. Expects gamma-compressed components +// ( Y' = 0.212R' + 0.701G' + 0.087B' ) +float luma_240M(vec3 color) +{ + return dot(color, vec3(0.212, 0.701, 0.087)); +} + +// Same as Rec. 709 but with quick-and-dirty gamma linearization added on top +float luma_gamma(vec3 color) +{ + color = color * color; + float luma = dot(color, vec3(0.2126, 0.7152, 0.0722)); + return sqrt(luma); +} + +/*------------------------------------------------------------------------------ + [COLORSPACE CONVERSION CODE SECTION] +------------------------------------------------------------------------------*/ + +/* XYZ color space is a device-invariant representation that encompasses all color sensations that are visible to a person +with average eyesight. Y is the luminance, Z is quasi-equal to blue and X is a mix of the three CIE RGB curves chosen to be non-negative */ + vec3 RGBtoXYZ(vec3 RGB) - { - const mat3x3 m = mat3x3( - 0.6068909, 0.1735011, 0.2003480, - 0.2989164, 0.5865990, 0.1144845, - 0.0000000, 0.0660957, 1.1162243); - +{ + const mat3x3 m = mat3x3( + 0.6068909, 0.1735011, 0.2003480, + 0.2989164, 0.5865990, 0.1144845, + 0.0000000, 0.0660957, 1.1162243); return RGB * m; - } +} vec3 XYZtoRGB(vec3 XYZ) - { - const mat3x3 m = mat3x3( - 1.9099961, -0.5324542, -0.2882091, - -0.9846663, 1.9991710, -0.0283082, - 0.0583056, -0.1183781, 0.8975535); - +{ + const mat3x3 m = mat3x3( + 1.9099961, -0.5324542, -0.2882091, + -0.9846663, 1.9991710, -0.0283082, + 0.0583056, -0.1183781, 0.8975535); return XYZ * m; } vec3 XYZtoSRGB(vec3 XYZ) { const mat3x3 m = mat3x3( - 3.2404542,-1.5371385,-0.4985314, - -0.9692660, 1.8760108, 0.0415560, - 0.0556434,-0.2040259, 1.0572252); - + 3.2404542,-1.5371385,-0.4985314, + -0.9692660, 1.8760108, 0.0415560, + 0.0556434,-0.2040259, 1.0572252); return XYZ * m; - } +} + +/* YUV is a color space that takes human perception into account, allowing reduced bandwidth for chrominance components, +as compared with a direct RGB representation. It includes a luminance component, Y, with nonlinear perceptual brightness, +and two color components, U and V. This colorspace was used in the PAL color broadcast standard and is the counterpart to +NTSC's YIQ colorspace. It is still commonly used to describe YCbCr signals. */ vec3 RGBtoYUV(vec3 RGB) - { - const mat3x3 m = mat3x3( - 0.2126, 0.7152, 0.0722, - -0.09991,-0.33609, 0.436, - 0.615, -0.55861, -0.05639); - - return RGB * m; - } +{ + const mat3x3 m = mat3x3( + 0.2126, 0.7152, 0.0722, + -0.09991,-0.33609, 0.436, + 0.615, -0.55861, -0.05639); + return RGB * m; +} vec3 YUVtoRGB(vec3 YUV) - { - const mat3x3 m = mat3x3( - 1.000, 0.000, 1.28033, - 1.000,-0.21482,-0.38059, - 1.000, 2.12798, 0.000); - - return YUV * m; - } +{ + const mat3x3 m = mat3x3( + 1.000, 0.000, 1.28033, + 1.000,-0.21482,-0.38059, + 1.000, 2.12798, 0.000); + return YUV * m; +} + +/* YIQ is the color space used for analog NTSC color broadcasts, whereby Y stands for luma, I stands for in-phase and +Q stands for quadrature, referring to the components used in quadrature amplitude modulation. The IQ axes exist on the +same plane as the UV axes from the YUV color space, just rotated 33 degrees. */ vec3 RGBtoYIQ(vec3 RGB) - { - const mat3x3 m = mat3x3( - 0.2989, 0.5870, 0.1140, - 0.5959, -0.2744, -0.3216, - 0.2115, -0.5229, 0.3114); - return RGB * m; - } +{ + const mat3x3 m = mat3x3( + 0.2989, 0.5870, 0.1140, + 0.5959, -0.2744, -0.3216, + 0.2115, -0.5229, 0.3114); + return RGB * m; +} vec3 YIQtoRGB(vec3 YIQ) - { - const mat3x3 m = mat3x3( - 1.0, 0.956, 0.6210, - 1.0, -0.2720, -0.6474, - 1.0, -1.1060, 1.7046); - return YIQ * m; - } +{ + const mat3x3 m = mat3x3( + 1.0, 0.956, 0.6210, + 1.0, -0.2720, -0.6474, + 1.0, -1.1060, 1.7046); + return YIQ * m; +} vec3 XYZtoYxy(vec3 XYZ) - { +{ float w = (XYZ.r + XYZ.g + XYZ.b); - vec3 Yxy; + vec3 Yxy; Yxy.r = XYZ.g; Yxy.g = XYZ.r / w; Yxy.b = XYZ.g / w; - return Yxy; - } + return Yxy; +} vec3 YxytoXYZ(vec3 Yxy) - { +{ vec3 XYZ; XYZ.g = Yxy.r; XYZ.r = Yxy.r * Yxy.g / Yxy.b; XYZ.b = Yxy.r * (1.0 - Yxy.g - Yxy.b) / Yxy.b; return XYZ; - } - +} + +/* CMYK--aka process color or four color--is a subtractive color model based on the CMY color model that is +used in color printing and to describe the printing process itself. C is for Cyan, M is for Magenta, Y is for +Yellow and K is for 'key' or black. */ + // RGB <-> CMYK conversions require 4 channels vec4 RGBtoCMYK(vec3 RGB){ - float Red = RGB.r; - float Green = RGB.g; - float Blue = RGB.b; - float Black = min(1.0 - Red, min(1.0 - Green, 1.0 - Blue)); - float Cyan = (1.0 - Red - Black) / (1.0 - Black); - float Magenta = (1.0 - Green - Black) / (1.0 - Black); - float Yellow = (1.0 - Blue - Black) / (1.0 - Black); - return vec4(Cyan, Magenta, Yellow, Black); + float Red = RGB.r; + float Green = RGB.g; + float Blue = RGB.b; + float Black = min(1.0 - Red, min(1.0 - Green, 1.0 - Blue)); + float Cyan = (1.0 - Red - Black) / (1.0 - Black); + float Magenta = (1.0 - Green - Black) / (1.0 - Black); + float Yellow = (1.0 - Blue - Black) / (1.0 - Black); + return vec4(Cyan, Magenta, Yellow, Black); } vec3 CMYKtoRGB(vec4 CMYK){ - float Cyan = CMYK.x; - float Magenta = CMYK.y; - float Yellow = CMYK.z; - float Black = CMYK.w; - float Red = 1.0 - min(1.0, Cyan * (1.0 - Black) + Black); - float Green = 1.0 - min(1.0, Magenta * (1.0 - Black) + Black); - float Blue = 1.0 - min(1.0, Yellow * (1.0 - Black) + Black); - return vec3(Red, Green, Blue); + float Cyan = CMYK.x; + float Magenta = CMYK.y; + float Yellow = CMYK.z; + float Black = CMYK.w; + float Red = 1.0 - min(1.0, Cyan * (1.0 - Black) + Black); + float Green = 1.0 - min(1.0, Magenta * (1.0 - Black) + Black); + float Blue = 1.0 - min(1.0, Yellow * (1.0 - Black) + Black); + return vec3(Red, Green, Blue); } // Converting pure hue to RGB @@ -291,20 +339,27 @@ const vec3 D9000KDS = vec3(0.90354,1.00000,1.31190);//8939K, 0.0114 Duv //} // --- sRGB --- // -vec3 XYZ_to_sRGB(vec3 x) { +vec3 XYZ_to_sRGB(vec3 x) +{ x = x * mat3x3( 3.2404542, -1.5371385, -0.4985314, -0.9692660, 1.8760108, 0.0415560, 0.0556434, -0.2040259, 1.0572252 ); x = mix(1.055*pow(x, vec3(1./2.4)) - 0.055, 12.92*x, step(x,vec3(0.0031308))); return x; } -vec3 sRGB_to_XYZ(vec3 x) { +vec3 sRGB_to_XYZ(vec3 x) +{ x = mix(pow((x + 0.055)/1.055,vec3(2.4)), x / 12.92, step(x,vec3(0.04045))); x = x * mat3x3( 0.4124564, 0.3575761, 0.1804375, 0.2126729, 0.7151522, 0.0721750, 0.0193339, 0.1191920, 0.9503041 ); return x; } -// --- Jzazbz --- //{ -vec3 XYZ_to_Jzazbz(vec3 XYZ) { +/* Jzazbz is a color space designed for perceptual uniformity in high dynamic range (HDR) and wide color gamut (WCG) applications. +It is conceptually similar to CIE Lab but is considered more "modern". As compared with Lab, perceptual color differences are +predicted by Euclidean distance, it is more perceptually uniform and changes in saturation or lightness produce less shifts in hue +(i.e., increased hue linearity). Jzazbz and JzCzhz are used by ImageMagick and not much else. */ + +vec3 XYZ_to_Jzazbz(vec3 XYZ) +{ float b = 1.15; float g = 0.66; vec3 XYZprime = XYZ; @@ -324,16 +379,20 @@ vec3 XYZ_to_Jzazbz(vec3 XYZ) { vec3 Jzazbz = Izazbz; Jzazbz.x = ((1 + d) * Izazbz.x)/(1 + d * Izazbz.x) - d0; return Jzazbz; -} +} + +/* The polar version of Jzazbz */ -vec3 Jzazbz_to_JzCzhz(vec3 Jzazbz) { +vec3 Jzazbz_to_JzCzhz(vec3 Jzazbz) +{ float Cz = sqrt(Jzazbz.y*Jzazbz.y + Jzazbz.z*Jzazbz.z); float hz = atan(Jzazbz.z,Jzazbz.y); vec3 JzCzhz = vec3(Jzazbz.x,Cz,hz); return JzCzhz; } -vec3 JzCzhz_Normalize(vec3 JzCzhz) { +vec3 JzCzhz_Normalize(vec3 JzCzhz) +{ JzCzhz.x = JzCzhz.x*56.91964; JzCzhz.y = JzCzhz.y*40.05235; JzCzhz.z = (JzCzhz.z+2.761)/5.522; @@ -343,19 +402,22 @@ vec3 JzCzhz_Normalize(vec3 JzCzhz) { return JzCzhz; } -vec3 JzCzhz_Denormalize(vec3 JzCzhz) { +vec3 JzCzhz_Denormalize(vec3 JzCzhz) +{ JzCzhz.x = JzCzhz.x/56.91964; JzCzhz.y = JzCzhz.y/40.05235; JzCzhz.z = JzCzhz.z * 5.522 - 2.761; return JzCzhz; } -vec3 JzCzhz_to_Jzazbz(vec3 JzCzhz) { +vec3 JzCzhz_to_Jzazbz(vec3 JzCzhz) +{ vec3 Jzazbz = vec3(JzCzhz.x,JzCzhz.y*cos(JzCzhz.z),JzCzhz.y*sin(JzCzhz.z));; return Jzazbz; } -vec3 Jzazbz_to_XYZ(vec3 Jzazbz) { +vec3 Jzazbz_to_XYZ(vec3 Jzazbz) +{ float d0 = 1.6295499532821566 * pow(10.0,-11.0); float d = -0.56; float Iz = (Jzazbz.x + d0) / (1 + d - d * (Jzazbz.x + d0));