bgfx/examples/common/shaderlib.sh

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/*
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* Copyright 2011-2021 Branimir Karadzic. All rights reserved.
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* License: https://github.com/bkaradzic/bgfx#license-bsd-2-clause
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*/
#ifndef __SHADERLIB_SH__
#define __SHADERLIB_SH__
vec4 encodeRE8(float _r)
{
float exponent = ceil(log2(_r) );
return vec4(_r / exp2(exponent)
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, 0.0
, 0.0
, (exponent + 128.0) / 255.0
);
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}
float decodeRE8(vec4 _re8)
{
float exponent = _re8.w * 255.0 - 128.0;
return _re8.x * exp2(exponent);
}
vec4 encodeRGBE8(vec3 _rgb)
{
vec4 rgbe8;
float maxComponent = max(max(_rgb.x, _rgb.y), _rgb.z);
float exponent = ceil(log2(maxComponent) );
rgbe8.xyz = _rgb / exp2(exponent);
rgbe8.w = (exponent + 128.0) / 255.0;
return rgbe8;
}
vec3 decodeRGBE8(vec4 _rgbe8)
{
float exponent = _rgbe8.w * 255.0 - 128.0;
vec3 rgb = _rgbe8.xyz * exp2(exponent);
return rgb;
}
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vec3 encodeNormalUint(vec3 _normal)
{
return _normal * 0.5 + 0.5;
}
vec3 decodeNormalUint(vec3 _encodedNormal)
{
return _encodedNormal * 2.0 - 1.0;
}
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vec2 encodeNormalSphereMap(vec3 _normal)
{
return normalize(_normal.xy) * sqrt(_normal.z * 0.5 + 0.5);
}
vec3 decodeNormalSphereMap(vec2 _encodedNormal)
{
float zz = dot(_encodedNormal, _encodedNormal) * 2.0 - 1.0;
return vec3(normalize(_encodedNormal.xy) * sqrt(1.0 - zz*zz), zz);
}
vec2 octahedronWrap(vec2 _val)
{
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// Reference(s):
// - Octahedron normal vector encoding
// https://web.archive.org/web/20191027010600/https://knarkowicz.wordpress.com/2014/04/16/octahedron-normal-vector-encoding/comment-page-1/
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return (1.0 - abs(_val.yx) )
* mix(vec2_splat(-1.0), vec2_splat(1.0), vec2(greaterThanEqual(_val.xy, vec2_splat(0.0) ) ) );
}
vec2 encodeNormalOctahedron(vec3 _normal)
{
_normal /= abs(_normal.x) + abs(_normal.y) + abs(_normal.z);
_normal.xy = _normal.z >= 0.0 ? _normal.xy : octahedronWrap(_normal.xy);
_normal.xy = _normal.xy * 0.5 + 0.5;
return _normal.xy;
}
vec3 decodeNormalOctahedron(vec2 _encodedNormal)
{
_encodedNormal = _encodedNormal * 2.0 - 1.0;
vec3 normal;
normal.z = 1.0 - abs(_encodedNormal.x) - abs(_encodedNormal.y);
normal.xy = normal.z >= 0.0 ? _encodedNormal.xy : octahedronWrap(_encodedNormal.xy);
return normalize(normal);
}
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vec3 convertRGB2XYZ(vec3 _rgb)
{
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// Reference(s):
// - RGB/XYZ Matrices
// https://web.archive.org/web/20191027010220/http://www.brucelindbloom.com/index.html?Eqn_RGB_XYZ_Matrix.html
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vec3 xyz;
xyz.x = dot(vec3(0.4124564, 0.3575761, 0.1804375), _rgb);
xyz.y = dot(vec3(0.2126729, 0.7151522, 0.0721750), _rgb);
xyz.z = dot(vec3(0.0193339, 0.1191920, 0.9503041), _rgb);
return xyz;
}
vec3 convertXYZ2RGB(vec3 _xyz)
{
vec3 rgb;
rgb.x = dot(vec3( 3.2404542, -1.5371385, -0.4985314), _xyz);
rgb.y = dot(vec3(-0.9692660, 1.8760108, 0.0415560), _xyz);
rgb.z = dot(vec3( 0.0556434, -0.2040259, 1.0572252), _xyz);
return rgb;
}
vec3 convertXYZ2Yxy(vec3 _xyz)
{
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// Reference(s):
// - XYZ to xyY
// https://web.archive.org/web/20191027010144/http://www.brucelindbloom.com/index.html?Eqn_XYZ_to_xyY.html
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float inv = 1.0/dot(_xyz, vec3(1.0, 1.0, 1.0) );
return vec3(_xyz.y, _xyz.x*inv, _xyz.y*inv);
}
vec3 convertYxy2XYZ(vec3 _Yxy)
{
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// Reference(s):
// - xyY to XYZ
// https://web.archive.org/web/20191027010036/http://www.brucelindbloom.com/index.html?Eqn_xyY_to_XYZ.html
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vec3 xyz;
xyz.x = _Yxy.x*_Yxy.y/_Yxy.z;
xyz.y = _Yxy.x;
xyz.z = _Yxy.x*(1.0 - _Yxy.y - _Yxy.z)/_Yxy.z;
return xyz;
}
vec3 convertRGB2Yxy(vec3 _rgb)
{
return convertXYZ2Yxy(convertRGB2XYZ(_rgb) );
}
vec3 convertYxy2RGB(vec3 _Yxy)
{
return convertXYZ2RGB(convertYxy2XYZ(_Yxy) );
}
vec3 convertRGB2Yuv(vec3 _rgb)
{
vec3 yuv;
yuv.x = dot(_rgb, vec3(0.299, 0.587, 0.114) );
yuv.y = (_rgb.x - yuv.x)*0.713 + 0.5;
yuv.z = (_rgb.z - yuv.x)*0.564 + 0.5;
return yuv;
}
vec3 convertYuv2RGB(vec3 _yuv)
{
vec3 rgb;
rgb.x = _yuv.x + 1.403*(_yuv.y-0.5);
rgb.y = _yuv.x - 0.344*(_yuv.y-0.5) - 0.714*(_yuv.z-0.5);
rgb.z = _yuv.x + 1.773*(_yuv.z-0.5);
return rgb;
}
vec3 convertRGB2YIQ(vec3 _rgb)
{
vec3 yiq;
yiq.x = dot(vec3(0.299, 0.587, 0.114 ), _rgb);
yiq.y = dot(vec3(0.595716, -0.274453, -0.321263), _rgb);
yiq.z = dot(vec3(0.211456, -0.522591, 0.311135), _rgb);
return yiq;
}
vec3 convertYIQ2RGB(vec3 _yiq)
{
vec3 rgb;
rgb.x = dot(vec3(1.0, 0.9563, 0.6210), _yiq);
rgb.y = dot(vec3(1.0, -0.2721, -0.6474), _yiq);
rgb.z = dot(vec3(1.0, -1.1070, 1.7046), _yiq);
return rgb;
}
vec3 toLinear(vec3 _rgb)
{
return pow(abs(_rgb), vec3_splat(2.2) );
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}
vec4 toLinear(vec4 _rgba)
{
return vec4(toLinear(_rgba.xyz), _rgba.w);
}
vec3 toLinearAccurate(vec3 _rgb)
{
vec3 lo = _rgb / 12.92;
vec3 hi = pow( (_rgb + 0.055) / 1.055, vec3_splat(2.4) );
vec3 rgb = mix(hi, lo, vec3(lessThanEqual(_rgb, vec3_splat(0.04045) ) ) );
return rgb;
}
vec4 toLinearAccurate(vec4 _rgba)
{
return vec4(toLinearAccurate(_rgba.xyz), _rgba.w);
}
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float toGamma(float _r)
{
return pow(abs(_r), 1.0/2.2);
}
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vec3 toGamma(vec3 _rgb)
{
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return pow(abs(_rgb), vec3_splat(1.0/2.2) );
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}
vec4 toGamma(vec4 _rgba)
{
return vec4(toGamma(_rgba.xyz), _rgba.w);
}
vec3 toGammaAccurate(vec3 _rgb)
{
vec3 lo = _rgb * 12.92;
vec3 hi = pow(abs(_rgb), vec3_splat(1.0/2.4) ) * 1.055 - 0.055;
vec3 rgb = mix(hi, lo, vec3(lessThanEqual(_rgb, vec3_splat(0.0031308) ) ) );
return rgb;
}
vec4 toGammaAccurate(vec4 _rgba)
{
return vec4(toGammaAccurate(_rgba.xyz), _rgba.w);
}
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vec3 toReinhard(vec3 _rgb)
{
return toGamma(_rgb/(_rgb+vec3_splat(1.0) ) );
}
vec4 toReinhard(vec4 _rgba)
{
return vec4(toReinhard(_rgba.xyz), _rgba.w);
}
vec3 toFilmic(vec3 _rgb)
{
_rgb = max(vec3_splat(0.0), _rgb - 0.004);
_rgb = (_rgb*(6.2*_rgb + 0.5) ) / (_rgb*(6.2*_rgb + 1.7) + 0.06);
return _rgb;
}
vec4 toFilmic(vec4 _rgba)
{
return vec4(toFilmic(_rgba.xyz), _rgba.w);
}
vec3 toAcesFilmic(vec3 _rgb)
{
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// Reference(s):
// - ACES Filmic Tone Mapping Curve
// https://web.archive.org/web/20191027010704/https://knarkowicz.wordpress.com/2016/01/06/aces-filmic-tone-mapping-curve/
float aa = 2.51f;
float bb = 0.03f;
float cc = 2.43f;
float dd = 0.59f;
float ee = 0.14f;
return saturate( (_rgb*(aa*_rgb + bb) )/(_rgb*(cc*_rgb + dd) + ee) );
}
vec4 toAcesFilmic(vec4 _rgba)
{
return vec4(toAcesFilmic(_rgba.xyz), _rgba.w);
}
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vec3 luma(vec3 _rgb)
{
float yy = dot(vec3(0.2126729, 0.7151522, 0.0721750), _rgb);
return vec3_splat(yy);
}
vec4 luma(vec4 _rgba)
{
return vec4(luma(_rgba.xyz), _rgba.w);
}
vec3 conSatBri(vec3 _rgb, vec3 _csb)
{
vec3 rgb = _rgb * _csb.z;
rgb = mix(luma(rgb), rgb, _csb.y);
rgb = mix(vec3_splat(0.5), rgb, _csb.x);
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return rgb;
}
vec4 conSatBri(vec4 _rgba, vec3 _csb)
{
return vec4(conSatBri(_rgba.xyz, _csb), _rgba.w);
}
vec3 posterize(vec3 _rgb, float _numColors)
{
return floor(_rgb*_numColors) / _numColors;
}
vec4 posterize(vec4 _rgba, float _numColors)
{
return vec4(posterize(_rgba.xyz, _numColors), _rgba.w);
}
vec3 sepia(vec3 _rgb)
{
vec3 color;
color.x = dot(_rgb, vec3(0.393, 0.769, 0.189) );
color.y = dot(_rgb, vec3(0.349, 0.686, 0.168) );
color.z = dot(_rgb, vec3(0.272, 0.534, 0.131) );
return color;
}
vec4 sepia(vec4 _rgba)
{
return vec4(sepia(_rgba.xyz), _rgba.w);
}
vec3 blendOverlay(vec3 _base, vec3 _blend)
{
vec3 lt = 2.0 * _base * _blend;
vec3 gte = 1.0 - 2.0 * (1.0 - _base) * (1.0 - _blend);
return mix(lt, gte, step(vec3_splat(0.5), _base) );
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}
vec4 blendOverlay(vec4 _base, vec4 _blend)
{
return vec4(blendOverlay(_base.xyz, _blend.xyz), _base.w);
}
vec3 adjustHue(vec3 _rgb, float _hue)
{
vec3 yiq = convertRGB2YIQ(_rgb);
float angle = _hue + atan2(yiq.z, yiq.y);
float len = length(yiq.yz);
return convertYIQ2RGB(vec3(yiq.x, len*cos(angle), len*sin(angle) ) );
}
vec4 packFloatToRgba(float _value)
{
const vec4 shift = vec4(256 * 256 * 256, 256 * 256, 256, 1.0);
const vec4 mask = vec4(0, 1.0 / 256.0, 1.0 / 256.0, 1.0 / 256.0);
vec4 comp = fract(_value * shift);
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comp -= comp.xxyz * mask;
return comp;
}
float unpackRgbaToFloat(vec4 _rgba)
{
const vec4 shift = vec4(1.0 / (256.0 * 256.0 * 256.0), 1.0 / (256.0 * 256.0), 1.0 / 256.0, 1.0);
return dot(_rgba, shift);
}
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vec2 packHalfFloat(float _value)
{
const vec2 shift = vec2(256, 1.0);
const vec2 mask = vec2(0, 1.0 / 256.0);
vec2 comp = fract(_value * shift);
comp -= comp.xx * mask;
return comp;
}
float unpackHalfFloat(vec2 _rg)
{
const vec2 shift = vec2(1.0 / 256.0, 1.0);
return dot(_rg, shift);
}
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float random(vec2 _uv)
{
return fract(sin(dot(_uv.xy, vec2(12.9898, 78.233) ) ) * 43758.5453);
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}
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vec3 fixCubeLookup(vec3 _v, float _lod, float _topLevelCubeSize)
{
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// Reference(s):
// - Seamless cube-map filtering
// https://web.archive.org/web/20190411181934/http://the-witness.net/news/2012/02/seamless-cube-map-filtering/
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float ax = abs(_v.x);
float ay = abs(_v.y);
float az = abs(_v.z);
float vmax = max(max(ax, ay), az);
float scale = 1.0 - exp2(_lod) / _topLevelCubeSize;
if (ax != vmax) { _v.x *= scale; }
if (ay != vmax) { _v.y *= scale; }
if (az != vmax) { _v.z *= scale; }
return _v;
}
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vec2 texture2DBc5(sampler2D _sampler, vec2 _uv)
{
#if BGFX_SHADER_LANGUAGE_HLSL && BGFX_SHADER_LANGUAGE_HLSL <= 300
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return texture2D(_sampler, _uv).yx;
#else
return texture2D(_sampler, _uv).xy;
#endif
}
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mat3 cofactor(mat4 _m)
{
// Reference:
// Cofactor of matrix. Use to transform normals. The code assumes the last column of _m is [0,0,0,1].
// https://www.shadertoy.com/view/3s33zj
// https://github.com/graphitemaster/normals_revisited
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return mat3(
_m[1][1]*_m[2][2]-_m[1][2]*_m[2][1],
_m[1][2]*_m[2][0]-_m[1][0]*_m[2][2],
_m[1][0]*_m[2][1]-_m[1][1]*_m[2][0],
_m[0][2]*_m[2][1]-_m[0][1]*_m[2][2],
_m[0][0]*_m[2][2]-_m[0][2]*_m[2][0],
_m[0][1]*_m[2][0]-_m[0][0]*_m[2][1],
_m[0][1]*_m[1][2]-_m[0][2]*_m[1][1],
_m[0][2]*_m[1][0]-_m[0][0]*_m[1][2],
_m[0][0]*_m[1][1]-_m[0][1]*_m[1][0]
);
}
float toClipSpaceDepth(float _depthTextureZ)
{
#if BGFX_SHADER_LANGUAGE_GLSL
return _depthTextureZ * 2.0 - 1.0;
#else
return _depthTextureZ;
#endif // BGFX_SHADER_LANGUAGE_GLSL
}
vec3 clipToWorld(mat4 _invViewProj, vec3 _clipPos)
{
vec4 wpos = mul(_invViewProj, vec4(_clipPos, 1.0) );
return wpos.xyz / wpos.w;
}
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#endif // __SHADERLIB_SH__