mirror of
https://github.com/X0nk/Bliss-Shader.git
synced 2024-12-23 01:59:39 +08:00
190 lines
6.6 KiB
GLSL
190 lines
6.6 KiB
GLSL
#include "/lib/settings.glsl"
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varying vec2 texcoord;
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uniform vec2 texelSize;
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uniform sampler2D colortex7;
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uniform sampler2D colortex14;
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uniform sampler2D depthtex0;
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uniform sampler2D noisetex;
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uniform float viewHeight;
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uniform float viewWidth;
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uniform float aspectRatio;
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uniform float frameTimeCounter;
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uniform int frameCounter;
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uniform int hideGUI;
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#include "/lib/color_transforms.glsl"
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#include "/lib/color_dither.glsl"
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#include "/lib/res_params.glsl"
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/*
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vec4 SampleTextureCatmullRom(sampler2D tex, vec2 uv, vec2 texSize )
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{
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// We're going to sample a a 4x4 grid of texels surrounding the target UV coordinate. We'll do this by rounding
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// down the sample location to get the exact center of our "starting" texel. The starting texel will be at
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// location [1, 1] in the grid, where [0, 0] is the top left corner.
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vec2 samplePos = uv * texSize;
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vec2 texPos1 = floor(samplePos - 0.5) + 0.5;
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// Compute the fractional offset from our starting texel to our original sample location, which we'll
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// feed into the Catmull-Rom spline function to get our filter weights.
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vec2 f = samplePos - texPos1;
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// Compute the Catmull-Rom weights using the fractional offset that we calculated earlier.
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// These equations are pre-expanded based on our knowledge of where the texels will be located,
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// which lets us avoid having to evaluate a piece-wise function.
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vec2 w0 = f * ( -0.5 + f * (1.0 - 0.5*f));
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vec2 w1 = 1.0 + f * f * (-2.5 + 1.5*f);
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vec2 w2 = f * ( 0.5 + f * (2.0 - 1.5*f) );
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vec2 w3 = f * f * (-0.5 + 0.5 * f);
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// Work out weighting factors and sampling offsets that will let us use bilinear filtering to
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// simultaneously evaluate the middle 2 samples from the 4x4 grid.
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vec2 w12 = w1 + w2;
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vec2 offset12 = w2 / (w1 + w2);
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// Compute the final UV coordinates we'll use for sampling the texture
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vec2 texPos0 = texPos1 - vec2(1.0);
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vec2 texPos3 = texPos1 + vec2(2.0);
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vec2 texPos12 = texPos1 + offset12;
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texPos0 *= texelSize;
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texPos3 *= texelSize;
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texPos12 *= texelSize;
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vec4 result = vec4(0.0);
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result += texture2D(tex, vec2(texPos0.x, texPos0.y)) * w0.x * w0.y;
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result += texture2D(tex, vec2(texPos12.x, texPos0.y)) * w12.x * w0.y;
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result += texture2D(tex, vec2(texPos3.x, texPos0.y)) * w3.x * w0.y;
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result += texture2D(tex, vec2(texPos0.x, texPos12.y)) * w0.x * w12.y;
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result += texture2D(tex, vec2(texPos12.x, texPos12.y)) * w12.x * w12.y;
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result += texture2D(tex, vec2(texPos3.x, texPos12.y)) * w3.x * w12.y;
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result += texture2D(tex, vec2(texPos0.x, texPos3.y)) * w0.x * w3.y;
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result += texture2D(tex, vec2(texPos12.x, texPos3.y)) * w12.x * w3.y;
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result += texture2D(tex, vec2(texPos3.x, texPos3.y)) * w3.x * w3.y;
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return result;
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}
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*/
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float lowerCurve(float x) {
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float y = 16 * x * (0.5 - x) * 0.1;
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return clamp(y, 0.0, 1.0);
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}
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float upperCurve(float x) {
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float y = 16 * (0.5 - x) * (x - 1.0) * 0.1;
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return clamp(y, 0.0, 1.0);
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}
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vec3 luminanceCurve(vec3 color){
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color.r += LOWER_CURVE * lowerCurve(color.r) + UPPER_CURVE * upperCurve(color.r);
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color.g += LOWER_CURVE * lowerCurve(color.g) + UPPER_CURVE * upperCurve(color.g);
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color.b += LOWER_CURVE * lowerCurve(color.b) + UPPER_CURVE * upperCurve(color.b);
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return color;
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}
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vec3 colorGrading(vec3 color) {
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float grade_luma = dot(color, vec3(1.0 / 3.0));
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float shadows_amount = saturate(-6.0 * grade_luma + 2.75);
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float mids_amount = saturate(-abs(6.0 * grade_luma - 3.0) + 1.25);
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float highlights_amount = saturate(6.0 * grade_luma - 3.25);
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vec3 graded_shadows = color * SHADOWS_TARGET * SHADOWS_GRADE_MUL * 1.7320508076;
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vec3 graded_mids = color * MIDS_TARGET * MIDS_GRADE_MUL * 1.7320508076;
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vec3 graded_highlights = color * HIGHLIGHTS_TARGET * HIGHLIGHTS_GRADE_MUL * 1.7320508076;
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return saturate(graded_shadows * shadows_amount + graded_mids * mids_amount + graded_highlights * highlights_amount);
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}
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vec3 contrastAdaptiveSharpening(vec3 color, vec2 texcoord){
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//Weights : 1 in the center, 0.5 middle, 0.25 corners
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vec3 albedoCurrent1 = texture2D(colortex7, texcoord + vec2(texelSize.x,texelSize.y)/MC_RENDER_QUALITY*0.5).rgb;
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vec3 albedoCurrent2 = texture2D(colortex7, texcoord + vec2(texelSize.x,-texelSize.y)/MC_RENDER_QUALITY*0.5).rgb;
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vec3 albedoCurrent3 = texture2D(colortex7, texcoord + vec2(-texelSize.x,-texelSize.y)/MC_RENDER_QUALITY*0.5).rgb;
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vec3 albedoCurrent4 = texture2D(colortex7, texcoord + vec2(-texelSize.x,texelSize.y)/MC_RENDER_QUALITY*0.5).rgb;
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vec3 m1 = -0.5/3.5*color + albedoCurrent1/3.5 + albedoCurrent2/3.5 + albedoCurrent3/3.5 + albedoCurrent4/3.5;
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vec3 std = abs(color - m1) + abs(albedoCurrent1 - m1) + abs(albedoCurrent2 - m1) +
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abs(albedoCurrent3 - m1) + abs(albedoCurrent3 - m1) + abs(albedoCurrent4 - m1);
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float contrast = 1.0 - luma(std)/5.0;
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color = color*(1.0+(SHARPENING+UPSCALING_SHARPNENING)*contrast) -
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(SHARPENING+UPSCALING_SHARPNENING)/(1.0-0.5/3.5)*contrast*(m1 - 0.5/3.5*color);
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return color;
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}
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vec3 saturationAndCrosstalk(vec3 color){
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float luminance = luma(color);
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vec3 lumaColDiff = color - luminance;
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color = color + lumaColDiff*(-luminance*CROSSTALK + SATURATION);
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return color;
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}
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float interleaved_gradientNoise(){
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vec2 coord = gl_FragCoord.xy;
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float noise = fract(52.9829189*fract(0.06711056*coord.x + 0.00583715*coord.y));
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return noise;
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}
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float blueNoise(){
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return fract(texelFetch2D(noisetex, ivec2(gl_FragCoord.xy)%512, 0).a + 1.0/1.6180339887 * frameCounter);
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}
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vec3 chromaticAberration(vec2 UV){
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float noise = blueNoise() - 0.5;
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vec2 centeredUV = (texcoord - 0.5);
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// not stretched by aspect ratio; circular by choice :) it makes most the abberation on the left/right of the screen.
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float vignette = 1.0 - clamp(1.0 - length(centeredUV * vec2(aspectRatio,1.0)) / 200.0,0.0,1.0);
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float aberrationStrength = CHROMATIC_ABERRATION_STRENGTH * vignette;
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vec3 color = vec3(0.0);
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color.r = texture2D(colortex7, (centeredUV - (centeredUV + centeredUV*noise) * aberrationStrength) + 0.5).r;
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color.g = texture2D(colortex7, texcoord).g;
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color.b = texture2D(colortex7, (centeredUV + (centeredUV + centeredUV*noise) * aberrationStrength) + 0.5).b;
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return color;
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}
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void main() {
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/* DRAWBUFFERS:7 */
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#ifdef CHROMATIC_ABERRATION
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vec3 color = chromaticAberration(texcoord);
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#else
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vec3 color = texture2D(colortex7,texcoord).rgb;
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#endif
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#ifdef CONTRAST_ADAPTATIVE_SHARPENING
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color = contrastAdaptiveSharpening(color, texcoord);
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#endif
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color = saturationAndCrosstalk(color);
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#ifdef LUMINANCE_CURVE
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color = luminanceCurve(color);
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#endif
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#ifdef COLOR_GRADING_ENABLED
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color = colorGrading(color);
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#endif
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gl_FragData[0].rgb = clamp(int8Dither(color, texcoord),0.0,1.0);
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}
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