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254 lines
8.8 KiB
Plaintext
254 lines
8.8 KiB
Plaintext
#version 420
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#extension GL_ARB_texture_gather : enable
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// shader bd8bba59e2149449
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// Monochromia
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// Simple Levels + Curves + LumaSharpening
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// Credits to Jamie, NAVras for LumaSharpening; CeeJay.dk for Levels, Curves
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// original shader dumped using cemu 1.11.0c, BotW 1.3.1
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// Levels controls
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const int BlackPoint = 3; //[0, 255] The black point is the new black - literally. Everything darker than this will become completely black
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const int WhitePoint = 252; //[0, 255] The new white point. Everything brighter than this becomes completely white
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// Curves controls
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const float Contrast = 0.25; //[-1.0, 1.0] The amount of contrast you want
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//LumaShapening
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#define sharp_strength 2.5 //[0.10 to 3.00] Default 0.65 , Strength of the sharpening.
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#define sharp_clamp 0.085 //[0.000 to 1.000] Default 0.035 , Limits maximum amount of sharpening a pixel recieves.
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//Advanced sharpening settings
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#define offset_bias 1.0 //[0.0 to 6.0] Offset bias adjusts the radius of the sampling pattern.
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//Others
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const float bloomFactor = 0.9; //Default is 1.0
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uniform ivec4 uf_remappedPS[1];
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layout(binding = 0) uniform sampler2D textureUnitPS0;// Tex0 addr 0xf46ac800 res 320x180x1 dim 1 tm: 4 format 0816 compSel: 0 1 2 5 mipView: 0x0 (num 0x5) sliceView: 0x0 (num 0x1) Sampler0 ClampX/Y/Z: 2 2 2 border: 1
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layout(binding = 1) uniform sampler2D textureUnitPS1;// Tex1 addr 0xf5c7b800 res 1280x720x1 dim 1 tm: 4 format 0816 compSel: 0 1 2 5 mipView: 0x0 (num 0x1) sliceView: 0x0 (num 0x1) Sampler1 ClampX/Y/Z: 2 2 2 border: 1
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layout(location = 0) in vec4 passParameterSem0;
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layout(location = 0) out vec4 passPixelColor0;
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uniform vec2 uf_fragCoordScale;
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int clampFI32(int v)
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{
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if( v == 0x7FFFFFFF )
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return floatBitsToInt(1.0);
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else if( v == 0xFFFFFFFF )
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return floatBitsToInt(0.0);
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return floatBitsToInt(clamp(intBitsToFloat(v), 0.0, 1.0));
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}
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float mul_nonIEEE(float a, float b){ if( a == 0.0 || b == 0.0 ) return 0.0; return a*b; }
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/**
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* Levels version 1.2
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* by Christian Cann Schuldt Jensen ~ CeeJay.dk
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*
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* Allows you to set a new black and a white level.
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* This increases contrast, but clips any colors outside the new range to either black or white
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* and so some details in the shadows or highlights can be lost.
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*
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* The shader is very useful for expanding the 16-235 TV range to 0-255 PC range.
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* You might need it if you're playing a game meant to display on a TV with an emulator that does not do this.
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* But it's also a quick and easy way to uniformly increase the contrast of an image.
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*
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* -- Version 1.0 --
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* First release
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* -- Version 1.1 --
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* Optimized to only use 1 instruction (down from 2 - a 100% performance increase :) )
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* -- Version 1.2 --
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* Added the ability to highlight clipping regions of the image with #define HighlightClipping 1
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*/
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vec3 LevelsPass(vec3 inputColor) {
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float black_point_float = BlackPoint / 255.0;
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float white_point_float = WhitePoint == BlackPoint ? (255.0 / 0.00025) : (255.0 / (WhitePoint - BlackPoint)); // Avoid division by zero if the white and black point are the same
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vec3 color = inputColor;
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color = color * white_point_float - (black_point_float * white_point_float);
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return color;
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}
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/**
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* Curves
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* by Christian Cann Schuldt Jensen ~ CeeJay.dk
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*
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* Curves, uses S-curves to increase contrast, without clipping highlights and shadows.
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*/
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vec3 CurvesPass(vec3 inputColor) {
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vec3 colorInput = inputColor;
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float Contrast_blend = Contrast * 2.0; //I multiply by two to give it a strength closer to the other curves.
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vec3 x = colorInput.rgb; //if the curve should be applied to both Luma and Chroma
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x = x * (x * (1.5 - x) + 0.5); //horner form - fastest version
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vec3 color = x; //if the curve should be applied to both Luma and Chroma
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colorInput.rgb = mix(colorInput.rgb, color, Contrast_blend); //Blend by Contrast
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return colorInput;
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}
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//LumaSharpening
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#define px (1.0/1280.0*uf_fragCoordScale.x)
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#define py (1.0/720.0*uf_fragCoordScale.y)
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#define CoefLuma vec3(0.2126, 0.7152, 0.0722)
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float lumaSharpening(sampler2D tex, vec2 pos){
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vec4 colorInput = texture(tex, pos);
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vec3 ori = colorInput.rgb;
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// -- Combining the strength and luma multipliers --
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vec3 sharp_strength_luma = (CoefLuma * sharp_strength);
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// -- Gaussian filter --
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// [ .25, .50, .25] [ 1 , 2 , 1 ]
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// [ .50, 1, .50] = [ 2 , 4 , 2 ]
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// [ .25, .50, .25] [ 1 , 2 , 1 ]
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//float px = 1.0/tex_size[0];
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//float py = 1.0/tex_size[1];
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vec3 blur_ori = texture(tex, pos + vec2(px,-py) * 0.5 * offset_bias).rgb; // South East
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blur_ori += texture(tex, pos + vec2(-px,-py) * 0.5 * offset_bias).rgb; // South West
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blur_ori += texture(tex, pos + vec2(px,py) * 0.5 * offset_bias).rgb; // North East
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blur_ori += texture(tex, pos + vec2(-px,py) * 0.5 * offset_bias).rgb; // North West
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blur_ori *= 0.25; // ( /= 4) Divide by the number of texture fetches
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// -- Calculate the sharpening --
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vec3 sharp = ori - blur_ori; //Subtracting the blurred image from the original image
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// -- Adjust strength of the sharpening and clamp it--
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vec4 sharp_strength_luma_clamp = vec4(sharp_strength_luma * (0.5 / sharp_clamp),0.5); //Roll part of the clamp into the dot
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float sharp_luma = clamp((dot(vec4(sharp,1.0), sharp_strength_luma_clamp)), 0.0,1.0 ); //Calculate the luma, adjust the strength, scale up and clamp
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sharp_luma = (sharp_clamp * 2.0) * sharp_luma - sharp_clamp; //scale down
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// -- Combining the values to get the final sharpened pixel --
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//colorInput.rgb = colorInput.rgb + sharp_luma; // Add the sharpening to the input color.
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return sharp_luma;
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}
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void main()
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{
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vec4 R0f = vec4(0.0);
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vec4 R1f = vec4(0.0);
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vec4 R123f = vec4(0.0);
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vec4 R125f = vec4(0.0);
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vec4 R126f = vec4(0.0);
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vec4 R127f = vec4(0.0);
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float backupReg0f, backupReg1f, backupReg2f, backupReg3f, backupReg4f;
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vec4 PV0f = vec4(0.0), PV1f = vec4(0.0);
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float PS0f = 0.0, PS1f = 0.0;
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vec4 tempf = vec4(0.0);
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float tempResultf;
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int tempResulti;
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ivec4 ARi = ivec4(0);
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bool predResult = true;
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vec3 cubeMapSTM;
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int cubeMapFaceId;
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R0f = passParameterSem0;
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R1f.xyz = (texture(textureUnitPS0, R0f.xy).xyz);
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R1f.xyz *= bloomFactor;
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R0f.xyz = texture(textureUnitPS1, passParameterSem0.xy).xyz;
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float smask = lumaSharpening(textureUnitPS1, passParameterSem0.xy);
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R0f.xyz += vec3(smask);
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// 0
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R126f.x = R1f.x + R0f.x;
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PV0f.x = R126f.x;
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R127f.y = R1f.y + R0f.y;
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PV0f.y = R127f.y;
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R126f.z = R1f.z + R0f.z;
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PV0f.z = R126f.z;
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R125f.w = 1.0;
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// 1
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tempf.x = dot(vec4(PV0f.x,PV0f.y,PV0f.z,-0.0),vec4(intBitsToFloat(0x3e99096c),intBitsToFloat(0x3f162b6b),intBitsToFloat(0x3dea4a8c),0.0));
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PV1f.x = tempf.x;
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PV1f.y = tempf.x;
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PV1f.z = tempf.x;
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PV1f.w = tempf.x;
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// 2
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R127f.x = -(R127f.y) * intBitsToFloat(0x3fb8aa3b);
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PV0f.y = -(PV1f.x) * intBitsToFloat(0x3fb8aa3b);
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R127f.z = -(R126f.x) * intBitsToFloat(0x3fb8aa3b);
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R127f.w = -(R126f.z) * intBitsToFloat(0x3fb8aa3b);
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R126f.w = 1.0 / PV1f.x;
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PS0f = R126f.w;
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// 3
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PS1f = exp2(PV0f.y);
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// 4
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PV0f.x = -(PS1f) + 1.0;
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PS0f = exp2(R127f.x);
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// 5
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R127f.x = -(PS0f) + 1.0;
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R126f.y = mul_nonIEEE(PV0f.x, PV0f.x);
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PV1f.z = PV0f.x * R126f.w;
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PS1f = exp2(R127f.w);
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// 6
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backupReg0f = R126f.x;
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backupReg1f = R127f.z;
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R126f.x = mul_nonIEEE(backupReg0f, PV1f.z);
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PV0f.y = -(PS1f) + 1.0;
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R127f.z = mul_nonIEEE(R126f.z, PV1f.z);
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PV0f.z = R127f.z;
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R127f.w = mul_nonIEEE(R127f.y, PV1f.z);
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PV0f.w = R127f.w;
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PS0f = exp2(backupReg1f);
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// 7
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PV1f.x = R127f.x + -(PV0f.w);
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PV1f.y = PV0f.y + -(PV0f.z);
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PV1f.w = -(PS0f) + 1.0;
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// 8
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backupReg0f = R127f.z;
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R127f.x = (mul_nonIEEE(PV1f.x,R126f.y) + R127f.w);
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R127f.x = clamp(R127f.x, 0.0, 1.0);
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PV0f.x = R127f.x;
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PV0f.y = PV1f.w + -(R126f.x);
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R127f.z = (mul_nonIEEE(PV1f.y,R126f.y) + backupReg0f);
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R127f.z = clamp(R127f.z, 0.0, 1.0);
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PV0f.z = R127f.z;
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// 9
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backupReg0f = R126f.x;
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R126f.x = (mul_nonIEEE(PV0f.y,R126f.y) + backupReg0f);
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R126f.x = clamp(R126f.x, 0.0, 1.0);
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PV1f.x = R126f.x;
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R126f.y = max(PV0f.x, PV0f.z);
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PV1f.w = min(PV0f.x, PV0f.z);
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// 10
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tempf.x = dot(vec4(PV1f.x,R127f.x,R127f.z,R125f.w),vec4(intBitsToFloat(0x3f2aaaab),intBitsToFloat(0x3f2aaaab),intBitsToFloat(0x3f2aaaab),-(1.0)));
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PV0f.x = tempf.x;
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PV0f.y = tempf.x;
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PV0f.z = tempf.x;
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PV0f.w = tempf.x;
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R126f.z = min(PV1f.x, PV1f.w);
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PS0f = R126f.z;
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// 11
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backupReg0f = R127f.x;
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backupReg1f = R127f.z;
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R127f.x = max(R126f.x, R126f.y);
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PV1f.x = R127f.x;
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R123f.y = (mul_nonIEEE(-(PV0f.x),PV0f.x) + 1.0);
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PV1f.y = R123f.y;
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R127f.z = backupReg0f + -(PS0f);
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R125f.w = R126f.x + -(PS0f);
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R126f.y = backupReg1f + -(PS0f);
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PS1f = R126f.y;
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// 12
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R126f.x = (mul_nonIEEE(PV1f.y,intBitsToFloat(uf_remappedPS[0].y)) + intBitsToFloat(uf_remappedPS[0].x));
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PV0f.x = R126f.x;
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PV0f.y = -(R126f.z) + PV1f.x;
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// 13
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R123f.w = (mul_nonIEEE(-(PV0f.x),PV0f.y) + R127f.x);
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PV1f.w = R123f.w;
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// 14
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R0f.x = (mul_nonIEEE(R126f.x,R125f.w) + PV1f.w);
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R0f.y = (mul_nonIEEE(R126f.x,R127f.z) + PV1f.w);
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R0f.z = (mul_nonIEEE(R126f.x,R126f.y) + PV1f.w);
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// export
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passPixelColor0 = vec4(R0f.x, R0f.y, R0f.z, R0f.w);
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vec3 color = (passPixelColor0.xyz);
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color = LevelsPass(color);
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color = CurvesPass(color);
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passPixelColor0 = vec4(color, R0f.w);
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}
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