mirror of
https://github.com/italicsjenga/slang-shaders.git
synced 2024-11-24 16:41:31 +11:00
227 lines
9.1 KiB
Plaintext
227 lines
9.1 KiB
Plaintext
#version 450
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#include "config.inc"
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#define RGB_SHIFT_RANGE 20
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#pragma stage vertex
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layout(location = 0) in vec4 Position;
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layout(location = 1) in vec2 TexCoord;
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layout(location = 0) out vec2 vTexCoord;
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layout(location = 1) out vec2 vR_offset;
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layout(location = 2) out vec2 vG_offset;
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layout(location = 3) out vec2 vB_offset;
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layout(location = 4) out float vDo_shadow_mode;
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#include "includes/functions.include.slang"
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void main()
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{
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gl_Position = global.MVP * Position;
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vTexCoord = TexCoord ;
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//...to tell fragment shader if dot matrix feature requests shadows.
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vDo_shadow_mode = float(DOT_M_SHADOW_STR + DO_DOT_MATRIX > 1 + eps);
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//Shadow mode disables deconvergence, they do not coexist in real life.
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if (vDo_shadow_mode == 1.0) {
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vR_offset = vec2(DOT_M_SHADOW_OFF, abs(DOT_M_SHADOW_OFF));
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vG_offset = vR_offset;
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vB_offset = vR_offset;
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} else if (DO_SHIFT_RGB == 1.0) {
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vR_offset=offsets_from_float(SHIFT_R+210.0,RGB_SHIFT_RANGE);
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vG_offset=offsets_from_float(SHIFT_G+210.0,RGB_SHIFT_RANGE);
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vB_offset=offsets_from_float(SHIFT_B+210.0,RGB_SHIFT_RANGE);
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}
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}
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#pragma stage fragment
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#include "includes/functions.include.slang"
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layout(location = 0) in vec2 vTexCoord;
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layout(location = 1) in vec2 vR_offset;
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layout(location = 2) in vec2 vG_offset;
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layout(location = 3) in vec2 vB_offset;
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layout(location = 4) in float vDo_shadow_mode;
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layout(location = 0) out vec4 FragColor;
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layout(set = 0, binding = 3) uniform sampler2D FXAA_pass;
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layout(set = 0, binding = 4) uniform sampler2D flick_and_noise_pass;
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layout(set = 0, binding = 5) uniform sampler2D colortools_and_ntsc_pass;
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#define bandwidth_mhz_Y_ntsc 4.2
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#define bandwidth_mhz_I 1.5
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#define bandwidth_mhz_Q 0.5
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const mat3 mat3_RGB2YIQ = mat3(
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0.2989, 0.5959, 0.2115,
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0.5870, -0.2744, -0.5229,
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0.1140, -0.3216, 0.3114);
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const mat3 mat3_YIQ2RGB = mat3(
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1.0, 1.0, 1.0,
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0.956, -0.2720, -1.1060,
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0.6210, -0.6474, 1.7046);
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//https://www.sciencedirect.com/topics/computer-science/color-subcarrier
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#define bandwidth_mhz_Y_pal 5.0
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#define bandwidth_mhz_U 1.3
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#define bandwidth_mhz_V 1.3
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const mat3 mat3_RGB2YUV = mat3(
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0.299, 0.587, 0.114,
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-0.14713, -0.28886, 0.436,
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0.615, -0.514991, -0.10001);
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const mat3 mat3_YUV2RGB = mat3(
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1.000, 0.000, 1.13983,
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1.000,-0.39465,-0.58060,
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1.000, 2.03211, 0.00000);
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vec3 deconvergence_shadow(vec3 pixel_cur,vec2 coord, sampler2D in_texture, vec4 sourcesize2) {
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//Emulates deconvergence or shadowing for dot matrix screens like Gameboy.
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//Since both effects should not coexist in real life, we use a singe function for both.
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//The function stays more or less the same, but rgb offsets calculated in vertex shader
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//will be the same for shadow mode. Hopefully shader texture cache will take care of
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//multiple sampling for the same tex coords.
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vec2 d = -vec2(sourcesize2.z, sourcesize2.w)*0.5;
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vec3 pixel_offset;
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pixel_offset.r=texture(in_texture,coord + vR_offset * d).r;
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pixel_offset.g=texture(in_texture,coord + vG_offset * d).g;
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pixel_offset.b=texture(in_texture,coord + vB_offset * d).b;
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vec3 deconvergence_mode = mix(pixel_cur, pixel_offset, OFFSET_STRENGTH);
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vec3 shadow_mode = pixel_cur - max( (pixel_cur - pixel_offset), vec3(0.0) ) * DOT_M_SHADOW_STR;
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return mix_step(deconvergence_mode, shadow_mode, vDo_shadow_mode);
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//Shadow mode:
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//return pixel_cur -
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// max( (pixel_cur - pixel_offset), vec3(0.0) ) * OFFSET_STRENGTH;
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}
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vec3 deconvergence_shadow_wrap (vec2 coord) {
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if ( DO_FXAA == 1.0) {
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return deconvergence_shadow(texture(FXAA_pass, vTexCoord).rgb, vTexCoord, FXAA_pass, global.FXAA_passSize);
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} else {
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return deconvergence_shadow(texture(flick_and_noise_pass, vTexCoord).rgb, vTexCoord, flick_and_noise_pass, global.flick_and_noise_passSize);
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}
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}
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vec3 pixel_bleed_side_NTSC(vec3 pixel_in, vec2 co, float size, float side, sampler2D in_texture, vec4 sourcesize2) {
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//apply strength modifier to blur ntsc artifacts more.
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float strength_modifier = mix(1.0, texture(colortools_and_ntsc_pass,co).a, DO_NTSC_ARTIFACTS);
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if (NTSC_SHOW_ARTF_MASK + DO_NTSC_ARTIFACTS == 2.0) return vec3(strength_modifier);
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float w = SAT_BLEED_STRENGTH * clamp (strength_modifier, (1-NTSC_ARTF_NOBLEED), 1.0 );
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vec3 blur_YIQ = pixel_in * mat3_RGB2YIQ; //Work in YIQ space
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float i = 0.0;
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for ( i=1 ; i <= size ; i++ ){
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w=w/SAT_BLEED_FALLOFF;
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//w = w * exp(i*i*(1-SAT_BLEED_FALLOFF)*0.1);
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//w=clamp(w,0.0,1.0);
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vec3 smp_YIQ = texture(flick_and_noise_pass, co - side * vec2(sourcesize2.z*i,0.0)).rgb * mat3_RGB2YIQ;
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blur_YIQ.x = mix(blur_YIQ.x, smp_YIQ.x, w/bandwidth_mhz_Y_ntsc); // Blur Y
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blur_YIQ.y = mix(blur_YIQ.y, smp_YIQ.y, w/bandwidth_mhz_I ); // Blur I
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blur_YIQ.z = mix(blur_YIQ.z, smp_YIQ.z, w/bandwidth_mhz_Q ); // BlurQ
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//Tried to optimize as follows to no avail:
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//vec3 vec3_mix = vec3(w/bandwidth_mhz_Y_ntsc, w/bandwidth_mhz_I, w/bandwidth_mhz_Q);
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//blur_YIQ = mix(blur_YIQ.xyz, smp_YIQ.xyz, vec3_mix);
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}
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//blur_YIQ.z/=i;
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return blur_YIQ.xyz * mat3_YIQ2RGB; //return to RGB colorspace
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}
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vec3 pixel_bleed_side_PAL(vec3 pixel_in, vec2 co, float size, float side, sampler2D in_texture, vec4 sourcesize2) {
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float w = SAT_BLEED_STRENGTH;
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vec3 blur_YUV = pixel_in * mat3_RGB2YUV; //Work in YIQ space
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float i = 0.0;
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for ( i=1 ; i <= size ; i++ ){
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w=w/SAT_BLEED_FALLOFF;
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//w=clamp(w,0.0,1.0);
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vec3 smp_YUV = texture(flick_and_noise_pass, co - side * vec2(sourcesize2.z*i,0.0)).rgb * mat3_RGB2YUV;
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blur_YUV.x = mix(blur_YUV.x, smp_YUV.x, w/bandwidth_mhz_Y_pal); // Blur Y
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blur_YUV.y = mix(blur_YUV.y, smp_YUV.y, w/bandwidth_mhz_U ); // Blur U
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blur_YUV.z = mix(blur_YUV.z, smp_YUV.z, w/bandwidth_mhz_V ); // Blur V
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}
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return blur_YUV.xyz * mat3_YUV2RGB; //return to RGB colorspace
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}
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#define SIDE_RIGHT 1
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#define SIDE_LEFT -1
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vec3 pixel_bleed(vec3 pixel_in, vec2 co, sampler2D in_texture, vec4 sourcesize2) {
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vec3 side_left ; vec3 side_right;
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//Tried to unbranch the following, no gain (even worse) probably due to not using constants anymore.
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//Just dont try again.
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if (SAT_BLEED_PAL == 1.0) {
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side_right = pixel_bleed_side_PAL(pixel_in, co, SAT_BLEED_SIZE_RIGHT, SIDE_RIGHT, in_texture, sourcesize2);
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side_left = pixel_bleed_side_PAL(pixel_in, co, SAT_BLEED_SIZE_LEFT, SIDE_LEFT, in_texture, sourcesize2);
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} else {
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side_right = pixel_bleed_side_NTSC(pixel_in, co, SAT_BLEED_SIZE_RIGHT, SIDE_RIGHT, in_texture, sourcesize2);
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side_left = pixel_bleed_side_NTSC(pixel_in, co, SAT_BLEED_SIZE_LEFT, SIDE_LEFT, in_texture, sourcesize2);
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}
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//Clamping min to 0.0 is needed for nvidia to avoid bad graphical glitches, why?
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return max( mix(side_left,side_right,0.5), 0.0) ;
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}
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void main() {
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float pixel_alpha_ntsc_artifacts; // <- this holds ntsc artifacts needed by glow to modulate blur there.
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vec3 pixel_out;
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//Handle case where both are needed:
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//First shift the right source, then pass it to bleed function.
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if (DO_SHIFT_RGB + DO_SAT_BLEED > 1.0 || DOT_M_SHADOW_STR > 0.0 ) {
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pixel_out = deconvergence_shadow_wrap(vTexCoord);
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if (DO_SAT_BLEED > 0.0) {
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if ( DO_FXAA == 1.0) {
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pixel_out = pixel_bleed(pixel_out, vTexCoord, FXAA_pass, global.FXAA_passSize);
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pixel_alpha_ntsc_artifacts = texture(FXAA_pass, vTexCoord).a;
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} else {
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pixel_out = pixel_bleed(pixel_out, vTexCoord, flick_and_noise_pass, global.flick_and_noise_passSize);
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pixel_alpha_ntsc_artifacts = texture(flick_and_noise_pass, vTexCoord).a;
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}
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}
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} else
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//Handle case where only color shifting is requested
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if (DO_SHIFT_RGB > 0.0 || DOT_M_SHADOW_STR > 0.0) {
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pixel_out = deconvergence_shadow_wrap(vTexCoord);
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pixel_alpha_ntsc_artifacts = texture(flick_and_noise_pass, vTexCoord).a;
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} else
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if (DO_SAT_BLEED > 0.0) {
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//Handle case where only chroma bleed is requested
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if ( DO_FXAA == 1.0) {
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pixel_out = texture(FXAA_pass, vTexCoord).rgb;
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pixel_alpha_ntsc_artifacts = texture(FXAA_pass, vTexCoord).a;
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pixel_out = pixel_bleed(pixel_out, vTexCoord, FXAA_pass, global.FXAA_passSize);
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} else {
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pixel_out = texture(flick_and_noise_pass, vTexCoord).rgb;
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pixel_alpha_ntsc_artifacts = texture(flick_and_noise_pass, vTexCoord).a;
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pixel_out = pixel_bleed(pixel_out, vTexCoord, flick_and_noise_pass, global.flick_and_noise_passSize);
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}
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} else
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//Passthrough
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if ( DO_FXAA == 1.0) {
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pixel_out = texture(FXAA_pass, vTexCoord).rgb;
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pixel_alpha_ntsc_artifacts = texture(FXAA_pass, vTexCoord).a;
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} else {
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pixel_out = texture(flick_and_noise_pass, vTexCoord).rgb;
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pixel_alpha_ntsc_artifacts = texture(flick_and_noise_pass, vTexCoord).a;
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}
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//pre-gamma if needed by glow.
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if (DO_CCORRECTION > 0.5)
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pixel_out = pow(pixel_out, vec3(IN_GLOW_GAMMA));
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FragColor = vec4(pixel_out,pixel_alpha_ntsc_artifacts);
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}
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