mirror of
https://github.com/RetroDECK/Duckstation.git
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151 lines
5 KiB
HLSL
151 lines
5 KiB
HLSL
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#include "ReShade.fxh"
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/*
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zfast_crt_geo - A simple, fast CRT shader.
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Copyright (C) 2017 Greg Hogan (SoltanGris42)
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Copyright (C) 2023 Jose Linares (Dogway)
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This program is free software; you can redistribute it and/or modify it
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under the terms of the GNU General Public License as published by the Free
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Software Foundation; either version 2 of the License, or (at your option)
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any later version.
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Notes: This shader does scaling with a weighted linear filter
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based on the algorithm by Iñigo Quilez here:
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https://iquilezles.org/articles/texture/
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but modified to be somewhat sharper. Then a scanline effect that varies
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based on pixel brightness is applied along with a monochrome aperture mask.
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This shader runs at ~60fps on the Chromecast HD (10GFlops) on a 1080p display.
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(https://forums.libretro.com/t/android-googletv-compatible-shaders-nitpicky)
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Dogway: I modified zfast_crt.glsl shader to include screen curvature,
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vignetting, round corners and phosphor*temperature. Horizontal pixel is left out
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from the Quilez' algo (read above) to provide a more S-Video like horizontal blur.
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The scanlines and mask are also now performed in the recommended linear light.
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For this to run smoothly on GPU deprived platforms like the Chromecast and
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older consoles, I had to remove several parameters and hardcode them into the shader.
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Another POV is to run the shader on handhelds like the Switch or SteamDeck so they consume less battery.
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*/
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uniform float SCANLINE_WEIGHT <
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ui_type = "drag";
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ui_min = 0.0;
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ui_max = 15.0;
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ui_step = 0.5;
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ui_label = "Scanline Amount";
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> = 7.0;
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uniform float MASK_DARK <
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ui_type = "drag";
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ui_min = 0.0;
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ui_max = 1.0;
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ui_step = 0.05;
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ui_label = "Mask Effect Amount";
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> = 0.5;
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uniform float2 NormalizedNativePixelSize < source = "normalized_native_pixel_size"; >;
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uniform float BufferWidth < source = "bufferwidth"; >;
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uniform float BufferHeight < source = "bufferheight"; >;
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sampler2D sBackBuffer{Texture=ReShade::BackBufferTex;AddressU=CLAMP;AddressV=CLAMP;AddressW=CLAMP;MagFilter=LINEAR;MinFilter=LINEAR;};
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struct ST_VertexOut
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{
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float2 invDims : TEXCOORD1;
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};
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// Vertex shader generating a triangle covering the entire screen
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void VS_CRT_Geo_zFast(in uint id : SV_VertexID, out float4 position : SV_Position, out float2 texcoord : TEXCOORD, out ST_VertexOut vVARS)
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{
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texcoord.x = (id == 2) ? 2.0 : 0.0;
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texcoord.y = (id == 1) ? 2.0 : 0.0;
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position = float4(texcoord * float2(2.0, -2.0) + float2(-1.0, 1.0), 0.0, 1.0);
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vVARS.invDims = NormalizedNativePixelSize;
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}
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#define MSCL (BufferHeight > 1499.0 ? 0.3333 : 0.5)
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// This compensates the scanline+mask embedded gamma from the beam dynamics
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#define pwr ((1.0/((-0.0325*SCANLINE_WEIGHT+1.0)*(-0.311*MASK_DARK+1.0))-1.2).xxx)
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// NTSC-J (D93) -> Rec709 D65 Joint Matrix (with D93 simulation)
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// This is compensated for a linearization hack (RGB*RGB and then sqrt())
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static const float3x3 P22D93 = float3x3(
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1.00000, 0.00000, -0.06173,
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0.07111, 0.96887, -0.01136,
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0.00000, 0.08197, 1.07280);
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// Returns gamma corrected output, compensated for scanline+mask embedded gamma
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float3 inv_gamma(float3 col, float3 power)
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{
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float3 cir = col-1.0;
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cir *= cir;
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col = lerp(sqrt(col),sqrt(1.0-cir),power);
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return col;
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}
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float2 Warp(float2 pos)
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{
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pos = pos*2.0-1.0;
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pos *= float2(1.0 + (pos.y*pos.y)*0.0276, 1.0 + (pos.x*pos.x)*0.0414);
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return pos*0.5 + 0.5;
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}
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float4 PS_CRT_Geo_zFast(float4 vpos: SV_Position, float2 vTexCoord : TEXCOORD0, in ST_VertexOut vVARS) : SV_Target
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{
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float2 pos = vTexCoord;
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float2 xy = Warp(pos);
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float2 corn = min(xy,1.0-xy); // This is used to mask the rounded
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corn.x = 0.0001/corn.x; // corners later on
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pos *= (1.0 - pos.xy);
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float vig = pos.x * pos.y * 46.0;
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vig = min(sqrt(vig), 1.0);
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// Of all the pixels that are mapped onto the texel we are
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// currently rendering, which pixel are we currently rendering?
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float ratio_scale = xy.y / NormalizedNativePixelSize.y - 0.5;
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// Snap to the center of the underlying texel.
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float i = floor(ratio_scale) + 0.5;
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// This is just like "Quilez Scaling" but sharper
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float f = ratio_scale - i;
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float Y = f*f;
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float p = (i + 4.0*Y*f)*vVARS.invDims.y;
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float whichmask = floor(vTexCoord.x*BufferWidth)*(-MSCL);
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float mask = 1.0 + float(frac(whichmask) < MSCL)*(-MASK_DARK);
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float3 colour = tex2D(sBackBuffer, float2(xy.x,p)).rgb;
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colour = max(mul(P22D93 * vig, colour*colour), 0.0.xxx);
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float scanLineWeight = (1.5 - SCANLINE_WEIGHT*(Y - Y*Y));
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if (corn.y <= corn.x || corn.x < 0.0001 )
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colour = 0.0.xxx;
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return float4(inv_gamma(colour.rgb*lerp(scanLineWeight*mask, 1.0, colour.r*0.26667+colour.g*0.26667+colour.b*0.26667),pwr),1.0);
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}
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technique CRT_Geo_zFast
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{
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pass
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{
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VertexShader = VS_CRT_Geo_zFast;
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PixelShader = PS_CRT_Geo_zFast;
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}
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}
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