mirror of
https://github.com/ZDoom/raze-gles.git
synced 2024-11-07 05:21:12 +00:00
cf30f5560b
The only compatibility mode feature left is the main drawer function using glBegin/glEnd but changing that is not as urgent as the rest. This also cleans up the fog application and adds the exponential fog mode again that somehow got lost over time.
197 lines
6.8 KiB
GLSL
197 lines
6.8 KiB
GLSL
#version 330
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//s_texture points to an indexed color texture
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uniform sampler2D s_texture;
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//s_palswap is the palette swap texture where u is the color index and v is the shade
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uniform sampler2D s_palswap;
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//s_palette is the base palette texture where u is the color index
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uniform sampler2D s_palette;
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uniform sampler2D s_detail;
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uniform sampler2D s_glow;
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uniform vec2 u_palswapPos;
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uniform vec2 u_palswapSize;
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uniform vec2 u_clamp;
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uniform float u_shade;
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uniform float u_numShades;
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uniform float u_visFactor;
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uniform float u_fogEnabled;
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uniform float u_useColorOnly;
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uniform float u_usePalette;
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uniform float u_npotEmulation;
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uniform float u_npotEmulationFactor;
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uniform float u_npotEmulationXOffset;
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uniform float u_shadeInterpolate;
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uniform float u_brightness;
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uniform vec4 u_fog;
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uniform vec4 u_fogColor;
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uniform float u_useDetailMapping;
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uniform float u_useGlowMapping;
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uniform int u_tinteffect;
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uniform vec3 u_tintcolor;
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in vec4 v_color;
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in float v_distance;
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in vec4 v_texCoord;
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in vec4 v_detailCoord;
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in vec4 v_glowCoord;
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in float v_fogCoord;
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const float c_basepalScale = 255.0/256.0;
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const float c_basepalOffset = 0.5/256.0;
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const float c_zero = 0.0;
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const float c_one = 1.0;
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const float c_two = 2.0;
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const vec4 c_vec4_one = vec4(c_one);
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const float c_wrapThreshold = 0.9;
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layout(location=0) out vec4 fragColor;
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layout(std140) uniform Palette {
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vec4 palette[256];
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};
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layout(std140) uniform Palswap {
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int palswap[256];
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};
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//===========================================================================
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//
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// Color to grayscale
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//
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//===========================================================================
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float grayscale(vec4 color)
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{
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return dot(color.rgb, vec3(0.3, 0.56, 0.14));
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}
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//===========================================================================
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//
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// Hightile tinting code. (hictinting[dapalnum]) This can be done inside the shader
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// to avoid costly texture duplication (but needs a more modern GLSL than 1.10.)
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//
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//===========================================================================
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vec4 convertColor(vec4 color, int effect, vec3 tint)
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{
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#if 0
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if (effect & HICTINT_GRAYSCALE)
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{
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float g = grayscale(color);
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color = vec4(g, g, g, color.a);
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}
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if (effect & HICTINT_INVERT)
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{
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color = vec4(1.0 - color.r, 1.0 - color.g, 1.0 - color.b);
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}
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vec3 tcol = color.rgb * 255.0; // * 255.0 to make it easier to reuse the integer math.
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tint *= 255.0;
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if (effect & HICTINT_COLORIZE)
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{
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tcol.b = min(((tcol.b) * tint.r) / 64.0, 255.0);
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tcol.g = min(((tcol.g) * tint.g) / 64.0, 255.0);
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tcol.r = min(((tcol.r) * tint.b) / 64.0, 255.0);
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}
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switch (effect & HICTINT_BLENDMASK)
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{
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case HICTINT_BLEND_SCREEN:
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tcol.b = 255.0 - (((255.0 - tcol.b) * (255.0 - tint.r)) / 256.0);
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tcol.g = 255.0 - (((255.0 - tcol.g) * (255.0 - tint.g)) / 256.0);
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tcol.r = 255.0 - (((255.0 - tcol.r) * (255.0 - tint.b)) / 256.0);
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break;
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case HICTINT_BLEND_OVERLAY:
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tcol.b = tcol.b < 128.0? (tcol.b * tint.r) / 128.0 : 255.0 - (((255.0 - tcol.b) * (255.0 - tint.r)) / 128.0);
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tcol.g = tcol.g < 128.0? (tcol.g * tint.g) / 128.0 : 255.0 - (((255.0 - tcol.g) * (255.0 - tint.g)) / 128.0);
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tcol.r = tcol.r < 128.0? (tcol.r * tint.b) / 128.0 : 255.0 - (((255.0 - tcol.r) * (255.0 - tint.b)) / 128.0);
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break;
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case HICTINT_BLEND_HARDLIGHT:
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tcol.b = tint.r < 128.0 ? (tcol.b * tint.r) / 128.0 : 255.0 - (((255.0 - tcol.b) * (255.0 - r)) / 128.0);
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tcol.g = tint.g < 128.0 ? (tcol.g * tint.g) / 128.0 : 255.0 - (((255.0 - tcol.g) * (255.0 - g)) / 128.0);
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tcol.r = tint.b < 128.0 ? (tcol.r * tint.b) / 128.0 : 255.0 - (((255.0 - tcol.r) * (255.0 - b)) / 128.0);
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break;
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}
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color.rgb = tcol / 255.0;
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#endif
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return color;
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}
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//===========================================================================
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//
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// Talk about all the wrong way of being 'efficient'... :(
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//
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//===========================================================================
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void main()
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{
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float coordY = mix(v_texCoord.y,v_texCoord.x,u_usePalette);
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float coordX = mix(v_texCoord.x,v_texCoord.y,u_usePalette);
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float period = floor(coordY/u_npotEmulationFactor);
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coordX += u_npotEmulationXOffset*floor(mod(coordY,u_npotEmulationFactor));
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coordY = period+mod(coordY,u_npotEmulationFactor);
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vec2 newCoord = mix(v_texCoord.xy,mix(vec2(coordX,coordY),vec2(coordY,coordX),u_usePalette),u_npotEmulation);
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vec2 transitionBlend = fwidth(floor(newCoord.xy));
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transitionBlend = fwidth(transitionBlend)+transitionBlend;
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vec2 texCoord = mix(mix(fract(newCoord.xy), abs(c_one-mod(newCoord.xy+c_one, c_two)), transitionBlend), clamp(newCoord.xy, c_zero, c_one), u_clamp);
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vec4 color = texture2D(s_texture, texCoord);
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float shade = clamp((u_shade+max(u_visFactor*v_distance-0.5*u_shadeInterpolate,c_zero)), c_zero, u_numShades-c_one);
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float shadeFrac = mod(shade, c_one);
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float colorIndex = texture2D(s_palswap, u_palswapPos+u_palswapSize*vec2(color.r, floor(shade)/u_numShades)).r;
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colorIndex = c_basepalOffset + c_basepalScale*colorIndex;
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vec4 palettedColor = texture2D(s_palette, vec2(colorIndex, c_zero));
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colorIndex = texture2D(s_palswap, u_palswapPos+u_palswapSize*vec2(color.r, (floor(shade)+c_one)/u_numShades)).r;
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colorIndex = c_basepalOffset + c_basepalScale*colorIndex;
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vec4 palettedColorNext = texture2D(s_palette, vec2(colorIndex, c_zero));
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palettedColor.rgb = mix(palettedColor.rgb, palettedColorNext.rgb, shadeFrac*u_shadeInterpolate);
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float fullbright = mix(u_usePalette*palettedColor.a, c_zero, u_useColorOnly); // This only gets set for paletted rendering.
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palettedColor.a = c_one-floor(color.r);
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color = mix(color, palettedColor, u_usePalette);
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if (u_useDetailMapping != 0.0)
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{
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vec4 detailColor = texture2D(s_detail, v_detailCoord.xy);
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detailColor = mix(c_vec4_one, 2.0*detailColor, detailColor.a);
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color.rgb *= detailColor.rgb;
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}
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// should be an 'else' to all the above.
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color = mix(color, c_vec4_one, u_useColorOnly);
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// only relevant for paletted rendering - in true color this requires a fifth color channel (i.e. an external brightmap - work for later) or an overlay (current implementation)
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color.rgb = mix(v_color.rgb*color.rgb, color.rgb, fullbright);
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if (u_usePalette == 0.0 && u_fogEnabled != 0.0)// the following would make sense if 'fullbright' could ever be true in non-paletted rendering: && (fullbright != 0.0 || u_fogColor.rgb != vec3(0.0) ))
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{
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float fogFactor;
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if (u_fog.z == 0) fogFactor = (u_fog.x-v_fogCoord)*u_fog.y; // linear fog
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else fogFactor = exp2 (u_fog.z * v_fogCoord); // exponential fog
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fogFactor = clamp(fogFactor, 0.0, 1.0);
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color.rgb = mix(u_fogColor.rgb, color.rgb, fogFactor);
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}
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if (u_useGlowMapping != 0.0 && u_useColorOnly == 0.0)
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{
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vec4 glowColor = texture2D(s_glow, v_glowCoord.xy);
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color.rgb = mix(color.rgb, glowColor.rgb, glowColor.a);
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}
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color.a *= v_color.a;
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color.rgb = pow(color.rgb, vec3(u_brightness));
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fragColor = color;
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}
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