mirror of
https://github.com/RetroDECK/Supermodel.git
synced 2024-11-24 06:35:41 +00:00
6595b9320e
Some games update the tilegen after the ping_ping bit has flipped at 66% of the frame, so we need to split the tilegen drawing up into two stages to get some effects to work. So having the tilegen draw independantly of the 3d chip can make this happen.
266 lines
7.3 KiB
C
266 lines
7.3 KiB
C
#ifndef _R3DSHADERTRIANGLES_H_
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#define _R3DSHADERTRIANGLES_H_
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static const char *vertexShaderR3D = R"glsl(
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#version 410 core
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// uniforms
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uniform float modelScale;
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uniform float nodeAlpha;
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uniform mat4 modelMat;
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uniform mat4 projMat;
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uniform bool translatorMap;
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// attributes
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in vec4 inVertex;
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in vec3 inNormal;
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in vec2 inTexCoord;
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in vec4 inColour;
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in vec3 inFaceNormal; // used to emulate r3d culling
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in float inFixedShade;
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// outputs to fragment shader
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out vec3 fsViewVertex;
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out vec3 fsViewNormal; // per vertex normal vector
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out vec2 fsTexCoord;
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out vec4 fsColor;
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out float fsDiscard; // can't have varying bool (glsl spec)
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out float fsFixedShade;
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vec4 GetColour(vec4 colour)
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{
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vec4 c = colour;
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if(translatorMap) {
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c.rgb *= 16.0;
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}
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c.a *= nodeAlpha;
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return c;
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}
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float CalcBackFace(in vec3 viewVertex)
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{
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vec3 vt = viewVertex - vec3(0.0);
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vec3 vn = (mat3(modelMat) * inFaceNormal);
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// dot product of face normal with view direction
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return dot(vt, vn);
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}
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void main(void)
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{
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fsViewVertex = vec3(modelMat * inVertex);
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fsViewNormal = (mat3(modelMat) * inNormal) / modelScale;
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fsDiscard = CalcBackFace(fsViewVertex);
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fsColor = GetColour(inColour);
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fsTexCoord = inTexCoord;
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fsFixedShade = inFixedShade;
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gl_Position = projMat * modelMat * inVertex;
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}
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)glsl";
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static const char *fragmentShaderR3D = R"glsl(
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#version 410 core
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uniform usampler2D tex1; // entire texture sheet
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// texturing
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uniform bool textureEnabled;
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uniform bool microTexture;
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uniform float microTextureScale;
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uniform int microTextureID;
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uniform ivec4 baseTexInfo; // x/y are x,y positions in the texture sheet. z/w are with and height
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uniform int baseTexType;
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uniform bool textureInverted;
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uniform bool textureAlpha;
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uniform bool alphaTest;
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uniform bool discardAlpha;
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uniform ivec2 textureWrapMode;
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// general
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uniform vec3 fogColour;
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uniform vec4 spotEllipse; // spotlight ellipse position: .x=X position (screen coordinates), .y=Y position, .z=half-width, .w=half-height)
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uniform vec2 spotRange; // spotlight Z range: .x=start (viewspace coordinates), .y=limit
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uniform vec3 spotColor; // spotlight RGB color
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uniform vec3 spotFogColor; // spotlight RGB color on fog
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uniform vec3 lighting[2]; // lighting state (lighting[0] = sun direction, lighting[1].x,y = diffuse, ambient intensities from 0-1.0)
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uniform bool lightEnabled; // lighting enabled (1.0) or luminous (0.0), drawn at full intensity
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uniform bool sunClamp; // not used by daytona and la machine guns
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uniform bool intensityClamp; // some games such as daytona and
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uniform bool specularEnabled; // specular enabled
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uniform float specularValue; // specular coefficient
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uniform float shininess; // specular shininess
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uniform float fogIntensity;
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uniform float fogDensity;
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uniform float fogStart;
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uniform float fogAttenuation;
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uniform float fogAmbient;
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uniform bool fixedShading;
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uniform int hardwareStep;
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uniform int colourLayer;
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//interpolated inputs from vertex shader
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in vec3 fsViewVertex;
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in vec3 fsViewNormal; // per vertex normal vector
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in vec4 fsColor;
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in vec2 fsTexCoord;
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in float fsDiscard;
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in float fsFixedShade;
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//outputs
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layout(location = 0) out vec4 out0; // opaque
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layout(location = 1) out vec4 out1; // trans layer 1
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layout(location = 2) out vec4 out2; // trans layer 2
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// forward declarations (see common file)
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float CalcFog();
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void Step15Luminous(inout vec4 colour);
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vec4 GetTextureValue();
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void WriteOutputs(vec4 colour, int layer);
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void main()
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{
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vec4 tex1Data;
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vec4 colData;
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vec4 finalData;
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vec4 fogData;
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if(fsDiscard > 0) {
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discard; //emulate back face culling here
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}
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fogData = vec4(fogColour.rgb * fogAmbient, CalcFog());
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tex1Data = vec4(1.0, 1.0, 1.0, 1.0);
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if(textureEnabled) {
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tex1Data = GetTextureValue();
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}
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colData = fsColor;
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Step15Luminous(colData); // no-op for step 2.0+
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finalData = tex1Data * colData;
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if (finalData.a < (1.0/16.0)) { // basically chuck out any totally transparent pixels value = 1/16 the smallest transparency level h/w supports
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discard;
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}
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float ellipse;
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ellipse = length((gl_FragCoord.xy - spotEllipse.xy) / spotEllipse.zw);
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ellipse = pow(ellipse, 2.0); // decay rate = square of distance from center
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ellipse = 1.0 - ellipse; // invert
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ellipse = max(0.0, ellipse); // clamp
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// Compute spotlight and apply lighting
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float enable, absExtent, d, inv_r, range;
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// start of spotlight
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enable = step(spotRange.x, -fsViewVertex.z);
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if (spotRange.y == 0.0) {
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range = 0.0;
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}
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else {
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absExtent = abs(spotRange.y);
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d = spotRange.x + absExtent + fsViewVertex.z;
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d = min(d, 0.0);
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// slope of decay function
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inv_r = 1.0 / (1.0 + absExtent);
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// inverse-linear falloff
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// Reference: https://imdoingitwrong.wordpress.com/2011/01/31/light-attenuation/
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// y = 1 / (d/r + 1)^2
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range = 1.0 / pow(d * inv_r - 1.0, 2.0);
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range *= enable;
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}
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float lobeEffect = range * ellipse;
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float lobeFogEffect = enable * ellipse;
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if (lightEnabled) {
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vec3 lightIntensity;
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vec3 sunVector; // sun lighting vector (as reflecting away from vertex)
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float sunFactor; // sun light projection along vertex normal (0.0 to 1.0)
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// Sun angle
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sunVector = lighting[0];
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// Compute diffuse factor for sunlight
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if(fixedShading) {
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sunFactor = fsFixedShade;
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}
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else {
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sunFactor = dot(sunVector, fsViewNormal);
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}
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// Clamp ceil, fix for upscaled models without "modelScale" defined
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sunFactor = clamp(sunFactor,-1.0,1.0);
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// Optional clamping, value is allowed to be negative
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if(sunClamp) {
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sunFactor = max(sunFactor,0.0);
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}
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// Total light intensity: sum of all components
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lightIntensity = vec3(sunFactor*lighting[1].x + lighting[1].y); // diffuse + ambient
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lightIntensity.rgb += spotColor*lobeEffect;
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// Upper clamp is optional, step 1.5+ games will drive brightness beyond 100%
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if(intensityClamp) {
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lightIntensity = min(lightIntensity,1.0);
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}
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finalData.rgb *= lightIntensity;
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// for now assume fixed shading doesn't work with specular
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if (specularEnabled) {
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float exponent, NdotL, specularFactor;
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vec4 biasIndex, expIndex, multIndex;
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// Always clamp floor to zero, we don't want deep black areas
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NdotL = max(0.0,sunFactor);
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expIndex = vec4(8.0, 16.0, 32.0, 64.0);
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multIndex = vec4(2.0, 2.0, 3.0, 4.0);
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biasIndex = vec4(0.95, 0.95, 1.05, 1.0);
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exponent = expIndex[int(shininess)] / biasIndex[int(shininess)];
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specularFactor = pow(NdotL, exponent);
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specularFactor *= multIndex[int(shininess)];
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specularFactor *= biasIndex[int(shininess)];
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specularFactor *= specularValue;
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specularFactor *= lighting[1].x;
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if (colData.a < 1.0) {
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/// Specular hi-light affects translucent polygons alpha channel ///
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finalData.a = max(finalData.a, specularFactor);
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}
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finalData.rgb += vec3(specularFactor);
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}
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}
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// Final clamp: we need it for proper shading in dimmed light and dark ambients
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finalData.rgb = min(finalData.rgb, vec3(1.0));
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// Spotlight on fog
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vec3 lSpotFogColor = spotFogColor * fogAttenuation * fogColour.rgb * lobeFogEffect;
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// Fog & spotlight applied
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finalData.rgb = mix(finalData.rgb, fogData.rgb + lSpotFogColor, fogData.a);
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// Write outputs to colour buffers
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WriteOutputs(finalData,colourLayer);
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}
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)glsl";
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#endif |