151 lines
4.2 KiB
GLSL
151 lines
4.2 KiB
GLSL
#version 330
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in vec3 fragPosition;
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in vec2 fragTexCoord;
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in vec4 fragColor;
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in vec3 fragNormal;
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out vec4 finalColor;
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uniform sampler2D texture0;
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uniform sampler2D texture1;
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uniform sampler2D texture2;
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uniform vec4 colAmbient;
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uniform vec4 colDiffuse;
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uniform vec4 colSpecular;
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uniform float glossiness;
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uniform int useNormal;
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uniform int useSpecular;
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uniform mat4 modelMatrix;
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uniform vec3 viewDir;
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struct Light {
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int enabled;
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int type;
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vec3 position;
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vec3 direction;
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vec4 diffuse;
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float intensity;
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float radius;
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float coneAngle;
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};
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const int maxLights = 8;
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uniform Light lights[maxLights];
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vec3 CalcPointLight(Light l, vec3 n, vec3 v, float s)
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{
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vec3 surfacePos = vec3(modelMatrix*vec4(fragPosition, 1));
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vec3 surfaceToLight = l.position - surfacePos;
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// Diffuse shading
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float brightness = clamp(dot(n, surfaceToLight)/(length(surfaceToLight)*length(n)), 0, 1);
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float diff = 1.0/dot(surfaceToLight/l.radius, surfaceToLight/l.radius)*brightness*l.intensity;
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// Specular shading
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float spec = 0.0;
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if (diff > 0.0)
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{
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vec3 h = normalize(-l.direction + v);
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spec = pow(dot(n, h), 3 + glossiness)*s;
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}
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return (diff*l.diffuse.rgb + spec*colSpecular.rgb);
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}
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vec3 CalcDirectionalLight(Light l, vec3 n, vec3 v, float s)
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{
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vec3 lightDir = normalize(-l.direction);
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// Diffuse shading
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float diff = clamp(dot(n, lightDir), 0.0, 1.0)*l.intensity;
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// Specular shading
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float spec = 0.0;
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if (diff > 0.0)
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{
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vec3 h = normalize(lightDir + v);
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spec = pow(dot(n, h), 3 + glossiness)*s;
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}
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// Combine results
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return (diff*l.intensity*l.diffuse.rgb + spec*colSpecular.rgb);
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}
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vec3 CalcSpotLight(Light l, vec3 n, vec3 v, float s)
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{
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vec3 surfacePos = vec3(modelMatrix*vec4(fragPosition, 1));
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vec3 lightToSurface = normalize(surfacePos - l.position);
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vec3 lightDir = normalize(-l.direction);
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// Diffuse shading
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float diff = clamp(dot(n, lightDir), 0.0, 1.0)*l.intensity;
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// Spot attenuation
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float attenuation = clamp(dot(n, lightToSurface), 0.0, 1.0);
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attenuation = dot(lightToSurface, -lightDir);
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float lightToSurfaceAngle = degrees(acos(attenuation));
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if (lightToSurfaceAngle > l.coneAngle) attenuation = 0.0;
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float falloff = (l.coneAngle - lightToSurfaceAngle)/l.coneAngle;
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// Combine diffuse and attenuation
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float diffAttenuation = diff*attenuation;
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// Specular shading
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float spec = 0.0;
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if (diffAttenuation > 0.0)
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{
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vec3 h = normalize(lightDir + v);
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spec = pow(dot(n, h), 3 + glossiness)*s;
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}
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return (falloff*(diffAttenuation*l.diffuse.rgb + spec*colSpecular.rgb));
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}
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void main()
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{
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// Calculate fragment normal in screen space
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// NOTE: important to multiply model matrix by fragment normal to apply model transformation (rotation and scale)
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mat3 normalMatrix = transpose(inverse(mat3(modelMatrix)));
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vec3 normal = normalize(normalMatrix*fragNormal);
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// Normalize normal and view direction vectors
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vec3 n = normalize(normal);
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vec3 v = normalize(viewDir);
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// Calculate diffuse texture color fetching
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vec4 texelColor = texture(texture0, fragTexCoord);
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vec3 lighting = colAmbient.rgb;
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// Calculate normal texture color fetching or set to maximum normal value by default
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if (useNormal == 1)
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{
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n *= texture(texture1, fragTexCoord).rgb;
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n = normalize(n);
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}
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// Calculate specular texture color fetching or set to maximum specular value by default
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float spec = 1.0;
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if (useSpecular == 1) spec *= normalize(texture(texture2, fragTexCoord).r);
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for (int i = 0; i < maxLights; i++)
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{
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// Check if light is enabled
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if (lights[i].enabled == 1)
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{
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// Calculate lighting based on light type
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if(lights[i].type == 0) lighting += CalcPointLight(lights[i], n, v, spec);
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else if(lights[i].type == 1) lighting += CalcDirectionalLight(lights[i], n, v, spec);
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else if(lights[i].type == 2) lighting += CalcSpotLight(lights[i], n, v, spec);
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}
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}
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// Calculate final fragment color
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finalColor = vec4(texelColor.rgb*lighting*colDiffuse.rgb, texelColor.a*colDiffuse.a);
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}
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