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Author | SHA1 | Date |
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Cat Flynn | 202ec0673f |
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@ -1,9 +1,10 @@
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const float INF = 45.0;
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const float INF = 20.0;
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const float PI = 3.14159;
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const float E = 2.71828;
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const int BOUNCES = 5;
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const int BOUNCES = 4;
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// materials
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const int MAT_SKY = -1;
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const int MAT_LAMBERT = 0;
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const int MAT_CHROME = 1;
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const int MAT_GLOW = 2;
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@ -12,5 +12,8 @@ float getLogarithmicDepth(float distance)
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float z = distance;
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// logarithmic depth
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return max(0,log(z*pow(E,n)/f)/n);
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float d = log(z*pow(E,n)/f)/n;
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//d = d < 0 ? 1 : d;
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return d;
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//return max(0,d);
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}
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@ -21,6 +21,29 @@ void intersectSphere(Ray ray, inout RayHit bestHit, Sphere sphere)
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}
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}
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void intersectInsideOutSphere(Ray ray, inout RayHit bestHit, Sphere sphere)
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{
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vec3 c = sphere.cr.xyz;
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float r = sphere.cr.w;
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vec3 d = ray.origin-c;
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float p1 = -dot(ray.direction,d);
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float p2sqr = p1*p1-dot(d,d)+r*r;
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if (p2sqr < 0) return;
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float p2 = sqrt(p2sqr);
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float t = p1-p2 > 0 ? p1-p2 : p1+p2;
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if (t > 0 && t < bestHit.distance)
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{
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bestHit.distance = t;
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bestHit.position = ray.origin + t * ray.direction;
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bestHit.normal = -normalize(bestHit.position-c);
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bestHit.albedo = sphere.albedo;
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bestHit.material = sphere.material;
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}
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}
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void intersectPlane(Ray ray, inout RayHit bestHit, vec3 p, vec3 normal)
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{
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float denom = dot(normal, ray.direction);
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@ -33,7 +56,7 @@ void intersectPlane(Ray ray, inout RayHit bestHit, vec3 p, vec3 normal)
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bestHit.distance = t;
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bestHit.position = ray.origin + t*ray.direction;
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bestHit.normal = normal;
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bestHit.albedo = vec3(1.0,.4,.4);
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bestHit.albedo = vec3(1.0,.8,.7);
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bestHit.material = MAT_LAMBERT;
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}
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}
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@ -35,18 +35,30 @@ vec3 sampleHemisphere(vec3 normal)
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vec3 scatterMetal(inout Ray ray, RayHit hit)
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{
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//float d = length(ray.origin - hit.position);
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ray.origin = hit.position + hit.normal*0.001;
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ray.direction = reflect(ray.direction,hit.normal);
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ray.energy *= 0.5;
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ray.energy *= 0.95;
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return vec3(0.0);
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}
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vec3 scatterLambert(inout Ray ray, RayHit hit)
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{
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//float d = length(ray.origin - hit.position);
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ray.origin = hit.position + hit.normal*0.001;
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ray.direction = sampleHemisphere(hit.normal);
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ray.energy *= hit.albedo * sdot(hit.normal, ray.direction);
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ray.energy = hit.albedo * sdot(hit.normal, ray.direction);
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//ray.distance += d;
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return vec3(0.0);
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}
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vec3 scatterGlow(inout Ray ray, RayHit hit)
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{
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ray.origin = hit.position + hit.normal*0.001;
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//ray.direction = reflect(ray.direction,hit.normal);
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ray.energy = hit.albedo * 2.0;
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return vec3(hit.albedo);
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}
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@ -11,35 +11,19 @@ RayHit trace(inout Ray ray)
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intersectSphere(ray, hit, _spheres[i]);
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}
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int sphereCount = 10;
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for (int i = 0; i < sphereCount; i++)
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{
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Sphere s;
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float a = i/float(sphereCount)*2.0*PI;
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float d = 17.0 + cos((1.3+a)*3.0) * 3.0;
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float r = 4.0 + sin(a*3.0)*2.0;
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s.cr = vec4(sin(a)*d,2.0*r+cos(a*5.0),cos(a)*d, r);
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s.albedo = vec3(.2);
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s.material = i % 3 == 0 ? MAT_CHROME : MAT_LAMBERT;
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Sphere s;
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s.cr = vec4(0.0,0.0,0.0,INF*2.0);
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s.material = MAT_GLOW;
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s.albedo = vec3(1.0,1.0,1.0);
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intersectInsideOutSphere(ray, hit, s);
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intersectSphere(ray, hit, s);
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}
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sphereCount = 3;
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for (int i = 0; i < sphereCount; i++)
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{
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Sphere s;
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float a = i/float(sphereCount)*2.0*PI;
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float d = 5.0 + cos((5.34+a)*5.0) * 3.0;
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float r = 3.0 + sin(a*2.0)*1.5;
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s.cr = vec4(sin(a)*d,4.0*r+cos(a*5.0),cos(a)*d, r);
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s.albedo = vec3(.2);
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s.material = i % 3 == 0 ? MAT_CHROME : MAT_LAMBERT;
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intersectSphere(ray, hit, s);
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}
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ray.distance += hit.distance * float(hit.distance < INF);
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//ray.distance += hit.material == MAT_CHROME
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// ? hit.distance * length(ray.energy) * float(hit.distance < INF)
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// : hit.distance * float(hit.distance < INF);
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//ray.distance += hit.distance * float(hit.distance < INF);
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ray.distance += hit.distance;
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//ray.distance = clamp(ray.distance, 0, INF);
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//ray.distance += hit.distance * length(ray.energy);
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return hit;
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}
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@ -49,9 +49,9 @@ vec4 denoise(sampler2D tex, vec2 uv, float sigma, float kSigma, float threshold)
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void main()
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{
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float sigma = 2.5;
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float kSigma = 7.0;
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float threshold = 0.3;
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float sigma = 2.2;
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float kSigma = 10.0;
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float threshold = 0.2;
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FragColor = denoise(ourTexture, TexCoord, sigma, kSigma, threshold);
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//FragColor = texture(ourTexture, TexCoord);
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@ -9,7 +9,8 @@ layout(rgba32f, binding = 3) readonly uniform image2D _g1;
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// final output
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layout(rgba32f, binding = 0) uniform image2D img_output; // rgba32f defines internal format, image2d for random write to output texture
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uniform vec3 _skyColor = vec3(0.68,0.85,0.9);
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//uniform vec3 _skyColor = vec3(0.75,0.9,1.0);
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uniform vec3 _skyColor = vec3(1.0,1.0,1.0);
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// TODO: some of these depend on each other!! need be be in this order for now c:
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#include func.glsl
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@ -39,16 +40,23 @@ vec3 shade(inout Ray ray, RayHit hit)
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case MAT_CHROME:
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return scatterMetal(ray, hit);
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break;
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case MAT_GLOW:
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return scatterGlow(ray, hit);
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break;
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}
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}
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// sky color
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return _skyColor;
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//ray.distance = INF;
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//return _skyColor * (1-getLinearDepth(ray.distance));
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//return vec3(1.0,0.0,0.0);
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}
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void main()
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{
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// base pixel colour for the image
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//vec4 pixel = vec4(0.0, 0.0, 0.0, 1.0);
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vec4 pixel = vec4(0.0, 0.0, 0.0, 1.0);
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ivec2 pixelCoords = ivec2(gl_GlobalInvocationID.xy);
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@ -74,12 +82,14 @@ void main()
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firstHit.normal = normal;
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firstHit.albedo = albedo;
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int sky = depth >= INF ? 1 : 0;
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int bounces = (1-sky) * BOUNCES;
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pixel.xyz = mix(pixel.xyz, _skyColor, sky);
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int bounces = BOUNCES;
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//pixel.xyz = mix(pixel.xyz, _skyColor, sky);
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// sample
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int samples = 2;
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//int reflections = 0;
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//depth = 0;
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float tracedDepth = 0;
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for (int i = 0; i < samples; i++)
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{
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float sampleDepth = 0;
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@ -89,24 +99,44 @@ void main()
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{
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RayHit hit = trace(ray);
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depth = getLogarithmicDepth(ray.distance);
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//ray.distance = hit.material == MAT_CHROME
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// ? ray.distance * hit.material
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// : 0;
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//int reflection = hit.material == MAT_CHROME ? 1 : 0;
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//reflections |= (reflection << j);
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sampleDepth = getLogarithmicDepth(ray.distance);
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pixel.xyz += ray.energy * shade(ray, hit);
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if (length(ray.energy) < 0.001) break;
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}
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depth += sampleDepth / float(samples);
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//depth = max(getLogarithmicDepth(ray.distance
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tracedDepth += sampleDepth / float(samples);
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}
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// include the first sample we took
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samples++;
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// gamma correction
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float scale = 1.0 / samples;
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pixel.xyz = sqrt(scale * pixel.xyz);
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// apply gamma correction
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float gamma = 2.0;
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float scale = 1.0 / gamma;
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pixel.xyz = sqrt(pixel.xyz * scale);
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pixel.xyz /= 2.0;
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//
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// apply fog
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//float fogDepth = (clamp(tracedDepth - depth, 0, 1) - 1.0) * 2.0;
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//fogDepth *= depth * depth;
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//fogDepth -= depth;
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//fogDepth = depth * tracedDepth;
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vec3 fogColor = _skyColor;
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pixel.xyz = mix(pixel.xyz, fogColor, depth);
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//pixel = clamp(pixel, 0, 1);
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pixel.xyz = mix(pixel.xyz, vec3(1.0), depth);
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//tracedDepth = max(depth,
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//tracedDepth -= 0.2;
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//tracedDepth *= (5.0/4.0);
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vec3 depthDebugColor = mix(vec3(depth), vec3(fogDepth), step(-uv.x, 0.0));
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pixel.xyz = mix(pixel.xyz, depthDebugColor, 1);
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// output to a specific pixel in the image
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imageStore(img_output, ivec2(gl_GlobalInvocationID.xy), pixel);
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@ -44,6 +44,6 @@ void main()
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imageStore(g0_output, pixelCoords, pixel);
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pixel.xyz = hit.albedo;
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pixel.w = 0;
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pixel.w = hit.material;
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imageStore(g1_output, pixelCoords, pixel);
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}
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@ -135,7 +135,7 @@ void updateUniforms(GLuint shaderProgram, float t)
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updateCameraUniforms(shaderProgram, aspect, t);
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// make and update spheres
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const int sphereCount = 25;
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const int sphereCount = 41;
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struct Sphere spheres[sphereCount];
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makeSpheres(spheres, sphereCount, t);
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updateSphereUniforms(shaderProgram, spheres, sphereCount);
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15
src/sphere.c
15
src/sphere.c
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@ -2,6 +2,17 @@
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void makeSpheres(struct Sphere *spheres, int count, float t)
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{
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vec3 albedos[] =
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{
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{0.0,0.0,1.0},
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{0.0,1.0,0.0},
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{0.0,1.0,1.0},
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{1.0,0.0,0.0},
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{1.0,0.0,1.0},
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{1.0,1.0,0.0},
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{1.0,1.0,1.0}
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};
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vec3 sc = {0.0,0.0,1.0};
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int sphereIdx = 0;
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@ -19,13 +30,13 @@ void makeSpheres(struct Sphere *spheres, int count, float t)
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int rainbowSpheres = count - middleSpheres;
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// distance from center
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float d = 6.0;
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radius = 0.7;
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radius = 0.5;
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float x;
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for (int i = 0; i < rainbowSpheres; i++)
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{
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x = 2.0*CGLM_PI * (float)i/(float)rainbowSpheres;
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sc[0] = sin(x)*d;
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sc[1] = radius*sin(x*3.0-5.0*sin(t));
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sc[1] = sin(x*3.0-5.0*sin(t));
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sc[2] = cos(x)*d;
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float ic = i/(float)rainbowSpheres*CGLM_PI*2.0;
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