+ | New file for volumetric

shaders/compute.glsl

@@ -80,6 +80,8 @@ struct hitInfo
 #include "shaders/random.glsl"
 #include "shaders/intersect.glsl"
 #include "shaders/scatter.glsl"
+#include "shaders/light.glsl"
+#include "shaders/volumetric.glsl"
 
 Ray	portalRay(Ray ray, hitInfo hit)
 {
@@ -139,68 +141,6 @@ hitInfo	traceRay(Ray ray)
 	return (hit);
 }
 
-float sampleHG(float g, inout uint rng_state)
-{
-    if (abs(g) < 0.001)
-        return 2.0 * randomValue(rng_state) - 1.0;
-        
-    float sqr_term = (1.0 - g * g) / (1.0 + g - 2.0 * g * randomValue(rng_state));
-    return (1.0 + g * g - sqr_term * sqr_term) / (2.0 * g);
-}
-
-vec3 sampleDirection(vec3 forward, float cos_theta, inout uint rng_state)
-{
-    float phi = 2.0 * M_PI * randomValue(rng_state);
-    float sin_theta = sqrt(max(0.0, 1.0 - cos_theta * cos_theta));
-    
-    vec3 dir;
-    dir.x = sin_theta * cos(phi);
-    dir.y = sin_theta * sin(phi);
-    dir.z = cos_theta;
-    
-    vec3 up = abs(forward.z) < 0.999 ? vec3(0, 0, 1) : vec3(1, 0, 0);
-    vec3 right = normalize(cross(up, forward));
-    up = cross(forward, right);
-    
-    return normalize(
-        dir.x * right +
-        dir.y * up +
-        dir.z * forward
-    );
-}
-
-vec3	sampleLights(vec3 position)
-{
-	vec3 light = vec3(0.0);
-
-	for (int i = 0; i < u_objectsNum; i++)
-	{
-		GPUObject obj = objects[i];
-		GPUMaterial mat = materials[obj.mat_index];
-
-		if (obj.type == 0 && mat.emission > 0.0)
-		{
-			vec3 light_dir = normalize(obj.position - position);
-			float light_dist = length(obj.position - position);
-
-			Ray shadow_ray = Ray(position + light_dir * 0.01, light_dir);
-			hitInfo shadow_hit = traceRay(shadow_ray);
-
-			if (shadow_hit.obj_index == i)
-				light += mat.emission * mat.color / (light_dist);
-		}
-	}
-
-	return (light);
-}
-
-struct VolumeProperties {
-    vec3 sigma_a;    // absorption coefficient
-    vec3 sigma_s;    // scattering coefficient
-    vec3 sigma_t;    // extinction coefficient
-    float g;         // phase function parameter
-};
-
 vec3    pathtrace(Ray ray, inout uint rng_state)
 {
 	vec3	color = vec3(1.0);
@@ -218,23 +158,10 @@ vec3    pathtrace(Ray ray, inout uint rng_state)
 	{
 		hitInfo hit = traceRay(ray);
 
-		float t_scatter = -log(randomValue(rng_state)) / volume.sigma_t.x;
-        float t_surface = hit.t;
-
-		if (t_scatter < t_surface && volume.sigma_t.x > 0.0)
+		float t_scatter = 0.0;
+		if (atmosScatter(volume, hit, t_scatter, rng_state))
         {
-            vec3 scatter_pos = ray.origin + ray.direction * t_scatter;
-            
-            transmittance *= exp(-volume.sigma_t * t_scatter);
-            color *= volume.sigma_s / volume.sigma_t;
-            
-            light += transmittance * color * sampleLights(scatter_pos);
-            
-            float cos_theta = sampleHG(volume.g, rng_state);
-            vec3 new_dir = sampleDirection(ray.direction, cos_theta, rng_state);
-            
-            ray.origin = scatter_pos;
-            ray.direction = new_dir;
+			calculateVolumetricLight(t_scatter, volume, ray, color, light, transmittance, rng_state);
             continue;
         }
 
@@ -245,7 +172,7 @@ vec3    pathtrace(Ray ray, inout uint rng_state)
 			break;
 		}
 
-		transmittance *= exp(-volume.sigma_t * t_surface);
+		transmittance *= exp(-volume.sigma_t * hit.t);
 
 		GPUObject obj = objects[hit.obj_index];
 		GPUMaterial mat = materials[obj.mat_index];
@@ -257,9 +184,7 @@ vec3    pathtrace(Ray ray, inout uint rng_state)
         color /= p;
 		//
 
-		color *= mat.color;
-		light += mat.emission * mat.color;
-		// light += sampleLights(hit.position);
+		calculateLightColor(color, light, mat, hit);
 		
 		if (mat.emission > 0.0)
 			break;