#ifdef WRITE_DEPTH #ifdef GL_EXT_frag_depth #extension GL_EXT_frag_depth : enable #endif #endif uniform vec3 u_radii; uniform vec3 u_oneOverEllipsoidRadiiSquared; varying vec3 v_positionEC; vec4 computeEllipsoidColor(czm_ray ray, float intersection, float side) { vec3 positionEC = czm_pointAlongRay(ray, intersection); vec3 positionMC = (czm_inverseModelView * vec4(positionEC, 1.0)).xyz; vec3 geodeticNormal = normalize(czm_geodeticSurfaceNormal(positionMC, vec3(0.0), u_oneOverEllipsoidRadiiSquared)); vec3 sphericalNormal = normalize(positionMC / u_radii); vec3 normalMC = geodeticNormal * side; // normalized surface normal (always facing the viewer) in model coordinates vec3 normalEC = normalize(czm_normal * normalMC); // normalized surface normal in eye coordiantes vec2 st = czm_ellipsoidWgs84TextureCoordinates(sphericalNormal); vec3 positionToEyeEC = -positionEC; czm_materialInput materialInput; materialInput.s = st.s; materialInput.st = st; materialInput.str = (positionMC + u_radii) / u_radii; materialInput.normalEC = normalEC; materialInput.tangentToEyeMatrix = czm_eastNorthUpToEyeCoordinates(positionMC, normalEC); materialInput.positionToEyeEC = positionToEyeEC; czm_material material = czm_getMaterial(materialInput); #ifdef ONLY_SUN_LIGHTING return czm_private_phong(normalize(positionToEyeEC), material, czm_sunDirectionEC); #else return czm_phong(normalize(positionToEyeEC), material, czm_lightDirectionEC); #endif } void main() { // PERFORMANCE_TODO: When dynamic branching is available, compute ratio of maximum and minimum radii // in the vertex shader. Only when it is larger than some constant, march along the ray. // Otherwise perform one intersection test which will be the common case. // Test if the ray intersects a sphere with the ellipsoid's maximum radius. // For very oblate ellipsoids, using the ellipsoid's radii for an intersection test // may cause false negatives. This will discard fragments before marching the ray forward. float maxRadius = max(u_radii.x, max(u_radii.y, u_radii.z)) * 1.5; vec3 direction = normalize(v_positionEC); vec3 ellipsoidCenter = czm_modelView[3].xyz; float t1 = -1.0; float t2 = -1.0; float b = -2.0 * dot(direction, ellipsoidCenter); float c = dot(ellipsoidCenter, ellipsoidCenter) - maxRadius * maxRadius; float discriminant = b * b - 4.0 * c; if (discriminant >= 0.0) { t1 = (-b - sqrt(discriminant)) * 0.5; t2 = (-b + sqrt(discriminant)) * 0.5; } if (t1 < 0.0 && t2 < 0.0) { discard; } float t = min(t1, t2); if (t < 0.0) { t = 0.0; } // March ray forward to intersection with larger sphere and find czm_ray ray = czm_ray(t * direction, direction); vec3 ellipsoid_inverseRadii = vec3(1.0 / u_radii.x, 1.0 / u_radii.y, 1.0 / u_radii.z); czm_raySegment intersection = czm_rayEllipsoidIntersectionInterval(ray, ellipsoidCenter, ellipsoid_inverseRadii); if (czm_isEmpty(intersection)) { discard; } // If the viewer is outside, compute outsideFaceColor, with normals facing outward. vec4 outsideFaceColor = (intersection.start != 0.0) ? computeEllipsoidColor(ray, intersection.start, 1.0) : vec4(0.0); // If the viewer either is inside or can see inside, compute insideFaceColor, with normals facing inward. vec4 insideFaceColor = (outsideFaceColor.a < 1.0) ? computeEllipsoidColor(ray, intersection.stop, -1.0) : vec4(0.0); gl_FragColor = mix(insideFaceColor, outsideFaceColor, outsideFaceColor.a); gl_FragColor.a = 1.0 - (1.0 - insideFaceColor.a) * (1.0 - outsideFaceColor.a); #ifdef WRITE_DEPTH #ifdef GL_EXT_frag_depth t = (intersection.start != 0.0) ? intersection.start : intersection.stop; vec3 positionEC = czm_pointAlongRay(ray, t); vec4 positionCC = czm_projection * vec4(positionEC, 1.0); #ifdef LOG_DEPTH czm_writeLogDepth(1.0 + positionCC.w); #else float z = positionCC.z / positionCC.w; float n = czm_depthRange.near; float f = czm_depthRange.far; gl_FragDepthEXT = (z * (f - n) + f + n) * 0.5; #endif #endif #endif }