// ======================================================================== // // Copyright 2009-2017 Intel Corporation // // // // Licensed under the Apache License, Version 2.0 (the "License"); // // you may not use this file except in compliance with the License. // // You may obtain a copy of the License at // // // // http://www.apache.org/licenses/LICENSE-2.0 // // // // Unless required by applicable law or agreed to in writing, software // // distributed under the License is distributed on an "AS IS" BASIS, // // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // // See the License for the specific language governing permissions and // // limitations under the License. // // ======================================================================== // #include "../common/tutorial/tutorial_device.isph" const uniform int numPhi = 5; const uniform int numTheta = 2*numPhi; void renderTileStandardStream(uniform int taskIndex, uniform int* uniform pixels, const uniform unsigned int width, const uniform unsigned int height, const uniform float time, const uniform ISPCCamera& camera, const uniform int numTilesX, const uniform int numTilesY); // ======================================================================== // // User defined instancing // // ======================================================================== // struct Instance { ALIGNED_STRUCT uniform unsigned int geometry; RTCScene object; uniform int userID; AffineSpace3f local2world; AffineSpace3f world2local; LinearSpace3f normal2world; Vec3f lower; Vec3f upper; }; unmasked void instanceBoundsFunc(const uniform Instance* uniform instance, uniform size_t item, uniform RTCBounds* uniform bounds_o) { uniform Vec3f l = instance->lower; uniform Vec3f u = instance->upper; uniform Vec3f p000 = xfmPoint(instance->local2world,make_Vec3f(l.x,l.y,l.z)); uniform Vec3f p001 = xfmPoint(instance->local2world,make_Vec3f(l.x,l.y,u.z)); uniform Vec3f p010 = xfmPoint(instance->local2world,make_Vec3f(l.x,u.y,l.z)); uniform Vec3f p011 = xfmPoint(instance->local2world,make_Vec3f(l.x,u.y,u.z)); uniform Vec3f p100 = xfmPoint(instance->local2world,make_Vec3f(u.x,l.y,l.z)); uniform Vec3f p101 = xfmPoint(instance->local2world,make_Vec3f(u.x,l.y,u.z)); uniform Vec3f p110 = xfmPoint(instance->local2world,make_Vec3f(u.x,u.y,l.z)); uniform Vec3f p111 = xfmPoint(instance->local2world,make_Vec3f(u.x,u.y,u.z)); uniform Vec3f lower = min(min(min(p000,p001),min(p010,p011)),min(min(p100,p101),min(p110,p111))); uniform Vec3f upper = max(max(max(p000,p001),max(p010,p011)),max(max(p100,p101),max(p110,p111))); bounds_o->lower_x = lower.x; bounds_o->lower_y = lower.y; bounds_o->lower_z = lower.z; bounds_o->upper_x = upper.x; bounds_o->upper_y = upper.y; bounds_o->upper_z = upper.z; } void instanceIntersectFunc(const uniform Instance* uniform instance, varying RTCRay& ray, uniform size_t item) { const Vec3f ray_org = ray.org; const Vec3f ray_dir = ray.dir; const int geomID = ray.geomID; ray.org = xfmPoint (instance->world2local,ray_org); ray.dir = xfmVector(instance->world2local,ray_dir); ray.geomID = RTC_INVALID_GEOMETRY_ID; rtcIntersect(instance->object,ray); ray.org = ray_org; ray.dir = ray_dir; if (ray.geomID == RTC_INVALID_GEOMETRY_ID) ray.geomID = geomID; else { ray.instID = instance->userID; ray.Ng = xfmVector(instance->normal2world,ray.Ng); } } void instanceOccludedFunc(const uniform Instance* uniform instance, varying RTCRay& ray, uniform size_t item) { const Vec3f ray_org = ray.org; const Vec3f ray_dir = ray.dir; ray.org = xfmPoint (instance->world2local,ray_org); ray.dir = xfmVector(instance->world2local,ray_dir); rtcOccluded(instance->object,ray); ray.org = ray_org; ray.dir = ray_dir; } unmasked void instanceIntersectFuncN(const uniform int* uniform valid, void* uniform ptr, const uniform RTCIntersectContext* uniform context, RTCRayN* uniform rays, uniform size_t N, uniform size_t item) { /* avoid crashing when debug visualizations are used */ if (context == NULL) return; const uniform Instance* uniform instance = (const uniform Instance* uniform) ptr; /* iterate over all rays in ray packet */ for (uniform unsigned int ui=0; ui=N) continue; /* ignore inactive rays */ if (valid[vi] != -1) continue; /* create transformed ray */ RTCRay ray; const Vec3f ray_org = make_Vec3f(RTCRayN_org_x(rays,N,ui),RTCRayN_org_y(rays,N,ui),RTCRayN_org_z(rays,N,ui)); const Vec3f ray_dir = make_Vec3f(RTCRayN_dir_x(rays,N,ui),RTCRayN_dir_y(rays,N,ui),RTCRayN_dir_z(rays,N,ui)); ray.org = xfmPoint (instance->world2local,ray_org); ray.dir = xfmVector(instance->world2local,ray_dir); bool mask = __mask; unmasked { ray.tnear = mask ? RTCRayN_tnear(rays,N,ui) : (float)(pos_inf); ray.tfar = mask ? RTCRayN_tfar(rays,N,ui ) : (float)(neg_inf); } ray.time = RTCRayN_time(rays,N,ui); ray.mask = RTCRayN_mask(rays,N,ui); ray.geomID = RTC_INVALID_GEOMETRY_ID; /* trace ray through object */ rtcIntersectVM(instance->object,context,&ray,1,sizeof(RTCRay)); if (ray.geomID == RTC_INVALID_GEOMETRY_ID) continue; /* update hit */ RTCRayN_u(rays,N,ui) = ray.u; RTCRayN_v(rays,N,ui) = ray.v; RTCRayN_tfar(rays,N,ui) = ray.tfar; RTCRayN_instID(rays,N,ui) = instance->userID; RTCRayN_geomID(rays,N,ui) = ray.geomID; RTCRayN_primID(rays,N,ui) = ray.primID; Vec3f Ng = xfmVector(instance->normal2world,ray.Ng); RTCRayN_Ng_x(rays,N,ui) = Ng.x; RTCRayN_Ng_y(rays,N,ui) = Ng.y; RTCRayN_Ng_z(rays,N,ui) = Ng.z; } } unmasked void instanceOccludedFuncN(const uniform int* uniform valid, void* uniform ptr, const uniform RTCIntersectContext* uniform context, RTCRayN* uniform rays, uniform size_t N, uniform size_t item) { /* avoid crashing when debug visualizations are used */ if (context == NULL) return; const uniform Instance* uniform instance = (const uniform Instance* uniform) ptr; /* iterate over all rays in ray packet */ for (uniform unsigned int ui=0; ui=N) continue; /* ignore inactive rays */ if (valid[vi] != -1) continue; /* create transformed ray */ RTCRay ray; const Vec3f ray_org = make_Vec3f(RTCRayN_org_x(rays,N,ui),RTCRayN_org_y(rays,N,ui),RTCRayN_org_z(rays,N,ui)); const Vec3f ray_dir = make_Vec3f(RTCRayN_dir_x(rays,N,ui),RTCRayN_dir_y(rays,N,ui),RTCRayN_dir_z(rays,N,ui)); ray.org = xfmPoint (instance->world2local,ray_org); ray.dir = xfmVector(instance->world2local,ray_dir); bool mask = __mask; unmasked { ray.tnear = mask ? RTCRayN_tnear(rays,N,ui) : (float)(pos_inf); ray.tfar = mask ? RTCRayN_tfar(rays,N,ui) : (float)(neg_inf); } ray.time = RTCRayN_time(rays,N,ui); ray.mask = RTCRayN_mask(rays,N,ui); ray.geomID = RTC_INVALID_GEOMETRY_ID; /* trace ray through object */ rtcOccludedVM(instance->object,context,&ray,1,sizeof(RTCRay)); if (ray.geomID == RTC_INVALID_GEOMETRY_ID) continue; /* update hit */ RTCRayN_geomID(rays,N,ui) = ray.geomID; } } uniform Instance* uniform createInstance (RTCScene scene, RTCScene object, uniform int userID, const uniform Vec3f& lower, const uniform Vec3f& upper) { uniform Instance* uniform instance = uniform new uniform Instance; instance->object = object; instance->userID = userID; instance->lower = lower; instance->upper = upper; instance->local2world.l.vx = make_Vec3f(1,0,0); instance->local2world.l.vy = make_Vec3f(0,1,0); instance->local2world.l.vz = make_Vec3f(0,0,1); instance->local2world.p = make_Vec3f(0,0,0); instance->geometry = rtcNewUserGeometry(scene,1); rtcSetUserData(scene,instance->geometry,instance); rtcSetBoundsFunction(scene,instance->geometry,(RTCBoundsFunc)&instanceBoundsFunc); if (g_mode == MODE_NORMAL) { rtcSetIntersectFunction(scene,instance->geometry,(RTCIntersectFuncVarying)&instanceIntersectFunc); rtcSetOccludedFunction (scene,instance->geometry,(RTCOccludedFuncVarying )&instanceOccludedFunc); } else { rtcSetIntersectFunctionN(scene,instance->geometry,&instanceIntersectFuncN); rtcSetOccludedFunctionN (scene,instance->geometry,&instanceOccludedFuncN); } return instance; } void updateInstance (RTCScene scene, uniform Instance* uniform instance) { instance->world2local = rcp(instance->local2world); instance->normal2world = transposed(rcp(instance->local2world.l)); rtcUpdate(scene,instance->geometry); } // ======================================================================== // // User defined sphere geometry // // ======================================================================== // struct Sphere { ALIGNED_STRUCT Vec3f p; //!< position of the sphere float r; //!< radius of the sphere unsigned int geomID; }; unmasked void sphereBoundsFunc(const uniform Sphere* uniform spheres, uniform size_t item, uniform RTCBounds* uniform bounds_o) { const uniform Sphere& sphere = spheres[item]; bounds_o->lower_x = sphere.p.x-sphere.r; bounds_o->lower_y = sphere.p.y-sphere.r; bounds_o->lower_z = sphere.p.z-sphere.r; bounds_o->upper_x = sphere.p.x+sphere.r; bounds_o->upper_y = sphere.p.y+sphere.r; bounds_o->upper_z = sphere.p.z+sphere.r; } void sphereIntersectFunc(const uniform Sphere* uniform spheres, varying RTCRay& ray, uniform size_t item) { const uniform Sphere& sphere = spheres[item]; const Vec3f v = ray.org-sphere.p; const float A = dot(ray.dir,ray.dir); const float B = 2.0f*dot(v,ray.dir); const float C = dot(v,v) - sqr(sphere.r); const float D = B*B - 4.0f*A*C; if (D < 0.0f) return; const float Q = sqrt(D); const float rcpA = rcp(A); const float t0 = 0.5f*rcpA*(-B-Q); const float t1 = 0.5f*rcpA*(-B+Q); if ((ray.tnear < t0) & (t0 < ray.tfar)) { ray.u = 0.0f; ray.v = 0.0f; ray.tfar = t0; ray.geomID = sphere.geomID; ray.primID = (unsigned int) item; ray.Ng = ray.org+t0*ray.dir-sphere.p; } if ((ray.tnear < t1) & (t1 < ray.tfar)) { ray.u = 0.0f; ray.v = 0.0f; ray.tfar = t1; ray.geomID = sphere.geomID; ray.primID = (unsigned int) item; ray.Ng = ray.org+t1*ray.dir-sphere.p; } } void sphereOccludedFunc(const uniform Sphere* uniform spheres, varying RTCRay& ray, uniform size_t item) { const uniform Sphere& sphere = spheres[item]; const Vec3f v = ray.org-sphere.p; const float A = dot(ray.dir,ray.dir); const float B = 2.0f*dot(v,ray.dir); const float C = dot(v,v) - sqr(sphere.r); const float D = B*B - 4.0f*A*C; if (D < 0.0f) return; const float Q = sqrt(D); const float rcpA = rcp(A); const float t0 = 0.5f*rcpA*(-B-Q); const float t1 = 0.5f*rcpA*(-B+Q); if ((ray.tnear < t0) & (t0 < ray.tfar)) { ray.geomID = 0; } if ((ray.tnear < t1) & (t1 < ray.tfar)) { ray.geomID = 0; } } unmasked void sphereIntersectFuncN(const uniform int* uniform valid, void* uniform ptr, const uniform RTCIntersectContext* uniform context, RTCRayN* uniform rays, uniform size_t N, uniform size_t item) { const uniform Sphere* uniform spheres = (const uniform Sphere* uniform) ptr; /* iterate over all rays in ray packet */ for (uniform unsigned int ui=0; ui=N) continue; /* ignore inactive rays */ if (valid[vi] != -1) continue; const Vec3f ray_org = make_Vec3f(RTCRayN_org_x(rays,N,ui),RTCRayN_org_y(rays,N,ui),RTCRayN_org_z(rays,N,ui)); const Vec3f ray_dir = make_Vec3f(RTCRayN_dir_x(rays,N,ui),RTCRayN_dir_y(rays,N,ui),RTCRayN_dir_z(rays,N,ui)); float& ray_tnear = RTCRayN_tnear(rays,N,ui); float& ray_tfar = RTCRayN_tfar(rays,N,ui); const uniform Sphere& sphere = spheres[item]; const Vec3f v = ray_org-sphere.p; const float A = dot(ray_dir,ray_dir); const float B = 2.0f*dot(v,ray_dir); const float C = dot(v,v) - sqr(sphere.r); const float D = B*B - 4.0f*A*C; if (D < 0.0f) continue; const float Q = sqrt(D); const float rcpA = rcp(A); const float t0 = 0.5f*rcpA*(-B-Q); const float t1 = 0.5f*rcpA*(-B+Q); if ((ray_tnear < t0) & (t0 < ray_tfar)) { RTCRayN_u(rays,N,ui) = 0.0f; RTCRayN_v(rays,N,ui) = 0.0f; RTCRayN_tfar(rays,N,ui) = t0; RTCRayN_geomID(rays,N,ui) = sphere.geomID; RTCRayN_primID(rays,N,ui) = (unsigned int)item; const Vec3f Ng = ray_org+t0*ray_dir-sphere.p; RTCRayN_Ng_x(rays,N,ui) = Ng.x; RTCRayN_Ng_y(rays,N,ui) = Ng.y; RTCRayN_Ng_z(rays,N,ui) = Ng.z; } if ((ray_tnear < t1) & (t1 < ray_tfar)) { RTCRayN_u(rays,N,ui) = 0.0f; RTCRayN_v(rays,N,ui) = 0.0f; RTCRayN_tfar(rays,N,ui) = t1; RTCRayN_geomID(rays,N,ui) = sphere.geomID; RTCRayN_primID(rays,N,ui) = (unsigned int)item; const Vec3f Ng = ray_org+t1*ray_dir-sphere.p; RTCRayN_Ng_x(rays,N,ui) = Ng.x; RTCRayN_Ng_y(rays,N,ui) = Ng.y; RTCRayN_Ng_z(rays,N,ui) = Ng.z; } } } unmasked void sphereOccludedFuncN(const uniform int* uniform valid, void* uniform ptr, const uniform RTCIntersectContext* uniform context, RTCRayN* uniform rays, uniform size_t N, uniform size_t item) { const uniform Sphere* uniform spheres = (const uniform Sphere* uniform) ptr; /* iterate over all rays in ray packet */ for (uniform unsigned int ui=0; ui=N) continue; /* ignore inactive rays */ if (valid[vi] != -1) continue; const Vec3f ray_org = make_Vec3f(RTCRayN_org_x(rays,N,ui),RTCRayN_org_y(rays,N,ui),RTCRayN_org_z(rays,N,ui)); const Vec3f ray_dir = make_Vec3f(RTCRayN_dir_x(rays,N,ui),RTCRayN_dir_y(rays,N,ui),RTCRayN_dir_z(rays,N,ui)); float& ray_tnear = RTCRayN_tnear(rays,N,ui); float& ray_tfar = RTCRayN_tfar(rays,N,ui); const uniform Sphere& sphere = spheres[item]; const Vec3f v = ray_org-sphere.p; const float A = dot(ray_dir,ray_dir); const float B = 2.0f*dot(v,ray_dir); const float C = dot(v,v) - sqr(sphere.r); const float D = B*B - 4.0f*A*C; if (D < 0.0f) continue; const float Q = sqrt(D); const float rcpA = rcp(A); const float t0 = 0.5f*rcpA*(-B-Q); const float t1 = 0.5f*rcpA*(-B+Q); if ((ray_tnear < t0) & (t0 < ray_tfar)) { RTCRayN_geomID(rays,N,ui) = 0; } if ((ray_tnear < t1) & (t1 < ray_tfar)) { RTCRayN_geomID(rays,N,ui) = 0; } } } uniform Sphere* uniform createAnalyticalSphere (RTCScene scene, const uniform Vec3f& p, uniform float r) { uniform unsigned int geomID = rtcNewUserGeometry(scene,1); uniform Sphere* uniform sphere = uniform new uniform Sphere; sphere->p = p; sphere->r = r; sphere->geomID = geomID; rtcSetUserData(scene,geomID,sphere); rtcSetBoundsFunction(scene,geomID,(RTCBoundsFunc)&sphereBoundsFunc); if (g_mode == MODE_NORMAL) { rtcSetIntersectFunction(scene,geomID,(RTCIntersectFuncVarying)&sphereIntersectFunc); rtcSetOccludedFunction (scene,geomID,(RTCOccludedFuncVarying )&sphereOccludedFunc); } else { rtcSetIntersectFunctionN(scene,geomID,&sphereIntersectFuncN); rtcSetOccludedFunctionN (scene,geomID,&sphereOccludedFuncN); } return sphere; } uniform Sphere* uniform createAnalyticalSpheres (RTCScene scene, uniform size_t N) { uniform unsigned int geomID = rtcNewUserGeometry(scene,N); uniform Sphere* uniform spheres = uniform new uniform Sphere[N]; for (uniform size_t i=0; i 1) { triangles[tri].v0 = p10; triangles[tri].v1 = p00; triangles[tri].v2 = p01; tri++; } if (phi < numPhi) { triangles[tri].v0 = p11; triangles[tri].v1 = p10; triangles[tri].v2 = p01; tri++; } } } rtcUnmapBuffer(scene,mesh,RTC_VERTEX_BUFFER); rtcUnmapBuffer(scene,mesh,RTC_INDEX_BUFFER); return mesh; } /* creates a ground plane */ uniform unsigned int createGroundPlane (RTCScene scene) { /* create a triangulated plane with 2 triangles and 4 vertices */ uniform unsigned int mesh = rtcNewTriangleMesh (scene, RTC_GEOMETRY_STATIC, 2, 4); /* set vertices */ uniform Vertex* uniform vertices = (uniform Vertex* uniform) rtcMapBuffer(scene,mesh,RTC_VERTEX_BUFFER); vertices[0].x = -10; vertices[0].y = -2; vertices[0].z = -10; vertices[1].x = -10; vertices[1].y = -2; vertices[1].z = +10; vertices[2].x = +10; vertices[2].y = -2; vertices[2].z = -10; vertices[3].x = +10; vertices[3].y = -2; vertices[3].z = +10; rtcUnmapBuffer(scene,mesh,RTC_VERTEX_BUFFER); /* set triangles */ uniform Triangle* uniform triangles = (uniform Triangle* uniform) rtcMapBuffer(scene,mesh,RTC_INDEX_BUFFER); triangles[0].v0 = 0; triangles[0].v1 = 2; triangles[0].v2 = 1; triangles[1].v0 = 1; triangles[1].v1 = 2; triangles[1].v2 = 3; rtcUnmapBuffer(scene,mesh,RTC_INDEX_BUFFER); return mesh; } /* scene data */ RTCDevice g_device = NULL; RTCScene g_scene = NULL; RTCScene g_scene0 = NULL; RTCScene g_scene1 = NULL; RTCScene g_scene2 = NULL; uniform Instance* uniform g_instance[4] = { NULL, NULL, NULL, NULL }; uniform Vec3f colors[5][4]; /* called by the C++ code for initialization */ export void device_init (uniform int8* uniform cfg) { /* create new Embree device */ g_device = rtcNewDevice(cfg); error_handler(rtcDeviceGetError(g_device)); /* set error handler */ rtcDeviceSetErrorFunction(g_device,error_handler); uniform RTCAlgorithmFlags aflags; if (g_mode == MODE_NORMAL) aflags = RTC_INTERSECT_UNIFORM | RTC_INTERSECT_VARYING; else aflags = RTC_INTERSECT_UNIFORM | RTC_INTERSECT_STREAM; /* create scene */ g_scene = rtcDeviceNewScene(g_device, RTC_SCENE_DYNAMIC,aflags); /* create scene with 4 analytical spheres */ g_scene0 = rtcDeviceNewScene(g_device, RTC_SCENE_STATIC,aflags); uniform Sphere* uniform spheres = createAnalyticalSpheres(g_scene0,4); spheres[0].p = make_Vec3f( 0, 0,+1); spheres[0].r = 0.5f; spheres[1].p = make_Vec3f(+1, 0, 0); spheres[1].r = 0.5f; spheres[2].p = make_Vec3f( 0, 0,-1); spheres[2].r = 0.5f; spheres[3].p = make_Vec3f(-1, 0, 0); spheres[3].r = 0.5f; rtcCommit(g_scene0); /* create scene with 4 triangulated spheres */ g_scene1 = rtcDeviceNewScene(g_device, RTC_SCENE_STATIC,aflags); createTriangulatedSphere(g_scene1,make_Vec3f( 0, 0,+1),0.5f); createTriangulatedSphere(g_scene1,make_Vec3f(+1, 0, 0),0.5f); createTriangulatedSphere(g_scene1,make_Vec3f( 0, 0,-1),0.5f); createTriangulatedSphere(g_scene1,make_Vec3f(-1, 0, 0),0.5f); rtcCommit(g_scene1); /* create scene with 2 triangulated and 2 analytical spheres */ g_scene2 = rtcDeviceNewScene(g_device, RTC_SCENE_STATIC,aflags); createTriangulatedSphere(g_scene2,make_Vec3f( 0, 0,+1),0.5f); createAnalyticalSphere (g_scene2,make_Vec3f(+1, 0, 0),0.5f); createTriangulatedSphere(g_scene2,make_Vec3f( 0, 0,-1),0.5f); createAnalyticalSphere (g_scene2,make_Vec3f(-1, 0, 0),0.5f); rtcCommit(g_scene2); /* instantiate geometry */ createGroundPlane(g_scene); g_instance[0] = createInstance(g_scene,g_scene0,0,make_Vec3f(-2,-2,-2),make_Vec3f(+2,+2,+2)); g_instance[1] = createInstance(g_scene,g_scene1,1,make_Vec3f(-2,-2,-2),make_Vec3f(+2,+2,+2)); g_instance[2] = createInstance(g_scene,g_scene2,2,make_Vec3f(-2,-2,-2),make_Vec3f(+2,+2,+2)); g_instance[3] = createInstance(g_scene,g_scene2,3,make_Vec3f(-2,-2,-2),make_Vec3f(+2,+2,+2)); rtcCommit(g_scene); /* set all colors */ colors[0][0] = make_Vec3f(0.25f, 0.00f, 0.00f); colors[0][1] = make_Vec3f(0.50f, 0.00f, 0.00f); colors[0][2] = make_Vec3f(0.75f, 0.00f, 0.00f); colors[0][3] = make_Vec3f(1.00f, 0.00f, 0.00f); colors[1][0] = make_Vec3f(0.00f, 0.25f, 0.00f); colors[1][1] = make_Vec3f(0.00f, 0.50f, 0.00f); colors[1][2] = make_Vec3f(0.00f, 0.75f, 0.00f); colors[1][3] = make_Vec3f(0.00f, 1.00f, 0.00f); colors[2][0] = make_Vec3f(0.00f, 0.00f, 0.25f); colors[2][1] = make_Vec3f(0.00f, 0.00f, 0.50f); colors[2][2] = make_Vec3f(0.00f, 0.00f, 0.75f); colors[2][3] = make_Vec3f(0.00f, 0.00f, 1.00f); colors[3][0] = make_Vec3f(0.25f, 0.25f, 0.00f); colors[3][1] = make_Vec3f(0.50f, 0.50f, 0.00f); colors[3][2] = make_Vec3f(0.75f, 0.75f, 0.00f); colors[3][3] = make_Vec3f(1.00f, 1.00f, 0.00f); colors[4][0] = make_Vec3f(1.0f, 1.0f, 1.0f); colors[4][1] = make_Vec3f(1.0f, 1.0f, 1.0f); colors[4][2] = make_Vec3f(1.0f, 1.0f, 1.0f); colors[4][3] = make_Vec3f(1.0f, 1.0f, 1.0f); /* set start render mode */ if (g_mode == MODE_NORMAL) renderTile = renderTileStandard; else renderTile = renderTileStandardStream; key_pressed_handler = device_key_pressed_default; } /* task that renders a single screen tile */ Vec3f renderPixelStandard(float x, float y, const uniform ISPCCamera& camera) { /* initialize ray */ RTCRay ray; ray.org = make_Vec3f(camera.xfm.p); ray.dir = make_Vec3f(normalize(x*camera.xfm.l.vx + y*camera.xfm.l.vy + camera.xfm.l.vz)); ray.tnear = 0.0f; ray.tfar = (float)(inf); ray.geomID = RTC_INVALID_GEOMETRY_ID; ray.primID = RTC_INVALID_GEOMETRY_ID; ray.instID = 4; // set default instance ID ray.mask = -1; ray.time = 0; /* intersect ray with scene */ rtcIntersect(g_scene,ray); /* shade pixels */ Vec3f color = make_Vec3f(0.0f); if (ray.geomID != RTC_INVALID_GEOMETRY_ID) { /* calculate shading normal */ Vec3f Ns = normalize(ray.Ng); /* calculate diffuse color of geometries */ Vec3f diffuse = make_Vec3f(0.0f); if (ray.instID == 0) diffuse = colors[ray.instID][ray.primID]; else diffuse = colors[ray.instID][ray.geomID]; color = color + diffuse*0.5; /* initialize shadow ray */ Vec3f lightDir = normalize(make_Vec3f(-1,-1,-1)); RTCRay shadow; shadow.org = ray.org + ray.tfar*ray.dir; shadow.dir = neg(lightDir); shadow.tnear = 0.001f; shadow.tfar = (float)(inf); shadow.geomID = 1; shadow.primID = 0; shadow.mask = -1; shadow.time = 0; /* trace shadow ray */ rtcOccluded(g_scene,shadow); /* add light contribution */ if (shadow.geomID) color = color + diffuse*clamp(-dot(lightDir,Ns),0.0f,1.0f); } return color; } /* renders a single screen tile */ void renderTileStandard(uniform int taskIndex, uniform int* uniform pixels, const uniform unsigned int width, const uniform unsigned int height, const uniform float time, const uniform ISPCCamera& camera, const uniform int numTilesX, const uniform int numTilesY) { const uniform unsigned int tileY = taskIndex / numTilesX; const uniform unsigned int tileX = taskIndex - tileY * numTilesX; const uniform unsigned int x0 = tileX * TILE_SIZE_X; const uniform unsigned int x1 = min(x0+TILE_SIZE_X,width); const uniform unsigned int y0 = tileY * TILE_SIZE_Y; const uniform unsigned int y1 = min(y0+TILE_SIZE_Y,height); foreach_tiled (y = y0 ... y1, x = x0 ... x1) { /* calculate pixel color */ Vec3f color = renderPixelStandard((float)x,(float)y,camera); /* write color to framebuffer */ unsigned int r = (unsigned int) (255.0f * clamp(color.x,0.0f,1.0f)); unsigned int g = (unsigned int) (255.0f * clamp(color.y,0.0f,1.0f)); unsigned int b = (unsigned int) (255.0f * clamp(color.z,0.0f,1.0f)); pixels[y*width+x] = (b << 16) + (g << 8) + r; } } /* renders a single screen tile */ void renderTileStandardStream(uniform int taskIndex, uniform int* uniform pixels, const uniform unsigned int width, const uniform unsigned int height, const uniform float time, const uniform ISPCCamera& camera, const uniform int numTilesX, const uniform int numTilesY) { const uniform unsigned int tileY = taskIndex / numTilesX; const uniform unsigned int tileX = taskIndex - tileY * numTilesX; const uniform unsigned int x0 = tileX * TILE_SIZE_X; const uniform unsigned int x1 = min(x0+TILE_SIZE_X,width); const uniform unsigned int y0 = tileY * TILE_SIZE_Y; const uniform unsigned int y1 = min(y0+TILE_SIZE_Y,height); RTCRay primary_stream[TILE_SIZE_X*TILE_SIZE_Y]; RTCRay shadow_stream[TILE_SIZE_X*TILE_SIZE_Y]; Vec3f color_stream[TILE_SIZE_X*TILE_SIZE_Y]; bool valid_stream[TILE_SIZE_X*TILE_SIZE_Y]; /* select stream mode */ uniform RTCIntersectFlags iflags = g_mode == MODE_STREAM_COHERENT ? RTC_INTERSECT_COHERENT : RTC_INTERSECT_INCOHERENT; /* generate stream of primary rays */ uniform int N = 0; foreach_tiled (y = y0 ... y1, x = x0 ... x1) { /* ISPC workaround for mask == 0 */ if (all(__mask == 0)) continue; /* initialize variables */ color_stream[N] = make_Vec3f(0.0f); bool mask = __mask; unmasked { valid_stream[N] = mask; } /* initialize ray */ RTCRay& primary = primary_stream[N]; primary.org = make_Vec3f(camera.xfm.p); primary.dir = make_Vec3f(normalize((float)x*camera.xfm.l.vx + (float)y*camera.xfm.l.vy + camera.xfm.l.vz)); mask = __mask; unmasked { // invalidates inactive rays primary.tnear = mask ? 0.0f : (float)(pos_inf); primary.tfar = mask ? (float)(inf) : (float)(neg_inf); } primary.instID = 4; // set default instance ID primary.geomID = RTC_INVALID_GEOMETRY_ID; primary.primID = RTC_INVALID_GEOMETRY_ID; primary.mask = -1; primary.time = 0.0f; N++; } Vec3f lightDir = normalize(make_Vec3f(-1,-1,-1)); /* trace rays */ uniform RTCIntersectContext primary_context; primary_context.flags = iflags; primary_context.userRayExt = &primary_stream; rtcIntersectVM(g_scene,&primary_context,(varying RTCRay* uniform)&primary_stream,N,sizeof(RTCRay)); /* terminate rays and update color */ N = -1; foreach_tiled (y = y0 ... y1, x = x0 ... x1) { N++; /* ISPC workaround for mask == 0 */ if (all(__mask == 0)) continue; /* invalidate shadow rays by default */ RTCRay& shadow = shadow_stream[N]; unmasked { shadow.tnear = (float)(pos_inf); shadow.tfar = (float)(neg_inf); } /* ignore invalid rays */ if (valid_stream[N] == false) continue; /* terminate rays that hit nothing */ if (primary_stream[N].geomID == RTC_INVALID_GEOMETRY_ID) { valid_stream[N] = false; continue; } /* calculate diffuse color of geometries */ RTCRay& primary = primary_stream[N]; Vec3f diffuse = make_Vec3f(0.0f); if (primary.instID == 0) diffuse = colors[primary.instID][primary.primID]; else diffuse = colors[primary.instID][primary.geomID]; color_stream[N] = color_stream[N] + diffuse*0.5; /* initialize shadow ray */ shadow.org = primary.org + primary.tfar*primary.dir; shadow.dir = neg(lightDir); bool mask = __mask; unmasked { shadow.tnear = mask ? 0.001f : (float)(pos_inf); shadow.tfar = mask ? (float)(inf) : (float)(neg_inf); } shadow.geomID = RTC_INVALID_GEOMETRY_ID; shadow.primID = RTC_INVALID_GEOMETRY_ID; shadow.mask = N*programCount + programIndex; shadow.time = 0; } N++; /* trace shadow rays */ uniform RTCIntersectContext shadow_context; shadow_context.flags = iflags; shadow_context.userRayExt = &shadow_stream; rtcOccludedVM(g_scene,&shadow_context,(varying RTCRay* uniform)&shadow_stream,N,sizeof(RTCRay)); /* add light contribution */ N = -1; foreach_tiled (y = y0 ... y1, x = x0 ... x1) { N++; /* ISPC workaround for mask == 0 */ if (all(__mask == 0)) continue; /* ignore invalid rays */ if (valid_stream[N] == false) continue; /* add light contrinution */ RTCRay& primary = primary_stream[N]; Vec3f Ns = normalize(primary.Ng); Vec3f diffuse = make_Vec3f(0.0f); if (primary.instID == 0) diffuse = colors[primary.instID][primary.primID]; else diffuse = colors[primary.instID][primary.geomID]; RTCRay& shadow = shadow_stream[N]; if (shadow.geomID) { color_stream[N] = color_stream[N] + diffuse*clamp(-dot(lightDir,Ns),0.0f,1.0f); } } N++; /* framebuffer writeback */ N = 0; foreach_tiled (y = y0 ... y1, x = x0 ... x1) { /* ISPC workaround for mask == 0 */ if (all(__mask == 0)) continue; /* write color to framebuffer */ unsigned int r = (unsigned int) (255.0f * clamp(color_stream[N].x,0.0f,1.0f)); unsigned int g = (unsigned int) (255.0f * clamp(color_stream[N].y,0.0f,1.0f)); unsigned int b = (unsigned int) (255.0f * clamp(color_stream[N].z,0.0f,1.0f)); pixels[y*width+x] = (b << 16) + (g << 8) + r; N++; } } /* task that renders a single screen tile */ task void renderTileTask(uniform int* uniform pixels, const uniform unsigned int width, const uniform unsigned int height, const uniform float time, const uniform ISPCCamera& camera, const uniform int numTilesX, const uniform int numTilesY) { renderTile(taskIndex,pixels,width,height,time,camera,numTilesX,numTilesY); } /* called by the C++ code to render */ export void device_render (uniform int* uniform pixels, const uniform unsigned int width, const uniform unsigned int height, const uniform float time, const uniform ISPCCamera& camera) { uniform float t0 = 0.7f*time; uniform float t1 = 1.5f*time; /* rotate instances around themselves */ uniform LinearSpace3f xfm; xfm.vx = make_Vec3f(cos(t1),0,sin(t1)); xfm.vy = make_Vec3f(0,1,0); xfm.vz = make_Vec3f(-sin(t1),0,cos(t1)); /* calculate transformations to move instances in circles */ g_instance[0]->local2world = make_AffineSpace3f(xfm,2.2f*make_Vec3f(+cos(t0),0.0f,+sin(t0))); g_instance[1]->local2world = make_AffineSpace3f(xfm,2.2f*make_Vec3f(-cos(t0),0.0f,-sin(t0))); g_instance[2]->local2world = make_AffineSpace3f(xfm,2.2f*make_Vec3f(-sin(t0),0.0f,+cos(t0))); g_instance[3]->local2world = make_AffineSpace3f(xfm,2.2f*make_Vec3f(+sin(t0),0.0f,-cos(t0))); /* update scene */ updateInstance(g_scene,g_instance[0]); updateInstance(g_scene,g_instance[1]); updateInstance(g_scene,g_instance[2]); updateInstance(g_scene,g_instance[3]); rtcCommit (g_scene); /* render all pixels */ const uniform int numTilesX = (width +TILE_SIZE_X-1)/TILE_SIZE_X; const uniform int numTilesY = (height+TILE_SIZE_Y-1)/TILE_SIZE_Y; launch[numTilesX*numTilesY] renderTileTask(pixels,width,height,time,camera,numTilesX,numTilesY); sync; } /* called by the C++ code for cleanup */ export void device_cleanup () { rtcDeleteScene (g_scene); g_scene = NULL; rtcDeleteScene (g_scene0); g_scene0 = NULL; rtcDeleteScene (g_scene1); g_scene1 = NULL; rtcDeleteScene (g_scene2); g_scene2 = NULL; rtcDeleteDevice(g_device); g_device = NULL; }