forked from bartvdbraak/blender
cf82b49a0f
Using camel case for variables is something what didn't came from our original code, but rather from third party libraries. Let's avoid those as much as possible.
337 lines
9.9 KiB
C
337 lines
9.9 KiB
C
/*
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* Adapted from code Copyright 2009-2010 NVIDIA Corporation,
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* and code copyright 2009-2012 Intel Corporation
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*
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* Modifications Copyright 2011-2014, Blender Foundation.
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*/
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#ifdef __QBVH__
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# include "qbvh_volume.h"
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#endif
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#if BVH_FEATURE(BVH_HAIR)
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# define NODE_INTERSECT bvh_node_intersect
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#else
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# define NODE_INTERSECT bvh_aligned_node_intersect
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#endif
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/* This is a template BVH traversal function for volumes, where
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* various features can be enabled/disabled. This way we can compile optimized
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* versions for each case without new features slowing things down.
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*
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* BVH_INSTANCING: object instancing
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* BVH_MOTION: motion blur rendering
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*
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*/
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ccl_device bool BVH_FUNCTION_FULL_NAME(BVH)(KernelGlobals *kg,
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const Ray *ray,
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Intersection *isect,
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const uint visibility)
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{
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/* todo:
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* - test if pushing distance on the stack helps (for non shadow rays)
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* - separate version for shadow rays
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* - likely and unlikely for if() statements
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* - test restrict attribute for pointers
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*/
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/* traversal stack in CUDA thread-local memory */
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int traversal_stack[BVH_STACK_SIZE];
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traversal_stack[0] = ENTRYPOINT_SENTINEL;
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/* traversal variables in registers */
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int stack_ptr = 0;
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int node_addr = kernel_data.bvh.root;
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/* ray parameters in registers */
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float3 P = ray->P;
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float3 dir = bvh_clamp_direction(ray->D);
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float3 idir = bvh_inverse_direction(dir);
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int object = OBJECT_NONE;
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#if BVH_FEATURE(BVH_MOTION)
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Transform ob_itfm;
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#endif
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isect->t = ray->t;
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isect->u = 0.0f;
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isect->v = 0.0f;
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isect->prim = PRIM_NONE;
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isect->object = OBJECT_NONE;
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#if defined(__KERNEL_SSE2__)
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const shuffle_swap_t shuf_identity = shuffle_swap_identity();
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const shuffle_swap_t shuf_swap = shuffle_swap_swap();
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const ssef pn = cast(ssei(0, 0, 0x80000000, 0x80000000));
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ssef Psplat[3], idirsplat[3];
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# if BVH_FEATURE(BVH_HAIR)
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ssef tnear(0.0f), tfar(isect->t);
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# endif
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shuffle_swap_t shufflexyz[3];
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Psplat[0] = ssef(P.x);
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Psplat[1] = ssef(P.y);
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Psplat[2] = ssef(P.z);
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ssef tsplat(0.0f, 0.0f, -isect->t, -isect->t);
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gen_idirsplat_swap(pn, shuf_identity, shuf_swap, idir, idirsplat, shufflexyz);
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#endif
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IsectPrecalc isect_precalc;
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triangle_intersect_precalc(dir, &isect_precalc);
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/* traversal loop */
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do {
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do {
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/* traverse internal nodes */
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while(node_addr >= 0 && node_addr != ENTRYPOINT_SENTINEL) {
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int node_addr_child1, traverse_mask;
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float dist[2];
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float4 cnodes = kernel_tex_fetch(__bvh_nodes, node_addr+0);
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#if !defined(__KERNEL_SSE2__)
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traverse_mask = NODE_INTERSECT(kg,
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P,
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# if BVH_FEATURE(BVH_HAIR)
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dir,
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# endif
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idir,
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isect->t,
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node_addr,
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visibility,
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dist);
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#else // __KERNEL_SSE2__
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traverse_mask = NODE_INTERSECT(kg,
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P,
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dir,
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# if BVH_FEATURE(BVH_HAIR)
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tnear,
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tfar,
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# endif
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tsplat,
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Psplat,
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idirsplat,
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shufflexyz,
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node_addr,
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visibility,
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dist);
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#endif // __KERNEL_SSE2__
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node_addr = __float_as_int(cnodes.z);
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node_addr_child1 = __float_as_int(cnodes.w);
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if(traverse_mask == 3) {
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/* Both children were intersected, push the farther one. */
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bool is_closest_child1 = (dist[1] < dist[0]);
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if(is_closest_child1) {
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int tmp = node_addr;
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node_addr = node_addr_child1;
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node_addr_child1 = tmp;
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}
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++stack_ptr;
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kernel_assert(stack_ptr < BVH_STACK_SIZE);
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traversal_stack[stack_ptr] = node_addr_child1;
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}
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else {
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/* One child was intersected. */
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if(traverse_mask == 2) {
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node_addr = node_addr_child1;
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}
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else if(traverse_mask == 0) {
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/* Neither child was intersected. */
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node_addr = traversal_stack[stack_ptr];
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--stack_ptr;
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}
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}
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}
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/* if node is leaf, fetch triangle list */
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if(node_addr < 0) {
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float4 leaf = kernel_tex_fetch(__bvh_leaf_nodes, (-node_addr-1));
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int prim_addr = __float_as_int(leaf.x);
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#if BVH_FEATURE(BVH_INSTANCING)
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if(prim_addr >= 0) {
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#endif
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const int prim_addr2 = __float_as_int(leaf.y);
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const uint type = __float_as_int(leaf.w);
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/* pop */
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node_addr = traversal_stack[stack_ptr];
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--stack_ptr;
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/* primitive intersection */
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switch(type & PRIMITIVE_ALL) {
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case PRIMITIVE_TRIANGLE: {
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/* intersect ray against primitive */
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for(; prim_addr < prim_addr2; prim_addr++) {
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kernel_assert(kernel_tex_fetch(__prim_type, prim_addr) == type);
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/* only primitives from volume object */
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uint tri_object = (object == OBJECT_NONE)? kernel_tex_fetch(__prim_object, prim_addr): object;
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int object_flag = kernel_tex_fetch(__object_flag, tri_object);
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if((object_flag & SD_OBJECT_HAS_VOLUME) == 0) {
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continue;
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}
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triangle_intersect(kg,
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&isect_precalc,
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isect,
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P,
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visibility,
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object,
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prim_addr);
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}
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break;
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}
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#if BVH_FEATURE(BVH_MOTION)
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case PRIMITIVE_MOTION_TRIANGLE: {
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/* intersect ray against primitive */
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for(; prim_addr < prim_addr2; prim_addr++) {
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kernel_assert(kernel_tex_fetch(__prim_type, prim_addr) == type);
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/* only primitives from volume object */
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uint tri_object = (object == OBJECT_NONE)? kernel_tex_fetch(__prim_object, prim_addr): object;
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int object_flag = kernel_tex_fetch(__object_flag, tri_object);
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if((object_flag & SD_OBJECT_HAS_VOLUME) == 0) {
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continue;
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}
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motion_triangle_intersect(kg,
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isect,
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P,
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dir,
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ray->time,
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visibility,
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object,
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prim_addr);
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}
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break;
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}
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#endif
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default: {
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break;
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}
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}
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}
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#if BVH_FEATURE(BVH_INSTANCING)
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else {
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/* instance push */
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object = kernel_tex_fetch(__prim_object, -prim_addr-1);
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int object_flag = kernel_tex_fetch(__object_flag, object);
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if(object_flag & SD_OBJECT_HAS_VOLUME) {
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# if BVH_FEATURE(BVH_MOTION)
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bvh_instance_motion_push(kg, object, ray, &P, &dir, &idir, &isect->t, &ob_itfm);
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# else
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bvh_instance_push(kg, object, ray, &P, &dir, &idir, &isect->t);
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# endif
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triangle_intersect_precalc(dir, &isect_precalc);
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# if defined(__KERNEL_SSE2__)
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Psplat[0] = ssef(P.x);
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Psplat[1] = ssef(P.y);
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Psplat[2] = ssef(P.z);
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tsplat = ssef(0.0f, 0.0f, -isect->t, -isect->t);
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# if BVH_FEATURE(BVH_HAIR)
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tfar = ssef(isect->t);
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# endif
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gen_idirsplat_swap(pn, shuf_identity, shuf_swap, idir, idirsplat, shufflexyz);
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# endif
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++stack_ptr;
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kernel_assert(stack_ptr < BVH_STACK_SIZE);
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traversal_stack[stack_ptr] = ENTRYPOINT_SENTINEL;
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node_addr = kernel_tex_fetch(__object_node, object);
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}
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else {
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/* pop */
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object = OBJECT_NONE;
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node_addr = traversal_stack[stack_ptr];
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--stack_ptr;
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}
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}
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}
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#endif /* FEATURE(BVH_INSTANCING) */
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} while(node_addr != ENTRYPOINT_SENTINEL);
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#if BVH_FEATURE(BVH_INSTANCING)
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if(stack_ptr >= 0) {
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kernel_assert(object != OBJECT_NONE);
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/* instance pop */
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# if BVH_FEATURE(BVH_MOTION)
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bvh_instance_motion_pop(kg, object, ray, &P, &dir, &idir, &isect->t, &ob_itfm);
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# else
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bvh_instance_pop(kg, object, ray, &P, &dir, &idir, &isect->t);
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# endif
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triangle_intersect_precalc(dir, &isect_precalc);
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# if defined(__KERNEL_SSE2__)
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Psplat[0] = ssef(P.x);
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Psplat[1] = ssef(P.y);
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Psplat[2] = ssef(P.z);
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tsplat = ssef(0.0f, 0.0f, -isect->t, -isect->t);
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# if BVH_FEATURE(BVH_HAIR)
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tfar = ssef(isect->t);
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# endif
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gen_idirsplat_swap(pn, shuf_identity, shuf_swap, idir, idirsplat, shufflexyz);
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# endif
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object = OBJECT_NONE;
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node_addr = traversal_stack[stack_ptr];
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--stack_ptr;
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}
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#endif /* FEATURE(BVH_MOTION) */
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} while(node_addr != ENTRYPOINT_SENTINEL);
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return (isect->prim != PRIM_NONE);
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}
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ccl_device_inline bool BVH_FUNCTION_NAME(KernelGlobals *kg,
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const Ray *ray,
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Intersection *isect,
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const uint visibility)
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{
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#ifdef __QBVH__
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if(kernel_data.bvh.use_qbvh) {
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return BVH_FUNCTION_FULL_NAME(QBVH)(kg,
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ray,
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isect,
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visibility);
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}
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else
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#endif
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{
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kernel_assert(kernel_data.bvh.use_qbvh == false);
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return BVH_FUNCTION_FULL_NAME(BVH)(kg,
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ray,
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isect,
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visibility);
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}
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}
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#undef BVH_FUNCTION_NAME
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#undef BVH_FUNCTION_FEATURES
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#undef NODE_INTERSECT
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