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Since Embree v3.13.0 supports AARCH64, switch back to the official repo instead of using Embree-aarch64. `thirdparty/embree/patches/godot-changes.patch` should now contain an accurate diff of the changes done to the library.
467 lines
17 KiB
C++
467 lines
17 KiB
C++
// Copyright 2009-2021 Intel Corporation
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// SPDX-License-Identifier: Apache-2.0
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#pragma once
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#include "bvh.h"
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#include "node_intersector1.h"
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#include "../common/stack_item.h"
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#define NEW_SORTING_CODE 1
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namespace embree
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{
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namespace isa
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{
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/*! BVH regular node traversal for single rays. */
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template<int N, int types>
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class BVHNNodeTraverser1Hit;
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#if defined(__AVX512VL__) // SKX
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template<int N>
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__forceinline void isort_update(vint<N> &dist, const vint<N> &d)
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{
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const vint<N> dist_shift = align_shift_right<N-1>(dist,dist);
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const vboolf<N> m_geq = d >= dist;
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const vboolf<N> m_geq_shift = m_geq << 1;
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dist = select(m_geq,d,dist);
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dist = select(m_geq_shift,dist_shift,dist);
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}
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template<int N>
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__forceinline void isort_quick_update(vint<N> &dist, const vint<N> &d) {
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dist = align_shift_right<N-1>(dist,permute(d,vint<N>(zero)));
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}
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__forceinline size_t permuteExtract(const vint8& index, const vllong4& n0, const vllong4& n1) {
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return toScalar(permutex2var((__m256i)index,n0,n1));
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}
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__forceinline float permuteExtract(const vint8& index, const vfloat8& n) {
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return toScalar(permute(n,index));
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}
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#endif
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/* Specialization for BVH4. */
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template<int types>
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class BVHNNodeTraverser1Hit<4, types>
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{
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typedef BVH4 BVH;
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typedef BVH4::NodeRef NodeRef;
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typedef BVH4::BaseNode BaseNode;
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public:
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/* Traverses a node with at least one hit child. Optimized for finding the closest hit (intersection). */
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static __forceinline void traverseClosestHit(NodeRef& cur,
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size_t mask,
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const vfloat4& tNear,
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StackItemT<NodeRef>*& stackPtr,
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StackItemT<NodeRef>* stackEnd)
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{
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assert(mask != 0);
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const BaseNode* node = cur.baseNode();
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/*! one child is hit, continue with that child */
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size_t r = bscf(mask);
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cur = node->child(r);
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BVH::prefetch(cur,types);
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if (likely(mask == 0)) {
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assert(cur != BVH::emptyNode);
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return;
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}
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/*! two children are hit, push far child, and continue with closer child */
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NodeRef c0 = cur;
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const unsigned int d0 = ((unsigned int*)&tNear)[r];
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r = bscf(mask);
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NodeRef c1 = node->child(r);
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BVH::prefetch(c1,types);
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const unsigned int d1 = ((unsigned int*)&tNear)[r];
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assert(c0 != BVH::emptyNode);
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assert(c1 != BVH::emptyNode);
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if (likely(mask == 0)) {
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assert(stackPtr < stackEnd);
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if (d0 < d1) { stackPtr->ptr = c1; stackPtr->dist = d1; stackPtr++; cur = c0; return; }
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else { stackPtr->ptr = c0; stackPtr->dist = d0; stackPtr++; cur = c1; return; }
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}
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#if NEW_SORTING_CODE == 1
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vint4 s0((size_t)c0,(size_t)d0);
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vint4 s1((size_t)c1,(size_t)d1);
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r = bscf(mask);
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NodeRef c2 = node->child(r); BVH::prefetch(c2,types); unsigned int d2 = ((unsigned int*)&tNear)[r];
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vint4 s2((size_t)c2,(size_t)d2);
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/* 3 hits */
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if (likely(mask == 0)) {
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StackItemT<NodeRef>::sort3(s0,s1,s2);
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*(vint4*)&stackPtr[0] = s0; *(vint4*)&stackPtr[1] = s1;
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cur = toSizeT(s2);
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stackPtr+=2;
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return;
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}
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r = bscf(mask);
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NodeRef c3 = node->child(r); BVH::prefetch(c3,types); unsigned int d3 = ((unsigned int*)&tNear)[r];
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vint4 s3((size_t)c3,(size_t)d3);
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/* 4 hits */
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StackItemT<NodeRef>::sort4(s0,s1,s2,s3);
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*(vint4*)&stackPtr[0] = s0; *(vint4*)&stackPtr[1] = s1; *(vint4*)&stackPtr[2] = s2;
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cur = toSizeT(s3);
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stackPtr+=3;
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#else
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/*! Here starts the slow path for 3 or 4 hit children. We push
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* all nodes onto the stack to sort them there. */
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assert(stackPtr < stackEnd);
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stackPtr->ptr = c0; stackPtr->dist = d0; stackPtr++;
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assert(stackPtr < stackEnd);
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stackPtr->ptr = c1; stackPtr->dist = d1; stackPtr++;
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/*! three children are hit, push all onto stack and sort 3 stack items, continue with closest child */
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assert(stackPtr < stackEnd);
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r = bscf(mask);
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NodeRef c = node->child(r); BVH::prefetch(c,types); unsigned int d = ((unsigned int*)&tNear)[r]; stackPtr->ptr = c; stackPtr->dist = d; stackPtr++;
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assert(c != BVH::emptyNode);
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if (likely(mask == 0)) {
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sort(stackPtr[-1],stackPtr[-2],stackPtr[-3]);
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cur = (NodeRef) stackPtr[-1].ptr; stackPtr--;
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return;
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}
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/*! four children are hit, push all onto stack and sort 4 stack items, continue with closest child */
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assert(stackPtr < stackEnd);
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r = bscf(mask);
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c = node->child(r); BVH::prefetch(c,types); d = *(unsigned int*)&tNear[r]; stackPtr->ptr = c; stackPtr->dist = d; stackPtr++;
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assert(c != BVH::emptyNode);
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sort(stackPtr[-1],stackPtr[-2],stackPtr[-3],stackPtr[-4]);
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cur = (NodeRef) stackPtr[-1].ptr; stackPtr--;
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#endif
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}
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/* Traverses a node with at least one hit child. Optimized for finding any hit (occlusion). */
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static __forceinline void traverseAnyHit(NodeRef& cur,
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size_t mask,
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const vfloat4& tNear,
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NodeRef*& stackPtr,
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NodeRef* stackEnd)
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{
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const BaseNode* node = cur.baseNode();
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/*! one child is hit, continue with that child */
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size_t r = bscf(mask);
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cur = node->child(r);
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BVH::prefetch(cur,types);
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/* simpler in sequence traversal order */
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assert(cur != BVH::emptyNode);
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if (likely(mask == 0)) return;
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assert(stackPtr < stackEnd);
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*stackPtr = cur; stackPtr++;
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for (; ;)
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{
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r = bscf(mask);
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cur = node->child(r); BVH::prefetch(cur,types);
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assert(cur != BVH::emptyNode);
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if (likely(mask == 0)) return;
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assert(stackPtr < stackEnd);
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*stackPtr = cur; stackPtr++;
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}
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}
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};
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/* Specialization for BVH8. */
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template<int types>
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class BVHNNodeTraverser1Hit<8, types>
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{
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typedef BVH8 BVH;
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typedef BVH8::NodeRef NodeRef;
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typedef BVH8::BaseNode BaseNode;
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#if defined(__AVX512VL__)
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template<class NodeRef, class BaseNode>
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static __forceinline void traverseClosestHitAVX512VL8(NodeRef& cur,
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size_t mask,
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const vfloat8& tNear,
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StackItemT<NodeRef>*& stackPtr,
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StackItemT<NodeRef>* stackEnd)
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{
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assert(mask != 0);
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const BaseNode* node = cur.baseNode();
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const vllong4 n0 = vllong4::loadu((vllong4*)&node->children[0]);
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const vllong4 n1 = vllong4::loadu((vllong4*)&node->children[4]);
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vint8 distance_i = (asInt(tNear) & 0xfffffff8) | vint8(step);
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distance_i = vint8::compact((int)mask,distance_i,distance_i);
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cur = permuteExtract(distance_i,n0,n1);
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BVH::prefetch(cur,types);
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mask &= mask-1;
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if (likely(mask == 0)) return;
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/* 2 hits: order A0 B0 */
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const vint8 d0(distance_i);
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const vint8 d1(shuffle<1>(distance_i));
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cur = permuteExtract(d1,n0,n1);
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BVH::prefetch(cur,types);
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const vint8 dist_A0 = min(d0, d1);
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const vint8 dist_B0 = max(d0, d1);
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assert(dist_A0[0] < dist_B0[0]);
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mask &= mask-1;
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if (likely(mask == 0)) {
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cur = permuteExtract(dist_A0,n0,n1);
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stackPtr[0].ptr = permuteExtract(dist_B0,n0,n1);
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*(float*)&stackPtr[0].dist = permuteExtract(dist_B0,tNear);
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stackPtr++;
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return;
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}
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/* 3 hits: order A1 B1 C1 */
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const vint8 d2(shuffle<2>(distance_i));
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cur = permuteExtract(d2,n0,n1);
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BVH::prefetch(cur,types);
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const vint8 dist_A1 = min(dist_A0,d2);
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const vint8 dist_tmp_B1 = max(dist_A0,d2);
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const vint8 dist_B1 = min(dist_B0,dist_tmp_B1);
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const vint8 dist_C1 = max(dist_B0,dist_tmp_B1);
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assert(dist_A1[0] < dist_B1[0]);
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assert(dist_B1[0] < dist_C1[0]);
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mask &= mask-1;
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if (likely(mask == 0)) {
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cur = permuteExtract(dist_A1,n0,n1);
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stackPtr[0].ptr = permuteExtract(dist_C1,n0,n1);
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*(float*)&stackPtr[0].dist = permuteExtract(dist_C1,tNear);
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stackPtr[1].ptr = permuteExtract(dist_B1,n0,n1);
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*(float*)&stackPtr[1].dist = permuteExtract(dist_B1,tNear);
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stackPtr+=2;
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return;
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}
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/* 4 hits: order A2 B2 C2 D2 */
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const vint8 d3(shuffle<3>(distance_i));
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cur = permuteExtract(d3,n0,n1);
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BVH::prefetch(cur,types);
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const vint8 dist_A2 = min(dist_A1,d3);
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const vint8 dist_tmp_B2 = max(dist_A1,d3);
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const vint8 dist_B2 = min(dist_B1,dist_tmp_B2);
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const vint8 dist_tmp_C2 = max(dist_B1,dist_tmp_B2);
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const vint8 dist_C2 = min(dist_C1,dist_tmp_C2);
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const vint8 dist_D2 = max(dist_C1,dist_tmp_C2);
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assert(dist_A2[0] < dist_B2[0]);
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assert(dist_B2[0] < dist_C2[0]);
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assert(dist_C2[0] < dist_D2[0]);
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mask &= mask-1;
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if (likely(mask == 0)) {
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cur = permuteExtract(dist_A2,n0,n1);
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stackPtr[0].ptr = permuteExtract(dist_D2,n0,n1);
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*(float*)&stackPtr[0].dist = permuteExtract(dist_D2,tNear);
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stackPtr[1].ptr = permuteExtract(dist_C2,n0,n1);
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*(float*)&stackPtr[1].dist = permuteExtract(dist_C2,tNear);
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stackPtr[2].ptr = permuteExtract(dist_B2,n0,n1);
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*(float*)&stackPtr[2].dist = permuteExtract(dist_B2,tNear);
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stackPtr+=3;
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return;
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}
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/* >=5 hits: reverse to descending order for writing to stack */
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distance_i = align_shift_right<3>(distance_i,distance_i);
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const size_t hits = 4 + popcnt(mask);
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vint8 dist(INT_MIN); // this will work with -0.0f (0x80000000) as distance, isort_update uses >= to insert
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isort_quick_update<8>(dist,dist_A2);
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isort_quick_update<8>(dist,dist_B2);
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isort_quick_update<8>(dist,dist_C2);
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isort_quick_update<8>(dist,dist_D2);
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do {
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distance_i = align_shift_right<1>(distance_i,distance_i);
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cur = permuteExtract(distance_i,n0,n1);
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BVH::prefetch(cur,types);
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const vint8 new_dist(permute(distance_i,vint8(zero)));
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mask &= mask-1;
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isort_update<8>(dist,new_dist);
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} while(mask);
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for (size_t i=0; i<7; i++)
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assert(dist[i+0]>=dist[i+1]);
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for (size_t i=0;i<hits-1;i++)
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{
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stackPtr->ptr = permuteExtract(dist,n0,n1);
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*(float*)&stackPtr->dist = permuteExtract(dist,tNear);
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dist = align_shift_right<1>(dist,dist);
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stackPtr++;
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}
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cur = permuteExtract(dist,n0,n1);
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}
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#endif
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public:
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static __forceinline void traverseClosestHit(NodeRef& cur,
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size_t mask,
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const vfloat8& tNear,
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StackItemT<NodeRef>*& stackPtr,
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StackItemT<NodeRef>* stackEnd)
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{
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assert(mask != 0);
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#if defined(__AVX512VL__)
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traverseClosestHitAVX512VL8<NodeRef,BaseNode>(cur,mask,tNear,stackPtr,stackEnd);
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#else
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const BaseNode* node = cur.baseNode();
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/*! one child is hit, continue with that child */
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size_t r = bscf(mask);
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cur = node->child(r);
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BVH::prefetch(cur,types);
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if (likely(mask == 0)) {
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assert(cur != BVH::emptyNode);
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return;
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}
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/*! two children are hit, push far child, and continue with closer child */
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NodeRef c0 = cur;
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const unsigned int d0 = ((unsigned int*)&tNear)[r];
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r = bscf(mask);
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NodeRef c1 = node->child(r);
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BVH::prefetch(c1,types);
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const unsigned int d1 = ((unsigned int*)&tNear)[r];
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assert(c0 != BVH::emptyNode);
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assert(c1 != BVH::emptyNode);
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if (likely(mask == 0)) {
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assert(stackPtr < stackEnd);
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if (d0 < d1) { stackPtr->ptr = c1; stackPtr->dist = d1; stackPtr++; cur = c0; return; }
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else { stackPtr->ptr = c0; stackPtr->dist = d0; stackPtr++; cur = c1; return; }
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}
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#if NEW_SORTING_CODE == 1
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vint4 s0((size_t)c0,(size_t)d0);
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vint4 s1((size_t)c1,(size_t)d1);
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r = bscf(mask);
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NodeRef c2 = node->child(r); BVH::prefetch(c2,types); unsigned int d2 = ((unsigned int*)&tNear)[r];
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vint4 s2((size_t)c2,(size_t)d2);
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/* 3 hits */
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if (likely(mask == 0)) {
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StackItemT<NodeRef>::sort3(s0,s1,s2);
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*(vint4*)&stackPtr[0] = s0; *(vint4*)&stackPtr[1] = s1;
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cur = toSizeT(s2);
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stackPtr+=2;
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return;
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}
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r = bscf(mask);
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NodeRef c3 = node->child(r); BVH::prefetch(c3,types); unsigned int d3 = ((unsigned int*)&tNear)[r];
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vint4 s3((size_t)c3,(size_t)d3);
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/* 4 hits */
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if (likely(mask == 0)) {
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StackItemT<NodeRef>::sort4(s0,s1,s2,s3);
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*(vint4*)&stackPtr[0] = s0; *(vint4*)&stackPtr[1] = s1; *(vint4*)&stackPtr[2] = s2;
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cur = toSizeT(s3);
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stackPtr+=3;
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return;
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}
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*(vint4*)&stackPtr[0] = s0; *(vint4*)&stackPtr[1] = s1; *(vint4*)&stackPtr[2] = s2; *(vint4*)&stackPtr[3] = s3;
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/*! fallback case if more than 4 children are hit */
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StackItemT<NodeRef>* stackFirst = stackPtr;
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stackPtr+=4;
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while (1)
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{
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assert(stackPtr < stackEnd);
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r = bscf(mask);
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NodeRef c = node->child(r); BVH::prefetch(c,types); unsigned int d = *(unsigned int*)&tNear[r];
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const vint4 s((size_t)c,(size_t)d);
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*(vint4*)stackPtr++ = s;
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assert(c != BVH::emptyNode);
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if (unlikely(mask == 0)) break;
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}
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sort(stackFirst,stackPtr);
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cur = (NodeRef) stackPtr[-1].ptr; stackPtr--;
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#else
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/*! Here starts the slow path for 3 or 4 hit children. We push
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* all nodes onto the stack to sort them there. */
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assert(stackPtr < stackEnd);
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stackPtr->ptr = c0; stackPtr->dist = d0; stackPtr++;
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assert(stackPtr < stackEnd);
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stackPtr->ptr = c1; stackPtr->dist = d1; stackPtr++;
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/*! three children are hit, push all onto stack and sort 3 stack items, continue with closest child */
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assert(stackPtr < stackEnd);
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r = bscf(mask);
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NodeRef c = node->child(r); BVH::prefetch(c,types); unsigned int d = ((unsigned int*)&tNear)[r]; stackPtr->ptr = c; stackPtr->dist = d; stackPtr++;
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assert(c != BVH::emptyNode);
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if (likely(mask == 0)) {
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sort(stackPtr[-1],stackPtr[-2],stackPtr[-3]);
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cur = (NodeRef) stackPtr[-1].ptr; stackPtr--;
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return;
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}
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/*! four children are hit, push all onto stack and sort 4 stack items, continue with closest child */
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assert(stackPtr < stackEnd);
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r = bscf(mask);
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c = node->child(r); BVH::prefetch(c,types); d = *(unsigned int*)&tNear[r]; stackPtr->ptr = c; stackPtr->dist = d; stackPtr++;
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assert(c != BVH::emptyNode);
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if (likely(mask == 0)) {
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sort(stackPtr[-1],stackPtr[-2],stackPtr[-3],stackPtr[-4]);
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cur = (NodeRef) stackPtr[-1].ptr; stackPtr--;
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return;
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}
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/*! fallback case if more than 4 children are hit */
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StackItemT<NodeRef>* stackFirst = stackPtr-4;
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while (1)
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{
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assert(stackPtr < stackEnd);
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r = bscf(mask);
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c = node->child(r); BVH::prefetch(c,types); d = *(unsigned int*)&tNear[r]; stackPtr->ptr = c; stackPtr->dist = d; stackPtr++;
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assert(c != BVH::emptyNode);
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if (unlikely(mask == 0)) break;
|
|
}
|
|
sort(stackFirst,stackPtr);
|
|
cur = (NodeRef) stackPtr[-1].ptr; stackPtr--;
|
|
#endif
|
|
#endif
|
|
}
|
|
|
|
static __forceinline void traverseAnyHit(NodeRef& cur,
|
|
size_t mask,
|
|
const vfloat8& tNear,
|
|
NodeRef*& stackPtr,
|
|
NodeRef* stackEnd)
|
|
{
|
|
const BaseNode* node = cur.baseNode();
|
|
|
|
/*! one child is hit, continue with that child */
|
|
size_t r = bscf(mask);
|
|
cur = node->child(r);
|
|
BVH::prefetch(cur,types);
|
|
|
|
/* simpler in sequence traversal order */
|
|
assert(cur != BVH::emptyNode);
|
|
if (likely(mask == 0)) return;
|
|
assert(stackPtr < stackEnd);
|
|
*stackPtr = cur; stackPtr++;
|
|
|
|
for (; ;)
|
|
{
|
|
r = bscf(mask);
|
|
cur = node->child(r); BVH::prefetch(cur,types);
|
|
assert(cur != BVH::emptyNode);
|
|
if (likely(mask == 0)) return;
|
|
assert(stackPtr < stackEnd);
|
|
*stackPtr = cur; stackPtr++;
|
|
}
|
|
}
|
|
};
|
|
}
|
|
}
|