// Copyright 2009-2020 Intel Corporation // SPDX-License-Identifier: Apache-2.0 #pragma once #include "../common/builder.h" #include "../../common/algorithms/parallel_reduce.h" namespace embree { namespace isa { struct BVHBuilderMorton { static const size_t MAX_BRANCHING_FACTOR = 8; //!< maximum supported BVH branching factor static const size_t MIN_LARGE_LEAF_LEVELS = 8; //!< create balanced tree of we are that many levels before the maximum tree depth /*! settings for morton builder */ struct Settings { /*! default settings */ Settings () : branchingFactor(2), maxDepth(32), minLeafSize(1), maxLeafSize(7), singleThreadThreshold(1024) {} /*! initialize settings from API settings */ Settings (const RTCBuildArguments& settings) : branchingFactor(2), maxDepth(32), minLeafSize(1), maxLeafSize(7), singleThreadThreshold(1024) { if (RTC_BUILD_ARGUMENTS_HAS(settings,maxBranchingFactor)) branchingFactor = settings.maxBranchingFactor; if (RTC_BUILD_ARGUMENTS_HAS(settings,maxDepth )) maxDepth = settings.maxDepth; if (RTC_BUILD_ARGUMENTS_HAS(settings,minLeafSize )) minLeafSize = settings.minLeafSize; if (RTC_BUILD_ARGUMENTS_HAS(settings,maxLeafSize )) maxLeafSize = settings.maxLeafSize; minLeafSize = min(minLeafSize,maxLeafSize); } Settings (size_t branchingFactor, size_t maxDepth, size_t minLeafSize, size_t maxLeafSize, size_t singleThreadThreshold) : branchingFactor(branchingFactor), maxDepth(maxDepth), minLeafSize(minLeafSize), maxLeafSize(maxLeafSize), singleThreadThreshold(singleThreadThreshold) { minLeafSize = min(minLeafSize,maxLeafSize); } public: size_t branchingFactor; //!< branching factor of BVH to build size_t maxDepth; //!< maximum depth of BVH to build size_t minLeafSize; //!< minimum size of a leaf size_t maxLeafSize; //!< maximum size of a leaf size_t singleThreadThreshold; //!< threshold when we switch to single threaded build }; /*! Build primitive consisting of morton code and primitive ID. */ struct __aligned(8) BuildPrim { union { struct { unsigned int code; //!< morton code unsigned int index; //!< i'th primitive }; uint64_t t; }; /*! interface for radix sort */ __forceinline operator unsigned() const { return code; } /*! interface for standard sort */ __forceinline bool operator<(const BuildPrim &m) const { return code < m.code; } }; /*! maps bounding box to morton code */ struct MortonCodeMapping { static const size_t LATTICE_BITS_PER_DIM = 10; static const size_t LATTICE_SIZE_PER_DIM = size_t(1) << LATTICE_BITS_PER_DIM; vfloat4 base; vfloat4 scale; __forceinline MortonCodeMapping(const BBox3fa& bounds) { base = (vfloat4)bounds.lower; const vfloat4 diag = (vfloat4)bounds.upper - (vfloat4)bounds.lower; scale = select(diag > vfloat4(1E-19f), rcp(diag) * vfloat4(LATTICE_SIZE_PER_DIM * 0.99f),vfloat4(0.0f)); } __forceinline const vint4 bin (const BBox3fa& box) const { const vfloat4 lower = (vfloat4)box.lower; const vfloat4 upper = (vfloat4)box.upper; const vfloat4 centroid = lower+upper; return vint4((centroid-base)*scale); } __forceinline unsigned int code (const BBox3fa& box) const { const vint4 binID = bin(box); const unsigned int x = extract<0>(binID); const unsigned int y = extract<1>(binID); const unsigned int z = extract<2>(binID); const unsigned int xyz = bitInterleave(x,y,z); return xyz; } }; #if defined (__AVX2__) /*! for AVX2 there is a fast scalar bitInterleave */ struct MortonCodeGenerator { __forceinline MortonCodeGenerator(const MortonCodeMapping& mapping, BuildPrim* dest) : mapping(mapping), dest(dest) {} __forceinline void operator() (const BBox3fa& b, const unsigned index) { dest->index = index; dest->code = mapping.code(b); dest++; } public: const MortonCodeMapping mapping; BuildPrim* dest; size_t currentID; }; #else /*! before AVX2 is it better to use the SSE version of bitInterleave */ struct MortonCodeGenerator { __forceinline MortonCodeGenerator(const MortonCodeMapping& mapping, BuildPrim* dest) : mapping(mapping), dest(dest), currentID(0), slots(0), ax(0), ay(0), az(0), ai(0) {} __forceinline ~MortonCodeGenerator() { if (slots != 0) { const vint4 code = bitInterleave(ax,ay,az); for (size_t i=0; i(binID); ay[slots] = extract<1>(binID); az[slots] = extract<2>(binID); ai[slots] = index; slots++; currentID++; if (slots == 4) { const vint4 code = bitInterleave(ax,ay,az); vint4::storeu(&dest[currentID-4],unpacklo(code,ai)); vint4::storeu(&dest[currentID-2],unpackhi(code,ai)); slots = 0; } } public: const MortonCodeMapping mapping; BuildPrim* dest; size_t currentID; size_t slots; vint4 ax, ay, az, ai; }; #endif template< typename ReductionTy, typename Allocator, typename CreateAllocator, typename CreateNodeFunc, typename SetNodeBoundsFunc, typename CreateLeafFunc, typename CalculateBounds, typename ProgressMonitor> class BuilderT : private Settings { ALIGNED_CLASS_(16); public: BuilderT (CreateAllocator& createAllocator, CreateNodeFunc& createNode, SetNodeBoundsFunc& setBounds, CreateLeafFunc& createLeaf, CalculateBounds& calculateBounds, ProgressMonitor& progressMonitor, const Settings& settings) : Settings(settings), createAllocator(createAllocator), createNode(createNode), setBounds(setBounds), createLeaf(createLeaf), calculateBounds(calculateBounds), progressMonitor(progressMonitor), morton(nullptr) {} ReductionTy createLargeLeaf(size_t depth, const range& current, Allocator alloc) { /* this should never occur but is a fatal error */ if (depth > maxDepth) throw_RTCError(RTC_ERROR_UNKNOWN,"depth limit reached"); /* create leaf for few primitives */ if (current.size() <= maxLeafSize) return createLeaf(current,alloc); /* fill all children by always splitting the largest one */ range children[MAX_BRANCHING_FACTOR]; size_t numChildren = 1; children[0] = current; do { /* find best child with largest number of primitives */ size_t bestChild = -1; size_t bestSize = 0; for (size_t i=0; i bestSize) { bestSize = children[i].size(); bestChild = i; } } if (bestChild == size_t(-1)) break; /*! split best child into left and right child */ auto split = children[bestChild].split(); /* add new children left and right */ children[bestChild] = children[numChildren-1]; children[numChildren-1] = split.first; children[numChildren+0] = split.second; numChildren++; } while (numChildren < branchingFactor); /* create node */ auto node = createNode(alloc,numChildren); /* recurse into each child */ ReductionTy bounds[MAX_BRANCHING_FACTOR]; for (size_t i=0; i& current) const { /* fast path for small ranges */ if (likely(current.size() < 1024)) { /*! recalculate centroid bounds */ BBox3fa centBounds(empty); for (size_t i=current.begin(); i& r ) { BBox3fa centBounds = empty; for (size_t i=r.begin(); i& r ) { for (size_t i=r.begin(); i& current, range& left, range& right) const { const unsigned int code_start = morton[current.begin()].code; const unsigned int code_end = morton[current.end()-1].code; unsigned int bitpos = lzcnt(code_start^code_end); /* if all items mapped to same morton code, then re-create new morton codes for the items */ if (unlikely(bitpos == 32)) { recreateMortonCodes(current); const unsigned int code_start = morton[current.begin()].code; const unsigned int code_end = morton[current.end()-1].code; bitpos = lzcnt(code_start^code_end); /* if the morton code is still the same, goto fall back split */ if (unlikely(bitpos == 32)) { current.split(left,right); return; } } /* split the items at the topmost different morton code bit */ const unsigned int bitpos_diff = 31-bitpos; const unsigned int bitmask = 1 << bitpos_diff; /* find location where bit differs using binary search */ unsigned begin = current.begin(); unsigned end = current.end(); while (begin + 1 != end) { const unsigned mid = (begin+end)/2; const unsigned bit = morton[mid].code & bitmask; if (bit == 0) begin = mid; else end = mid; } unsigned center = end; #if defined(DEBUG) for (unsigned int i=begin; i& current, Allocator alloc, bool toplevel) { /* get thread local allocator */ if (!alloc) alloc = createAllocator(); /* call memory monitor function to signal progress */ if (toplevel && current.size() <= singleThreadThreshold) progressMonitor(current.size()); /* create leaf node */ if (unlikely(depth+MIN_LARGE_LEAF_LEVELS >= maxDepth || current.size() <= minLeafSize)) return createLargeLeaf(depth,current,alloc); /* fill all children by always splitting the one with the largest surface area */ range children[MAX_BRANCHING_FACTOR]; split(current,children[0],children[1]); size_t numChildren = 2; while (numChildren < branchingFactor) { /* find best child with largest number of primitives */ int bestChild = -1; unsigned bestItems = 0; for (unsigned int i=0; i bestItems) { bestItems = children[i].size(); bestChild = i; } } if (bestChild == -1) break; /*! split best child into left and right child */ range left, right; split(children[bestChild],left,right); /* add new children left and right */ children[bestChild] = children[numChildren-1]; children[numChildren-1] = left; children[numChildren+0] = right; numChildren++; } /* create leaf node if no split is possible */ if (unlikely(numChildren == 1)) return createLeaf(current,alloc); /* allocate node */ auto node = createNode(alloc,numChildren); /* process top parts of tree parallel */ ReductionTy bounds[MAX_BRANCHING_FACTOR]; if (current.size() > singleThreadThreshold) { /*! parallel_for is faster than spawing sub-tasks */ parallel_for(size_t(0), numChildren, [&] (const range& r) { for (size_t i=r.begin(); i(0,(unsigned)numPrimitives), nullptr, true); _mm_mfence(); // to allow non-temporal stores during build return root; } public: CreateAllocator& createAllocator; CreateNodeFunc& createNode; SetNodeBoundsFunc& setBounds; CreateLeafFunc& createLeaf; CalculateBounds& calculateBounds; ProgressMonitor& progressMonitor; public: BuildPrim* morton; }; template< typename ReductionTy, typename CreateAllocFunc, typename CreateNodeFunc, typename SetBoundsFunc, typename CreateLeafFunc, typename CalculateBoundsFunc, typename ProgressMonitor> static ReductionTy build(CreateAllocFunc createAllocator, CreateNodeFunc createNode, SetBoundsFunc setBounds, CreateLeafFunc createLeaf, CalculateBoundsFunc calculateBounds, ProgressMonitor progressMonitor, BuildPrim* src, BuildPrim* tmp, size_t numPrimitives, const Settings& settings) { typedef BuilderT< ReductionTy, decltype(createAllocator()), CreateAllocFunc, CreateNodeFunc, SetBoundsFunc, CreateLeafFunc, CalculateBoundsFunc, ProgressMonitor> Builder; Builder builder(createAllocator, createNode, setBounds, createLeaf, calculateBounds, progressMonitor, settings); return builder.build(src,tmp,numPrimitives); } }; } }