// Copyright 2009-2020 Intel Corporation // SPDX-License-Identifier: Apache-2.0 #pragma once #include "heuristic_binning.h" namespace embree { namespace isa { struct PrimInfoRange : public CentGeomBBox3fa, public range { __forceinline PrimInfoRange () { } __forceinline PrimInfoRange(const PrimInfo& pinfo) : CentGeomBBox3fa(pinfo), range(pinfo.begin,pinfo.end) {} __forceinline PrimInfoRange(EmptyTy) : CentGeomBBox3fa(EmptyTy()), range(0,0) {} __forceinline PrimInfoRange (size_t begin, size_t end, const CentGeomBBox3fa& centGeomBounds) : CentGeomBBox3fa(centGeomBounds), range(begin,end) {} __forceinline float leafSAH() const { return expectedApproxHalfArea(geomBounds)*float(size()); } __forceinline float leafSAH(size_t block_shift) const { return expectedApproxHalfArea(geomBounds)*float((size()+(size_t(1)<> block_shift); } }; /*! Performs standard object binning */ template struct HeuristicArrayBinningSAH { typedef BinSplit Split; typedef BinInfoT Binner; typedef range Set; #if defined(__AVX512ER__) // KNL static const size_t PARALLEL_THRESHOLD = 4*768; static const size_t PARALLEL_FIND_BLOCK_SIZE = 768; static const size_t PARALLEL_PARTITION_BLOCK_SIZE = 768; #else static const size_t PARALLEL_THRESHOLD = 3 * 1024; static const size_t PARALLEL_FIND_BLOCK_SIZE = 1024; static const size_t PARALLEL_PARTITION_BLOCK_SIZE = 128; #endif __forceinline HeuristicArrayBinningSAH () : prims(nullptr) {} /*! remember prim array */ __forceinline HeuristicArrayBinningSAH (PrimRef* prims) : prims(prims) {} /*! finds the best split */ __noinline const Split find(const PrimInfoRange& pinfo, const size_t logBlockSize) { if (likely(pinfo.size() < PARALLEL_THRESHOLD)) return find_template(pinfo,logBlockSize); else return find_template(pinfo,logBlockSize); } template __forceinline const Split find_template(const PrimInfoRange& pinfo, const size_t logBlockSize) { Binner binner(empty); const BinMapping mapping(pinfo); bin_serial_or_parallel(binner,prims,pinfo.begin(),pinfo.end(),PARALLEL_FIND_BLOCK_SIZE,mapping); return binner.best(mapping,logBlockSize); } /*! array partitioning */ __forceinline void split(const Split& split, const PrimInfoRange& pinfo, PrimInfoRange& linfo, PrimInfoRange& rinfo) { if (likely(pinfo.size() < PARALLEL_THRESHOLD)) split_template(split,pinfo,linfo,rinfo); else split_template(split,pinfo,linfo,rinfo); } template __forceinline void split_template(const Split& split, const PrimInfoRange& set, PrimInfoRange& lset, PrimInfoRange& rset) { if (!split.valid()) { deterministic_order(set); return splitFallback(set,lset,rset); } const size_t begin = set.begin(); const size_t end = set.end(); CentGeomBBox3fa local_left(empty); CentGeomBBox3fa local_right(empty); const unsigned int splitPos = split.pos; const unsigned int splitDim = split.dim; const unsigned int splitDimMask = (unsigned int)1 << splitDim; const typename Binner::vint vSplitPos(splitPos); const typename Binner::vbool vSplitMask(splitDimMask); auto isLeft = [&] (const PrimRef &ref) { return split.mapping.bin_unsafe(ref,vSplitPos,vSplitMask); }; size_t center = 0; if (!parallel) center = serial_partitioning(prims,begin,end,local_left,local_right,isLeft, [] (CentGeomBBox3fa& pinfo,const PrimRef& ref) { pinfo.extend_center2(ref); }); else center = parallel_partitioning( prims,begin,end,EmptyTy(),local_left,local_right,isLeft, [] (CentGeomBBox3fa& pinfo,const PrimRef& ref) { pinfo.extend_center2(ref); }, [] (CentGeomBBox3fa& pinfo0,const CentGeomBBox3fa& pinfo1) { pinfo0.merge(pinfo1); }, PARALLEL_PARTITION_BLOCK_SIZE); new (&lset) PrimInfoRange(begin,center,local_left); new (&rset) PrimInfoRange(center,end,local_right); assert(area(lset.geomBounds) >= 0.0f); assert(area(rset.geomBounds) >= 0.0f); } void deterministic_order(const PrimInfoRange& pinfo) { /* required as parallel partition destroys original primitive order */ std::sort(&prims[pinfo.begin()],&prims[pinfo.end()]); } void splitFallback(const PrimInfoRange& pinfo, PrimInfoRange& linfo, PrimInfoRange& rinfo) { const size_t begin = pinfo.begin(); const size_t end = pinfo.end(); const size_t center = (begin + end)/2; CentGeomBBox3fa left(empty); for (size_t i=begin; i& range, PrimInfoRange& linfo, PrimInfoRange& rinfo) { assert(range.size() > 1); CentGeomBBox3fa left(empty); CentGeomBBox3fa right(empty); unsigned int geomID = prims[range.begin()].geomID(); size_t center = serial_partitioning(prims,range.begin(),range.end(),left,right, [&] ( const PrimRef& prim ) { return prim.geomID() == geomID; }, [ ] ( CentGeomBBox3fa& a, const PrimRef& ref ) { a.extend_center2(ref); }); new (&linfo) PrimInfoRange(range.begin(),center,left); new (&rinfo) PrimInfoRange(center,range.end(),right); } private: PrimRef* const prims; }; /*! Performs standard object binning */ template struct HeuristicArrayBinningMB { typedef BinSplit Split; typedef typename PrimRefMB::BBox BBox; typedef BinInfoT ObjectBinner; static const size_t PARALLEL_THRESHOLD = 3 * 1024; static const size_t PARALLEL_FIND_BLOCK_SIZE = 1024; static const size_t PARALLEL_PARTITION_BLOCK_SIZE = 128; /*! finds the best split */ const Split find(const SetMB& set, const size_t logBlockSize) { ObjectBinner binner(empty); const BinMapping mapping(set.size(),set.centBounds); bin_parallel(binner,set.prims->data(),set.begin(),set.end(),PARALLEL_FIND_BLOCK_SIZE,PARALLEL_THRESHOLD,mapping); Split osplit = binner.best(mapping,logBlockSize); osplit.sah *= set.time_range.size(); if (!osplit.valid()) osplit.data = Split::SPLIT_FALLBACK; // use fallback split return osplit; } /*! array partitioning */ __forceinline void split(const Split& split, const SetMB& set, SetMB& lset, SetMB& rset) { const size_t begin = set.begin(); const size_t end = set.end(); PrimInfoMB left = empty; PrimInfoMB right = empty; const vint4 vSplitPos(split.pos); const vbool4 vSplitMask(1 << split.dim); auto isLeft = [&] (const PrimRefMB &ref) { return any(((vint4)split.mapping.bin_unsafe(ref) < vSplitPos) & vSplitMask); }; auto reduction = [] (PrimInfoMB& pinfo, const PrimRefMB& ref) { pinfo.add_primref(ref); }; auto reduction2 = [] (PrimInfoMB& pinfo0,const PrimInfoMB& pinfo1) { pinfo0.merge(pinfo1); }; size_t center = parallel_partitioning(set.prims->data(),begin,end,EmptyTy(),left,right,isLeft,reduction,reduction2,PARALLEL_PARTITION_BLOCK_SIZE,PARALLEL_THRESHOLD); new (&lset) SetMB(left, set.prims,range(begin,center),set.time_range); new (&rset) SetMB(right,set.prims,range(center,end ),set.time_range); } }; } }