virtualx-engine/thirdparty/embree-aarch64/kernels/builders/heuristic_timesplit_array.h

// Copyright 2009-2020 Intel Corporation
// SPDX-License-Identifier: Apache-2.0

#pragma once

#include "../common/primref_mb.h"
#include "../../common/algorithms/parallel_filter.h"

#define MBLUR_TIME_SPLIT_THRESHOLD 1.25f

namespace embree
{
  namespace isa
  { 
    /*! Performs standard object binning */
    template<typename PrimRefMB, typename RecalculatePrimRef, size_t BINS>
      struct HeuristicMBlurTemporalSplit
      {
        typedef BinSplit<MBLUR_NUM_OBJECT_BINS> Split;
        typedef mvector<PrimRefMB>* PrimRefVector;
        typedef typename PrimRefMB::BBox BBox; 

        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;

        HeuristicMBlurTemporalSplit (MemoryMonitorInterface* device, const RecalculatePrimRef& recalculatePrimRef)
          : device(device), recalculatePrimRef(recalculatePrimRef) {}

        struct TemporalBinInfo
        {
          __forceinline TemporalBinInfo () {
          }

          __forceinline TemporalBinInfo (EmptyTy)
          {
            for (size_t i=0; i<BINS-1; i++)
            {
              count0[i] = count1[i] = 0;
              bounds0[i] = bounds1[i] = empty;
            }
          }
          
          void bin(const PrimRefMB* prims, size_t begin, size_t end, BBox1f time_range, const SetMB& set, const RecalculatePrimRef& recalculatePrimRef)
          {
            for (int b=0; b<BINS-1; b++)
            {
              const float t = float(b+1)/float(BINS);
              const float ct = lerp(time_range.lower,time_range.upper,t);
              const float center_time = set.align_time(ct);
              if (center_time <= time_range.lower) continue;
              if (center_time >= time_range.upper) continue;
              const BBox1f dt0(time_range.lower,center_time);
              const BBox1f dt1(center_time,time_range.upper);
              
              /* find linear bounds for both time segments */
              for (size_t i=begin; i<end; i++) 
              {
                if (prims[i].time_range_overlap(dt0))
                {
                  const LBBox3fa bn0 = recalculatePrimRef.linearBounds(prims[i],dt0);
#if MBLUR_BIN_LBBOX
                  bounds0[b].extend(bn0);
#else
                  bounds0[b].extend(bn0.interpolate(0.5f));
#endif
                  count0[b] += prims[i].timeSegmentRange(dt0).size();
                }

                if (prims[i].time_range_overlap(dt1))
                {
                  const LBBox3fa bn1 = recalculatePrimRef.linearBounds(prims[i],dt1);
#if MBLUR_BIN_LBBOX
                  bounds1[b].extend(bn1);
#else
                  bounds1[b].extend(bn1.interpolate(0.5f));
#endif
                  count1[b] += prims[i].timeSegmentRange(dt1).size();
                }
              }
            }
          }

          __forceinline void bin_parallel(const PrimRefMB* prims, size_t begin, size_t end, size_t blockSize, size_t parallelThreshold, BBox1f time_range, const SetMB& set, const RecalculatePrimRef& recalculatePrimRef) 
          {
            if (likely(end-begin < parallelThreshold)) {
              bin(prims,begin,end,time_range,set,recalculatePrimRef);
            } 
            else 
            {
              auto bin = [&](const range<size_t>& r) -> TemporalBinInfo { 
                TemporalBinInfo binner(empty); binner.bin(prims, r.begin(), r.end(), time_range, set, recalculatePrimRef); return binner; 
              };
              *this = parallel_reduce(begin,end,blockSize,TemporalBinInfo(empty),bin,merge2);
            }
          }
          
          /*! merges in other binning information */
          __forceinline void merge (const TemporalBinInfo& other)
          {
            for (size_t i=0; i<BINS-1; i++) 
            {
              count0[i] += other.count0[i];
              count1[i] += other.count1[i];
              bounds0[i].extend(other.bounds0[i]);
              bounds1[i].extend(other.bounds1[i]);
            }
          }

          static __forceinline const TemporalBinInfo merge2(const TemporalBinInfo& a, const TemporalBinInfo& b) {
            TemporalBinInfo r = a; r.merge(b); return r;
          }
                    
          Split best(int logBlockSize, BBox1f time_range, const SetMB& set)
          {
            float bestSAH = inf;
            float bestPos = 0.0f;
            for (int b=0; b<BINS-1; b++)
            {
              float t = float(b+1)/float(BINS);
              float ct = lerp(time_range.lower,time_range.upper,t);
              const float center_time = set.align_time(ct);
              if (center_time <= time_range.lower) continue;
              if (center_time >= time_range.upper) continue;
              const BBox1f dt0(time_range.lower,center_time);
              const BBox1f dt1(center_time,time_range.upper);
              
              /* calculate sah */
              const size_t lCount = (count0[b]+(size_t(1) << logBlockSize)-1) >> int(logBlockSize);
              const size_t rCount = (count1[b]+(size_t(1) << logBlockSize)-1) >> int(logBlockSize);
              float sah0 = expectedApproxHalfArea(bounds0[b])*float(lCount)*dt0.size();
              float sah1 = expectedApproxHalfArea(bounds1[b])*float(rCount)*dt1.size();
              if (unlikely(lCount == 0)) sah0 = 0.0f; // happens for initial splits when objects not alive over entire shutter time
              if (unlikely(rCount == 0)) sah1 = 0.0f;
              const float sah = sah0+sah1;
              if (sah < bestSAH) {
                bestSAH = sah;
                bestPos = center_time;
              }
            }
            return Split(bestSAH*MBLUR_TIME_SPLIT_THRESHOLD,(unsigned)Split::SPLIT_TEMPORAL,0,bestPos);
          }
          
        public:
          size_t count0[BINS-1];
          size_t count1[BINS-1];
          BBox bounds0[BINS-1];
          BBox bounds1[BINS-1];
        };
        
        /*! finds the best split */
        const Split find(const SetMB& set, const size_t logBlockSize)
        {
          assert(set.size() > 0);
          TemporalBinInfo binner(empty);
          binner.bin_parallel(set.prims->data(),set.begin(),set.end(),PARALLEL_FIND_BLOCK_SIZE,PARALLEL_THRESHOLD,set.time_range,set,recalculatePrimRef);
          Split tsplit = binner.best((int)logBlockSize,set.time_range,set);
          if (!tsplit.valid()) tsplit.data = Split::SPLIT_FALLBACK; // use fallback split
          return tsplit;
        }

        __forceinline std::unique_ptr<mvector<PrimRefMB>> split(const Split& tsplit, const SetMB& set, SetMB& lset, SetMB& rset)
        {
          assert(tsplit.sah != float(inf));
          assert(tsplit.fpos > set.time_range.lower);
          assert(tsplit.fpos < set.time_range.upper);

          float center_time = tsplit.fpos;
          const BBox1f time_range0(set.time_range.lower,center_time);
          const BBox1f time_range1(center_time,set.time_range.upper);
          mvector<PrimRefMB>& prims = *set.prims;
          
          /* calculate primrefs for first time range */
          std::unique_ptr<mvector<PrimRefMB>> new_vector(new mvector<PrimRefMB>(device, set.size()));
          PrimRefVector lprims = new_vector.get();
          
          auto reduction_func0 = [&] (const range<size_t>& r) {
            PrimInfoMB pinfo = empty;
            for (size_t i=r.begin(); i<r.end(); i++) 
            {
              if (likely(prims[i].time_range_overlap(time_range0)))
              {
                const PrimRefMB& prim = recalculatePrimRef(prims[i],time_range0);
                (*lprims)[i-set.begin()] = prim;
                pinfo.add_primref(prim);
              }
              else
              {
                (*lprims)[i-set.begin()] = prims[i];
              }
            }
            return pinfo;
          };        
          PrimInfoMB linfo = parallel_reduce(set.object_range,PARALLEL_PARTITION_BLOCK_SIZE,PARALLEL_THRESHOLD,PrimInfoMB(empty),reduction_func0,PrimInfoMB::merge2);

          /* primrefs for first time range are in lprims[0 .. set.size()) */
          /* some primitives may need to be filtered out */
          if (linfo.size() != set.size())
            linfo.object_range._end = parallel_filter(lprims->data(), size_t(0), set.size(), size_t(1024),
                                                      [&](const PrimRefMB& prim) { return prim.time_range_overlap(time_range0); });
                      
          lset = SetMB(linfo,lprims,time_range0);

          /* calculate primrefs for second time range */
          auto reduction_func1 = [&] (const range<size_t>& r) {
            PrimInfoMB pinfo = empty;
            for (size_t i=r.begin(); i<r.end(); i++) 
            {
              if (likely(prims[i].time_range_overlap(time_range1)))
              {
                const PrimRefMB& prim = recalculatePrimRef(prims[i],time_range1);
                prims[i] = prim;
                pinfo.add_primref(prim);
              }
            }
            return pinfo;
          };        
          PrimInfoMB rinfo = parallel_reduce(set.object_range,PARALLEL_PARTITION_BLOCK_SIZE,PARALLEL_THRESHOLD,PrimInfoMB(empty),reduction_func1,PrimInfoMB::merge2);
          rinfo.object_range = range<size_t>(set.begin(), set.begin() + rinfo.size());

          /* primrefs for second time range are in prims[set.begin() .. set.end()) */
          /* some primitives may need to be filtered out */
          if (rinfo.size() != set.size())
            rinfo.object_range._end = parallel_filter(prims.data(), set.begin(), set.end(), size_t(1024),
                                                      [&](const PrimRefMB& prim) { return prim.time_range_overlap(time_range1); });
        
          rset = SetMB(rinfo,&prims,time_range1);

          return new_vector;
        }

      private:
        MemoryMonitorInterface* device;              // device to report memory usage to
        const RecalculatePrimRef recalculatePrimRef;
      };
  }
}