godot/thirdparty/embree/kernels/builders/priminfo.h

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// Copyright 2009-2021 Intel Corporation
2021-04-20 16:38:09 +00:00
// SPDX-License-Identifier: Apache-2.0
#pragma once
#include "../common/default.h"
#include "../common/primref.h"
#include "../common/primref_mb.h"
namespace embree
{
// FIXME: maybe there's a better place for this util fct
__forceinline float areaProjectedTriangle(const Vec3fa& v0, const Vec3fa& v1, const Vec3fa& v2)
{
const Vec3fa e0 = v1-v0;
const Vec3fa e1 = v2-v0;
const Vec3fa d = cross(e0,e1);
return fabs(d.x) + fabs(d.y) + fabs(d.z);
}
//namespace isa
//{
template<typename BBox>
class CentGeom
{
public:
__forceinline CentGeom () {}
__forceinline CentGeom (EmptyTy)
: geomBounds(empty), centBounds(empty) {}
__forceinline CentGeom (const BBox& geomBounds, const BBox3fa& centBounds)
: geomBounds(geomBounds), centBounds(centBounds) {}
template<typename PrimRef>
__forceinline void extend_primref(const PrimRef& prim)
{
BBox bounds; Vec3fa center;
prim.binBoundsAndCenter(bounds,center);
geomBounds.extend(bounds);
centBounds.extend(center);
}
template<typename PrimRef>
__forceinline void extend_center2(const PrimRef& prim)
{
BBox3fa bounds = prim.bounds();
geomBounds.extend(bounds);
centBounds.extend(bounds.center2());
}
__forceinline void extend(const BBox& geomBounds_) {
geomBounds.extend(geomBounds_);
centBounds.extend(center2(geomBounds_));
}
__forceinline void merge(const CentGeom& other)
{
geomBounds.extend(other.geomBounds);
centBounds.extend(other.centBounds);
}
static __forceinline const CentGeom merge2(const CentGeom& a, const CentGeom& b) {
CentGeom r = a; r.merge(b); return r;
}
public:
BBox geomBounds; //!< geometry bounds of primitives
BBox3fa centBounds; //!< centroid bounds of primitives
};
typedef CentGeom<BBox3fa> CentGeomBBox3fa;
/*! stores bounding information for a set of primitives */
template<typename BBox>
class PrimInfoT : public CentGeom<BBox>
{
public:
using CentGeom<BBox>::geomBounds;
using CentGeom<BBox>::centBounds;
__forceinline PrimInfoT () {}
__forceinline PrimInfoT (EmptyTy)
: CentGeom<BBox>(empty), begin(0), end(0) {}
__forceinline PrimInfoT (size_t begin, size_t end, const CentGeomBBox3fa& centGeomBounds)
: CentGeom<BBox>(centGeomBounds), begin(begin), end(end) {}
template<typename PrimRef>
__forceinline void add_primref(const PrimRef& prim)
{
CentGeom<BBox>::extend_primref(prim);
end++;
}
template<typename PrimRef>
__forceinline void add_center2(const PrimRef& prim) {
CentGeom<BBox>::extend_center2(prim);
end++;
}
template<typename PrimRef>
__forceinline void add_center2(const PrimRef& prim, const size_t i) {
CentGeom<BBox>::extend_center2(prim);
end+=i;
}
/*__forceinline void add(const BBox& geomBounds_) {
CentGeom<BBox>::extend(geomBounds_);
end++;
}
__forceinline void add(const BBox& geomBounds_, const size_t i) {
CentGeom<BBox>::extend(geomBounds_);
end+=i;
}*/
__forceinline void merge(const PrimInfoT& other)
{
CentGeom<BBox>::merge(other);
begin += other.begin;
end += other.end;
}
static __forceinline const PrimInfoT merge(const PrimInfoT& a, const PrimInfoT& b) {
PrimInfoT r = a; r.merge(b); return r;
}
/*! returns the number of primitives */
__forceinline size_t size() const {
return end-begin;
}
__forceinline float halfArea() {
return expectedApproxHalfArea(geomBounds);
}
__forceinline float leafSAH() const {
return expectedApproxHalfArea(geomBounds)*float(size());
//return halfArea(geomBounds)*blocks(num);
}
__forceinline float leafSAH(size_t block_shift) const {
return expectedApproxHalfArea(geomBounds)*float((size()+(size_t(1)<<block_shift)-1) >> block_shift);
//return halfArea(geomBounds)*float((num+3) >> 2);
//return halfArea(geomBounds)*blocks(num);
}
/*! stream output */
friend embree_ostream operator<<(embree_ostream cout, const PrimInfoT& pinfo) {
return cout << "PrimInfo { begin = " << pinfo.begin << ", end = " << pinfo.end << ", geomBounds = " << pinfo.geomBounds << ", centBounds = " << pinfo.centBounds << "}";
}
public:
size_t begin,end; //!< number of primitives
};
typedef PrimInfoT<BBox3fa> PrimInfo;
//typedef PrimInfoT<LBBox3fa> PrimInfoMB;
/*! stores bounding information for a set of primitives */
template<typename BBox>
class PrimInfoMBT : public CentGeom<BBox>
{
public:
using CentGeom<BBox>::geomBounds;
using CentGeom<BBox>::centBounds;
__forceinline PrimInfoMBT () {
}
__forceinline PrimInfoMBT (EmptyTy)
: CentGeom<BBox>(empty), object_range(0,0), num_time_segments(0), max_num_time_segments(0), max_time_range(0.0f,1.0f), time_range(1.0f,0.0f) {}
__forceinline PrimInfoMBT (size_t begin, size_t end)
: CentGeom<BBox>(empty), object_range(begin,end), num_time_segments(0), max_num_time_segments(0), max_time_range(0.0f,1.0f), time_range(1.0f,0.0f) {}
template<typename PrimRef>
__forceinline void add_primref(const PrimRef& prim)
{
CentGeom<BBox>::extend_primref(prim);
time_range.extend(prim.time_range);
object_range._end++;
num_time_segments += prim.size();
if (max_num_time_segments < prim.totalTimeSegments()) {
max_num_time_segments = prim.totalTimeSegments();
max_time_range = prim.time_range;
}
}
__forceinline void merge(const PrimInfoMBT& other)
{
CentGeom<BBox>::merge(other);
time_range.extend(other.time_range);
object_range._begin += other.object_range.begin();
object_range._end += other.object_range.end();
num_time_segments += other.num_time_segments;
if (max_num_time_segments < other.max_num_time_segments) {
max_num_time_segments = other.max_num_time_segments;
max_time_range = other.max_time_range;
}
}
static __forceinline const PrimInfoMBT merge2(const PrimInfoMBT& a, const PrimInfoMBT& b) {
PrimInfoMBT r = a; r.merge(b); return r;
}
__forceinline size_t begin() const {
return object_range.begin();
}
__forceinline size_t end() const {
return object_range.end();
}
/*! returns the number of primitives */
__forceinline size_t size() const {
return object_range.size();
}
__forceinline float halfArea() const {
return time_range.size()*expectedApproxHalfArea(geomBounds);
}
__forceinline float leafSAH() const {
return time_range.size()*expectedApproxHalfArea(geomBounds)*float(num_time_segments);
}
__forceinline float leafSAH(size_t block_shift) const {
return time_range.size()*expectedApproxHalfArea(geomBounds)*float((num_time_segments+(size_t(1)<<block_shift)-1) >> block_shift);
}
__forceinline float align_time(float ct) const
{
//return roundf(ct * float(numTimeSegments)) / float(numTimeSegments);
float t0 = (ct-max_time_range.lower)/max_time_range.size();
float t1 = roundf(t0 * float(max_num_time_segments)) / float(max_num_time_segments);
return t1*max_time_range.size()+max_time_range.lower;
}
/*! stream output */
friend embree_ostream operator<<(embree_ostream cout, const PrimInfoMBT& pinfo)
{
return cout << "PrimInfo { " <<
"object_range = " << pinfo.object_range <<
", time_range = " << pinfo.time_range <<
", time_segments = " << pinfo.num_time_segments <<
", geomBounds = " << pinfo.geomBounds <<
", centBounds = " << pinfo.centBounds <<
"}";
}
public:
range<size_t> object_range; //!< primitive range
size_t num_time_segments; //!< total number of time segments of all added primrefs
size_t max_num_time_segments; //!< maximum number of time segments of a primitive
BBox1f max_time_range; //!< time range of primitive with max_num_time_segments
BBox1f time_range; //!< merged time range of primitives when merging prims, or additionally clipped with build time range when used in SetMB
};
typedef PrimInfoMBT<typename PrimRefMB::BBox> PrimInfoMB;
struct SetMB : public PrimInfoMB
{
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;
typedef mvector<PrimRefMB>* PrimRefVector;
__forceinline SetMB() {}
__forceinline SetMB(const PrimInfoMB& pinfo_i, PrimRefVector prims)
: PrimInfoMB(pinfo_i), prims(prims) {}
__forceinline SetMB(const PrimInfoMB& pinfo_i, PrimRefVector prims, range<size_t> object_range_in, BBox1f time_range_in)
: PrimInfoMB(pinfo_i), prims(prims)
{
object_range = object_range_in;
time_range = intersect(time_range,time_range_in);
}
__forceinline SetMB(const PrimInfoMB& pinfo_i, PrimRefVector prims, BBox1f time_range_in)
: PrimInfoMB(pinfo_i), prims(prims)
{
time_range = intersect(time_range,time_range_in);
}
void deterministic_order() const
{
/* required as parallel partition destroys original primitive order */
PrimRefMB* prim = prims->data();
std::sort(&prim[object_range.begin()],&prim[object_range.end()]);
}
template<typename RecalculatePrimRef>
__forceinline LBBox3fa linearBounds(const RecalculatePrimRef& recalculatePrimRef) const
{
auto reduce = [&](const range<size_t>& r) -> LBBox3fa
{
LBBox3fa cbounds(empty);
for (size_t j = r.begin(); j < r.end(); j++)
{
PrimRefMB& ref = (*prims)[j];
const LBBox3fa bn = recalculatePrimRef.linearBounds(ref, time_range);
cbounds.extend(bn);
};
return cbounds;
};
return parallel_reduce(object_range.begin(), object_range.end(), PARALLEL_FIND_BLOCK_SIZE, PARALLEL_THRESHOLD, LBBox3fa(empty),
reduce,
[&](const LBBox3fa& b0, const LBBox3fa& b1) -> LBBox3fa { return embree::merge(b0, b1); });
}
template<typename RecalculatePrimRef>
__forceinline LBBox3fa linearBounds(const RecalculatePrimRef& recalculatePrimRef, const LinearSpace3fa& space) const
{
auto reduce = [&](const range<size_t>& r) -> LBBox3fa
{
LBBox3fa cbounds(empty);
for (size_t j = r.begin(); j < r.end(); j++)
{
PrimRefMB& ref = (*prims)[j];
const LBBox3fa bn = recalculatePrimRef.linearBounds(ref, time_range, space);
cbounds.extend(bn);
};
return cbounds;
};
return parallel_reduce(object_range.begin(), object_range.end(), PARALLEL_FIND_BLOCK_SIZE, PARALLEL_THRESHOLD, LBBox3fa(empty),
reduce,
[&](const LBBox3fa& b0, const LBBox3fa& b1) -> LBBox3fa { return embree::merge(b0, b1); });
}
template<typename RecalculatePrimRef>
const SetMB primInfo(const RecalculatePrimRef& recalculatePrimRef, const LinearSpace3fa& space) const
{
auto computePrimInfo = [&](const range<size_t>& r) -> PrimInfoMB
{
PrimInfoMB pinfo(empty);
for (size_t j=r.begin(); j<r.end(); j++)
{
PrimRefMB& ref = (*prims)[j];
PrimRefMB ref1 = recalculatePrimRef(ref,time_range,space);
pinfo.add_primref(ref1);
};
return pinfo;
};
const PrimInfoMB pinfo = parallel_reduce(object_range.begin(), object_range.end(), PARALLEL_FIND_BLOCK_SIZE, PARALLEL_THRESHOLD,
PrimInfoMB(empty), computePrimInfo, PrimInfoMB::merge2);
return SetMB(pinfo,prims,object_range,time_range);
}
public:
PrimRefVector prims;
};
//}
}