virtualx-engine/thirdparty/embree/kernels/common/rtcore_builder.cpp
jfons a69cc9f13d
Upgrade Embree to the latest official release.
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.

(cherry picked from commit 767e374dce)
2021-05-22 15:14:07 +02:00

442 lines
17 KiB
C++

// Copyright 2009-2021 Intel Corporation
// SPDX-License-Identifier: Apache-2.0
#define RTC_EXPORT_API
#include "default.h"
#include "device.h"
#include "scene.h"
#include "context.h"
#include "alloc.h"
#include "../builders/bvh_builder_sah.h"
#include "../builders/bvh_builder_morton.h"
namespace embree
{
namespace isa // FIXME: support more ISAs for builders
{
struct BVH : public RefCount
{
BVH (Device* device)
: device(device), allocator(device,true), morton_src(device,0), morton_tmp(device,0)
{
device->refInc();
}
~BVH() {
device->refDec();
}
public:
Device* device;
FastAllocator allocator;
mvector<BVHBuilderMorton::BuildPrim> morton_src;
mvector<BVHBuilderMorton::BuildPrim> morton_tmp;
};
void* rtcBuildBVHMorton(const RTCBuildArguments* arguments)
{
BVH* bvh = (BVH*) arguments->bvh;
RTCBuildPrimitive* prims_i = arguments->primitives;
size_t primitiveCount = arguments->primitiveCount;
RTCCreateNodeFunction createNode = arguments->createNode;
RTCSetNodeChildrenFunction setNodeChildren = arguments->setNodeChildren;
RTCSetNodeBoundsFunction setNodeBounds = arguments->setNodeBounds;
RTCCreateLeafFunction createLeaf = arguments->createLeaf;
RTCProgressMonitorFunction buildProgress = arguments->buildProgress;
void* userPtr = arguments->userPtr;
std::atomic<size_t> progress(0);
/* initialize temporary arrays for morton builder */
PrimRef* prims = (PrimRef*) prims_i;
mvector<BVHBuilderMorton::BuildPrim>& morton_src = bvh->morton_src;
mvector<BVHBuilderMorton::BuildPrim>& morton_tmp = bvh->morton_tmp;
morton_src.resize(primitiveCount);
morton_tmp.resize(primitiveCount);
/* compute centroid bounds */
const BBox3fa centBounds = parallel_reduce ( size_t(0), primitiveCount, BBox3fa(empty), [&](const range<size_t>& r) -> BBox3fa {
BBox3fa bounds(empty);
for (size_t i=r.begin(); i<r.end(); i++)
bounds.extend(prims[i].bounds().center2());
return bounds;
}, BBox3fa::merge);
/* compute morton codes */
BVHBuilderMorton::MortonCodeMapping mapping(centBounds);
parallel_for ( size_t(0), primitiveCount, [&](const range<size_t>& r) {
BVHBuilderMorton::MortonCodeGenerator generator(mapping,&morton_src[r.begin()]);
for (size_t i=r.begin(); i<r.end(); i++) {
generator(prims[i].bounds(),(unsigned) i);
}
});
/* start morton build */
std::pair<void*,BBox3fa> root = BVHBuilderMorton::build<std::pair<void*,BBox3fa>>(
/* thread local allocator for fast allocations */
[&] () -> FastAllocator::CachedAllocator {
return bvh->allocator.getCachedAllocator();
},
/* lambda function that allocates BVH nodes */
[&] ( const FastAllocator::CachedAllocator& alloc, size_t N ) -> void* {
return createNode((RTCThreadLocalAllocator)&alloc, (unsigned int)N,userPtr);
},
/* lambda function that sets bounds */
[&] (void* node, const std::pair<void*,BBox3fa>* children, size_t N) -> std::pair<void*,BBox3fa>
{
BBox3fa bounds = empty;
void* childptrs[BVHBuilderMorton::MAX_BRANCHING_FACTOR];
const RTCBounds* cbounds[BVHBuilderMorton::MAX_BRANCHING_FACTOR];
for (size_t i=0; i<N; i++) {
bounds.extend(children[i].second);
childptrs[i] = children[i].first;
cbounds[i] = (const RTCBounds*)&children[i].second;
}
setNodeBounds(node,cbounds,(unsigned int)N,userPtr);
setNodeChildren(node,childptrs, (unsigned int)N,userPtr);
return std::make_pair(node,bounds);
},
/* lambda function that creates BVH leaves */
[&]( const range<unsigned>& current, const FastAllocator::CachedAllocator& alloc) -> std::pair<void*,BBox3fa>
{
RTCBuildPrimitive localBuildPrims[RTC_BUILD_MAX_PRIMITIVES_PER_LEAF];
BBox3fa bounds = empty;
for (size_t i=0;i<current.size();i++)
{
const size_t id = morton_src[current.begin()+i].index;
bounds.extend(prims[id].bounds());
localBuildPrims[i] = prims_i[id];
}
void* node = createLeaf((RTCThreadLocalAllocator)&alloc,localBuildPrims,current.size(),userPtr);
return std::make_pair(node,bounds);
},
/* lambda that calculates the bounds for some primitive */
[&] (const BVHBuilderMorton::BuildPrim& morton) -> BBox3fa {
return prims[morton.index].bounds();
},
/* progress monitor function */
[&] (size_t dn) {
if (!buildProgress) return true;
const size_t n = progress.fetch_add(dn)+dn;
const double f = std::min(1.0,double(n)/double(primitiveCount));
return buildProgress(userPtr,f);
},
morton_src.data(),morton_tmp.data(),primitiveCount,
*arguments);
bvh->allocator.cleanup();
return root.first;
}
void* rtcBuildBVHBinnedSAH(const RTCBuildArguments* arguments)
{
BVH* bvh = (BVH*) arguments->bvh;
RTCBuildPrimitive* prims = arguments->primitives;
size_t primitiveCount = arguments->primitiveCount;
RTCCreateNodeFunction createNode = arguments->createNode;
RTCSetNodeChildrenFunction setNodeChildren = arguments->setNodeChildren;
RTCSetNodeBoundsFunction setNodeBounds = arguments->setNodeBounds;
RTCCreateLeafFunction createLeaf = arguments->createLeaf;
RTCProgressMonitorFunction buildProgress = arguments->buildProgress;
void* userPtr = arguments->userPtr;
std::atomic<size_t> progress(0);
/* calculate priminfo */
auto computeBounds = [&](const range<size_t>& r) -> CentGeomBBox3fa
{
CentGeomBBox3fa bounds(empty);
for (size_t j=r.begin(); j<r.end(); j++)
bounds.extend((BBox3fa&)prims[j]);
return bounds;
};
const CentGeomBBox3fa bounds =
parallel_reduce(size_t(0),primitiveCount,size_t(1024),size_t(1024),CentGeomBBox3fa(empty), computeBounds, CentGeomBBox3fa::merge2);
const PrimInfo pinfo(0,primitiveCount,bounds);
/* build BVH */
void* root = BVHBuilderBinnedSAH::build<void*>(
/* thread local allocator for fast allocations */
[&] () -> FastAllocator::CachedAllocator {
return bvh->allocator.getCachedAllocator();
},
/* lambda function that creates BVH nodes */
[&](BVHBuilderBinnedSAH::BuildRecord* children, const size_t N, const FastAllocator::CachedAllocator& alloc) -> void*
{
void* node = createNode((RTCThreadLocalAllocator)&alloc, (unsigned int)N,userPtr);
const RTCBounds* cbounds[GeneralBVHBuilder::MAX_BRANCHING_FACTOR];
for (size_t i=0; i<N; i++) cbounds[i] = (const RTCBounds*) &children[i].prims.geomBounds;
setNodeBounds(node,cbounds, (unsigned int)N,userPtr);
return node;
},
/* lambda function that updates BVH nodes */
[&](const BVHBuilderBinnedSAH::BuildRecord& precord, const BVHBuilderBinnedSAH::BuildRecord* crecords, void* node, void** children, const size_t N) -> void* {
setNodeChildren(node,children, (unsigned int)N,userPtr);
return node;
},
/* lambda function that creates BVH leaves */
[&](const PrimRef* prims, const range<size_t>& range, const FastAllocator::CachedAllocator& alloc) -> void* {
return createLeaf((RTCThreadLocalAllocator)&alloc,(RTCBuildPrimitive*)(prims+range.begin()),range.size(),userPtr);
},
/* progress monitor function */
[&] (size_t dn) {
if (!buildProgress) return true;
const size_t n = progress.fetch_add(dn)+dn;
const double f = std::min(1.0,double(n)/double(primitiveCount));
return buildProgress(userPtr,f);
},
(PrimRef*)prims,pinfo,*arguments);
bvh->allocator.cleanup();
return root;
}
static __forceinline const std::pair<CentGeomBBox3fa,unsigned int> mergePair(const std::pair<CentGeomBBox3fa,unsigned int>& a, const std::pair<CentGeomBBox3fa,unsigned int>& b) {
CentGeomBBox3fa centBounds = CentGeomBBox3fa::merge2(a.first,b.first);
unsigned int maxGeomID = max(a.second,b.second);
return std::pair<CentGeomBBox3fa,unsigned int>(centBounds,maxGeomID);
}
void* rtcBuildBVHSpatialSAH(const RTCBuildArguments* arguments)
{
BVH* bvh = (BVH*) arguments->bvh;
RTCBuildPrimitive* prims = arguments->primitives;
size_t primitiveCount = arguments->primitiveCount;
RTCCreateNodeFunction createNode = arguments->createNode;
RTCSetNodeChildrenFunction setNodeChildren = arguments->setNodeChildren;
RTCSetNodeBoundsFunction setNodeBounds = arguments->setNodeBounds;
RTCCreateLeafFunction createLeaf = arguments->createLeaf;
RTCSplitPrimitiveFunction splitPrimitive = arguments->splitPrimitive;
RTCProgressMonitorFunction buildProgress = arguments->buildProgress;
void* userPtr = arguments->userPtr;
std::atomic<size_t> progress(0);
/* calculate priminfo */
auto computeBounds = [&](const range<size_t>& r) -> std::pair<CentGeomBBox3fa,unsigned int>
{
CentGeomBBox3fa bounds(empty);
unsigned maxGeomID = 0;
for (size_t j=r.begin(); j<r.end(); j++)
{
bounds.extend((BBox3fa&)prims[j]);
maxGeomID = max(maxGeomID,prims[j].geomID);
}
return std::pair<CentGeomBBox3fa,unsigned int>(bounds,maxGeomID);
};
const std::pair<CentGeomBBox3fa,unsigned int> pair =
parallel_reduce(size_t(0),primitiveCount,size_t(1024),size_t(1024),std::pair<CentGeomBBox3fa,unsigned int>(CentGeomBBox3fa(empty),0), computeBounds, mergePair);
CentGeomBBox3fa bounds = pair.first;
const unsigned int maxGeomID = pair.second;
if (unlikely(maxGeomID >= ((unsigned int)1 << (32-RESERVED_NUM_SPATIAL_SPLITS_GEOMID_BITS))))
{
/* fallback code for max geomID larger than threshold */
return rtcBuildBVHBinnedSAH(arguments);
}
const PrimInfo pinfo(0,primitiveCount,bounds);
/* function that splits a build primitive */
struct Splitter
{
Splitter (RTCSplitPrimitiveFunction splitPrimitive, unsigned geomID, unsigned primID, void* userPtr)
: splitPrimitive(splitPrimitive), geomID(geomID), primID(primID), userPtr(userPtr) {}
__forceinline void operator() (PrimRef& prim, const size_t dim, const float pos, PrimRef& left_o, PrimRef& right_o) const
{
prim.geomIDref() &= BVHBuilderBinnedFastSpatialSAH::GEOMID_MASK;
splitPrimitive((RTCBuildPrimitive*)&prim,(unsigned)dim,pos,(RTCBounds*)&left_o,(RTCBounds*)&right_o,userPtr);
left_o.geomIDref() = geomID; left_o.primIDref() = primID;
right_o.geomIDref() = geomID; right_o.primIDref() = primID;
}
__forceinline void operator() (const BBox3fa& box, const size_t dim, const float pos, BBox3fa& left_o, BBox3fa& right_o) const
{
PrimRef prim(box,geomID & BVHBuilderBinnedFastSpatialSAH::GEOMID_MASK,primID);
splitPrimitive((RTCBuildPrimitive*)&prim,(unsigned)dim,pos,(RTCBounds*)&left_o,(RTCBounds*)&right_o,userPtr);
}
RTCSplitPrimitiveFunction splitPrimitive;
unsigned geomID;
unsigned primID;
void* userPtr;
};
/* build BVH */
void* root = BVHBuilderBinnedFastSpatialSAH::build<void*>(
/* thread local allocator for fast allocations */
[&] () -> FastAllocator::CachedAllocator {
return bvh->allocator.getCachedAllocator();
},
/* lambda function that creates BVH nodes */
[&] (BVHBuilderBinnedFastSpatialSAH::BuildRecord* children, const size_t N, const FastAllocator::CachedAllocator& alloc) -> void*
{
void* node = createNode((RTCThreadLocalAllocator)&alloc, (unsigned int)N,userPtr);
const RTCBounds* cbounds[GeneralBVHBuilder::MAX_BRANCHING_FACTOR];
for (size_t i=0; i<N; i++) cbounds[i] = (const RTCBounds*) &children[i].prims.geomBounds;
setNodeBounds(node,cbounds, (unsigned int)N,userPtr);
return node;
},
/* lambda function that updates BVH nodes */
[&] (const BVHBuilderBinnedFastSpatialSAH::BuildRecord& precord, const BVHBuilderBinnedFastSpatialSAH::BuildRecord* crecords, void* node, void** children, const size_t N) -> void* {
setNodeChildren(node,children, (unsigned int)N,userPtr);
return node;
},
/* lambda function that creates BVH leaves */
[&] (const PrimRef* prims, const range<size_t>& range, const FastAllocator::CachedAllocator& alloc) -> void* {
return createLeaf((RTCThreadLocalAllocator)&alloc,(RTCBuildPrimitive*)(prims+range.begin()),range.size(),userPtr);
},
/* returns the splitter */
[&] ( const PrimRef& prim ) -> Splitter {
return Splitter(splitPrimitive,prim.geomID(),prim.primID(),userPtr);
},
/* progress monitor function */
[&] (size_t dn) {
if (!buildProgress) return true;
const size_t n = progress.fetch_add(dn)+dn;
const double f = std::min(1.0,double(n)/double(primitiveCount));
return buildProgress(userPtr,f);
},
(PrimRef*)prims,
arguments->primitiveArrayCapacity,
pinfo,*arguments);
bvh->allocator.cleanup();
return root;
}
}
}
using namespace embree;
using namespace embree::isa;
RTC_NAMESPACE_BEGIN
RTC_API RTCBVH rtcNewBVH(RTCDevice device)
{
RTC_CATCH_BEGIN;
RTC_TRACE(rtcNewAllocator);
RTC_VERIFY_HANDLE(device);
BVH* bvh = new BVH((Device*)device);
return (RTCBVH) bvh->refInc();
RTC_CATCH_END((Device*)device);
return nullptr;
}
RTC_API void* rtcBuildBVH(const RTCBuildArguments* arguments)
{
BVH* bvh = (BVH*) arguments->bvh;
RTC_CATCH_BEGIN;
RTC_TRACE(rtcBuildBVH);
RTC_VERIFY_HANDLE(bvh);
RTC_VERIFY_HANDLE(arguments);
RTC_VERIFY_HANDLE(arguments->createNode);
RTC_VERIFY_HANDLE(arguments->setNodeChildren);
RTC_VERIFY_HANDLE(arguments->setNodeBounds);
RTC_VERIFY_HANDLE(arguments->createLeaf);
if (arguments->primitiveArrayCapacity < arguments->primitiveCount)
throw_RTCError(RTC_ERROR_INVALID_ARGUMENT,"primitiveArrayCapacity must be greater or equal to primitiveCount")
/* initialize the allocator */
bvh->allocator.init_estimate(arguments->primitiveCount*sizeof(BBox3fa));
bvh->allocator.reset();
/* switch between differnet builders based on quality level */
if (arguments->buildQuality == RTC_BUILD_QUALITY_LOW)
return rtcBuildBVHMorton(arguments);
else if (arguments->buildQuality == RTC_BUILD_QUALITY_MEDIUM)
return rtcBuildBVHBinnedSAH(arguments);
else if (arguments->buildQuality == RTC_BUILD_QUALITY_HIGH) {
if (arguments->splitPrimitive == nullptr || arguments->primitiveArrayCapacity <= arguments->primitiveCount)
return rtcBuildBVHBinnedSAH(arguments);
else
return rtcBuildBVHSpatialSAH(arguments);
}
else
throw_RTCError(RTC_ERROR_INVALID_OPERATION,"invalid build quality");
/* if we are in dynamic mode, then do not clear temporary data */
if (!(arguments->buildFlags & RTC_BUILD_FLAG_DYNAMIC))
{
bvh->morton_src.clear();
bvh->morton_tmp.clear();
}
RTC_CATCH_END(bvh->device);
return nullptr;
}
RTC_API void* rtcThreadLocalAlloc(RTCThreadLocalAllocator localAllocator, size_t bytes, size_t align)
{
FastAllocator::CachedAllocator* alloc = (FastAllocator::CachedAllocator*) localAllocator;
RTC_CATCH_BEGIN;
RTC_TRACE(rtcThreadLocalAlloc);
return alloc->malloc0(bytes,align);
RTC_CATCH_END(alloc->alloc->getDevice());
return nullptr;
}
RTC_API void rtcMakeStaticBVH(RTCBVH hbvh)
{
BVH* bvh = (BVH*) hbvh;
RTC_CATCH_BEGIN;
RTC_TRACE(rtcStaticBVH);
RTC_VERIFY_HANDLE(hbvh);
bvh->morton_src.clear();
bvh->morton_tmp.clear();
RTC_CATCH_END(bvh->device);
}
RTC_API void rtcRetainBVH(RTCBVH hbvh)
{
BVH* bvh = (BVH*) hbvh;
Device* device = bvh ? bvh->device : nullptr;
RTC_CATCH_BEGIN;
RTC_TRACE(rtcRetainBVH);
RTC_VERIFY_HANDLE(hbvh);
bvh->refInc();
RTC_CATCH_END(device);
}
RTC_API void rtcReleaseBVH(RTCBVH hbvh)
{
BVH* bvh = (BVH*) hbvh;
Device* device = bvh ? bvh->device : nullptr;
RTC_CATCH_BEGIN;
RTC_TRACE(rtcReleaseBVH);
RTC_VERIFY_HANDLE(hbvh);
bvh->refDec();
RTC_CATCH_END(device);
}
RTC_NAMESPACE_END