virtualx-engine/thirdparty/embree/kernels/common/scene_quad_mesh.h

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// Copyright 2009-2021 Intel Corporation
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// SPDX-License-Identifier: Apache-2.0
#pragma once
#include "geometry.h"
#include "buffer.h"
namespace embree
{
/*! Quad Mesh */
struct QuadMesh : public Geometry
{
/*! type of this geometry */
static const Geometry::GTypeMask geom_type = Geometry::MTY_QUAD_MESH;
/*! triangle indices */
struct Quad
{
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Quad() {}
Quad (uint32_t v0, uint32_t v1, uint32_t v2, uint32_t v3) {
v[0] = v0; v[1] = v1; v[2] = v2; v[3] = v3;
}
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/*! outputs triangle indices */
__forceinline friend embree_ostream operator<<(embree_ostream cout, const Quad& q) {
return cout << "Quad {" << q.v[0] << ", " << q.v[1] << ", " << q.v[2] << ", " << q.v[3] << " }";
}
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uint32_t v[4];
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};
public:
/*! quad mesh construction */
QuadMesh (Device* device);
/* geometry interface */
public:
void setMask(unsigned mask);
void setNumTimeSteps (unsigned int numTimeSteps);
void setVertexAttributeCount (unsigned int N);
void setBuffer(RTCBufferType type, unsigned int slot, RTCFormat format, const Ref<Buffer>& buffer, size_t offset, size_t stride, unsigned int num);
void* getBuffer(RTCBufferType type, unsigned int slot);
void updateBuffer(RTCBufferType type, unsigned int slot);
void commit();
bool verify();
void interpolate(const RTCInterpolateArguments* const args);
void addElementsToCount (GeometryCounts & counts) const;
template<int N>
void interpolate_impl(const RTCInterpolateArguments* const args)
{
unsigned int primID = args->primID;
float u = args->u;
float v = args->v;
RTCBufferType bufferType = args->bufferType;
unsigned int bufferSlot = args->bufferSlot;
float* P = args->P;
float* dPdu = args->dPdu;
float* dPdv = args->dPdv;
float* ddPdudu = args->ddPdudu;
float* ddPdvdv = args->ddPdvdv;
float* ddPdudv = args->ddPdudv;
unsigned int valueCount = args->valueCount;
/* calculate base pointer and stride */
assert((bufferType == RTC_BUFFER_TYPE_VERTEX && bufferSlot < numTimeSteps) ||
(bufferType == RTC_BUFFER_TYPE_VERTEX_ATTRIBUTE && bufferSlot <= vertexAttribs.size()));
const char* src = nullptr;
size_t stride = 0;
if (bufferType == RTC_BUFFER_TYPE_VERTEX_ATTRIBUTE) {
src = vertexAttribs[bufferSlot].getPtr();
stride = vertexAttribs[bufferSlot].getStride();
} else {
src = vertices[bufferSlot].getPtr();
stride = vertices[bufferSlot].getStride();
}
for (unsigned int i=0; i<valueCount; i+=N)
{
const vbool<N> valid = vint<N>((int)i)+vint<N>(step) < vint<N>(int(valueCount));
const size_t ofs = i*sizeof(float);
const Quad& tri = quad(primID);
const vfloat<N> p0 = mem<vfloat<N>>::loadu(valid,(float*)&src[tri.v[0]*stride+ofs]);
const vfloat<N> p1 = mem<vfloat<N>>::loadu(valid,(float*)&src[tri.v[1]*stride+ofs]);
const vfloat<N> p2 = mem<vfloat<N>>::loadu(valid,(float*)&src[tri.v[2]*stride+ofs]);
const vfloat<N> p3 = mem<vfloat<N>>::loadu(valid,(float*)&src[tri.v[3]*stride+ofs]);
const vbool<N> left = u+v <= 1.0f;
const vfloat<N> Q0 = select(left,p0,p2);
const vfloat<N> Q1 = select(left,p1,p3);
const vfloat<N> Q2 = select(left,p3,p1);
const vfloat<N> U = select(left,u,vfloat<N>(1.0f)-u);
const vfloat<N> V = select(left,v,vfloat<N>(1.0f)-v);
const vfloat<N> W = 1.0f-U-V;
if (P) {
mem<vfloat<N>>::storeu(valid,P+i,madd(W,Q0,madd(U,Q1,V*Q2)));
}
if (dPdu) {
assert(dPdu); mem<vfloat<N>>::storeu(valid,dPdu+i,select(left,Q1-Q0,Q0-Q1));
assert(dPdv); mem<vfloat<N>>::storeu(valid,dPdv+i,select(left,Q2-Q0,Q0-Q2));
}
if (ddPdudu) {
assert(ddPdudu); mem<vfloat<N>>::storeu(valid,ddPdudu+i,vfloat<N>(zero));
assert(ddPdvdv); mem<vfloat<N>>::storeu(valid,ddPdvdv+i,vfloat<N>(zero));
assert(ddPdudv); mem<vfloat<N>>::storeu(valid,ddPdudv+i,vfloat<N>(zero));
}
}
}
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public:
/*! returns number of vertices */
__forceinline size_t numVertices() const {
return vertices[0].size();
}
/*! returns i'th quad */
__forceinline const Quad& quad(size_t i) const {
return quads[i];
}
/*! returns i'th vertex of itime'th timestep */
__forceinline const Vec3fa vertex(size_t i) const {
return vertices0[i];
}
/*! returns i'th vertex of itime'th timestep */
__forceinline const char* vertexPtr(size_t i) const {
return vertices0.getPtr(i);
}
/*! returns i'th vertex of itime'th timestep */
__forceinline const Vec3fa vertex(size_t i, size_t itime) const {
return vertices[itime][i];
}
/*! returns i'th vertex of itime'th timestep */
__forceinline const char* vertexPtr(size_t i, size_t itime) const {
return vertices[itime].getPtr(i);
}
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/*! returns i'th vertex of for specified time */
__forceinline Vec3fa vertex(size_t i, float time) const
{
float ftime;
const size_t itime = timeSegment(time, ftime);
const float t0 = 1.0f - ftime;
const float t1 = ftime;
Vec3fa v0 = vertex(i, itime+0);
Vec3fa v1 = vertex(i, itime+1);
return madd(Vec3fa(t0),v0,t1*v1);
}
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/*! calculates the bounds of the i'th quad */
__forceinline BBox3fa bounds(size_t i) const
{
const Quad& q = quad(i);
const Vec3fa v0 = vertex(q.v[0]);
const Vec3fa v1 = vertex(q.v[1]);
const Vec3fa v2 = vertex(q.v[2]);
const Vec3fa v3 = vertex(q.v[3]);
return BBox3fa(min(v0,v1,v2,v3),max(v0,v1,v2,v3));
}
/*! calculates the bounds of the i'th quad at the itime'th timestep */
__forceinline BBox3fa bounds(size_t i, size_t itime) const
{
const Quad& q = quad(i);
const Vec3fa v0 = vertex(q.v[0],itime);
const Vec3fa v1 = vertex(q.v[1],itime);
const Vec3fa v2 = vertex(q.v[2],itime);
const Vec3fa v3 = vertex(q.v[3],itime);
return BBox3fa(min(v0,v1,v2,v3),max(v0,v1,v2,v3));
}
/*! check if the i'th primitive is valid at the itime'th timestep */
__forceinline bool valid(size_t i, size_t itime) const {
return valid(i, make_range(itime, itime));
}
/*! check if the i'th primitive is valid between the specified time range */
__forceinline bool valid(size_t i, const range<size_t>& itime_range) const
{
const Quad& q = quad(i);
if (unlikely(q.v[0] >= numVertices())) return false;
if (unlikely(q.v[1] >= numVertices())) return false;
if (unlikely(q.v[2] >= numVertices())) return false;
if (unlikely(q.v[3] >= numVertices())) return false;
for (size_t itime = itime_range.begin(); itime <= itime_range.end(); itime++)
{
if (!isvalid(vertex(q.v[0],itime))) return false;
if (!isvalid(vertex(q.v[1],itime))) return false;
if (!isvalid(vertex(q.v[2],itime))) return false;
if (!isvalid(vertex(q.v[3],itime))) return false;
}
return true;
}
/*! calculates the linear bounds of the i'th quad at the itimeGlobal'th time segment */
__forceinline LBBox3fa linearBounds(size_t i, size_t itime) const {
return LBBox3fa(bounds(i,itime+0),bounds(i,itime+1));
}
/*! calculates the build bounds of the i'th primitive, if it's valid */
__forceinline bool buildBounds(size_t i, BBox3fa* bbox = nullptr) const
{
const Quad& q = quad(i);
if (q.v[0] >= numVertices()) return false;
if (q.v[1] >= numVertices()) return false;
if (q.v[2] >= numVertices()) return false;
if (q.v[3] >= numVertices()) return false;
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for (size_t t=0; t<numTimeSteps; t++)
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{
const Vec3fa v0 = vertex(q.v[0],t);
const Vec3fa v1 = vertex(q.v[1],t);
const Vec3fa v2 = vertex(q.v[2],t);
const Vec3fa v3 = vertex(q.v[3],t);
if (unlikely(!isvalid(v0) || !isvalid(v1) || !isvalid(v2) || !isvalid(v3)))
return false;
}
if (bbox)
*bbox = bounds(i);
return true;
}
/*! calculates the build bounds of the i'th primitive at the itime'th time segment, if it's valid */
__forceinline bool buildBounds(size_t i, size_t itime, BBox3fa& bbox) const
{
const Quad& q = quad(i);
if (unlikely(q.v[0] >= numVertices())) return false;
if (unlikely(q.v[1] >= numVertices())) return false;
if (unlikely(q.v[2] >= numVertices())) return false;
if (unlikely(q.v[3] >= numVertices())) return false;
assert(itime+1 < numTimeSteps);
const Vec3fa a0 = vertex(q.v[0],itime+0); if (unlikely(!isvalid(a0))) return false;
const Vec3fa a1 = vertex(q.v[1],itime+0); if (unlikely(!isvalid(a1))) return false;
const Vec3fa a2 = vertex(q.v[2],itime+0); if (unlikely(!isvalid(a2))) return false;
const Vec3fa a3 = vertex(q.v[3],itime+0); if (unlikely(!isvalid(a3))) return false;
const Vec3fa b0 = vertex(q.v[0],itime+1); if (unlikely(!isvalid(b0))) return false;
const Vec3fa b1 = vertex(q.v[1],itime+1); if (unlikely(!isvalid(b1))) return false;
const Vec3fa b2 = vertex(q.v[2],itime+1); if (unlikely(!isvalid(b2))) return false;
const Vec3fa b3 = vertex(q.v[3],itime+1); if (unlikely(!isvalid(b3))) return false;
/* use bounds of first time step in builder */
bbox = BBox3fa(min(a0,a1,a2,a3),max(a0,a1,a2,a3));
return true;
}
/*! calculates the linear bounds of the i'th primitive for the specified time range */
__forceinline LBBox3fa linearBounds(size_t primID, const BBox1f& dt) const {
return LBBox3fa([&] (size_t itime) { return bounds(primID, itime); }, dt, time_range, fnumTimeSegments);
}
/*! calculates the linear bounds of the i'th primitive for the specified time range */
__forceinline bool linearBounds(size_t i, const BBox1f& dt, LBBox3fa& bbox) const
{
if (!valid(i, timeSegmentRange(dt))) return false;
bbox = linearBounds(i, dt);
return true;
}
/*! get fast access to first vertex buffer */
__forceinline float * getCompactVertexArray () const {
return (float*) vertices0.getPtr();
}
/* gets version info of topology */
unsigned int getTopologyVersion() const {
return quads.modCounter;
}
/* returns true if topology changed */
bool topologyChanged(unsigned int otherVersion) const {
return quads.isModified(otherVersion); // || numPrimitivesChanged;
}
/* returns the projected area */
__forceinline float projectedPrimitiveArea(const size_t i) const {
const Quad& q = quad(i);
const Vec3fa v0 = vertex(q.v[0]);
const Vec3fa v1 = vertex(q.v[1]);
const Vec3fa v2 = vertex(q.v[2]);
const Vec3fa v3 = vertex(q.v[3]);
return areaProjectedTriangle(v0,v1,v3) +
areaProjectedTriangle(v1,v2,v3);
}
public:
BufferView<Quad> quads; //!< array of quads
BufferView<Vec3fa> vertices0; //!< fast access to first vertex buffer
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Device::vector<BufferView<Vec3fa>> vertices = device; //!< vertex array for each timestep
Device::vector<RawBufferView> vertexAttribs = device; //!< vertex attribute buffers
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};
namespace isa
{
struct QuadMeshISA : public QuadMesh
{
QuadMeshISA (Device* device)
: QuadMesh(device) {}
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LBBox3fa vlinearBounds(size_t primID, const BBox1f& time_range) const {
return linearBounds(primID,time_range);
}
PrimInfo createPrimRefArray(PrimRef* prims, const range<size_t>& r, size_t k, unsigned int geomID) const
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{
PrimInfo pinfo(empty);
for (size_t j=r.begin(); j<r.end(); j++)
{
BBox3fa bounds = empty;
if (!buildBounds(j,&bounds)) continue;
const PrimRef prim(bounds,geomID,unsigned(j));
pinfo.add_center2(prim);
prims[k++] = prim;
}
return pinfo;
}
PrimInfo createPrimRefArrayMB(mvector<PrimRef>& prims, size_t itime, const range<size_t>& r, size_t k, unsigned int geomID) const
{
PrimInfo pinfo(empty);
for (size_t j=r.begin(); j<r.end(); j++)
{
BBox3fa bounds = empty;
if (!buildBounds(j,itime,bounds)) continue;
const PrimRef prim(bounds,geomID,unsigned(j));
pinfo.add_center2(prim);
prims[k++] = prim;
}
return pinfo;
}
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PrimInfo createPrimRefArrayMB(PrimRef* prims, const BBox1f& time_range, const range<size_t>& r, size_t k, unsigned int geomID) const
{
PrimInfo pinfo(empty);
const BBox1f t0t1 = BBox1f::intersect(getTimeRange(), time_range);
if (t0t1.empty()) return pinfo;
for (size_t j = r.begin(); j < r.end(); j++) {
LBBox3fa lbounds = empty;
if (!linearBounds(j, t0t1, lbounds))
continue;
const PrimRef prim(lbounds.bounds(), geomID, unsigned(j));
pinfo.add_center2(prim);
prims[k++] = prim;
}
return pinfo;
}
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PrimInfoMB createPrimRefMBArray(mvector<PrimRefMB>& prims, const BBox1f& t0t1, const range<size_t>& r, size_t k, unsigned int geomID) const
{
PrimInfoMB pinfo(empty);
for (size_t j=r.begin(); j<r.end(); j++)
{
if (!valid(j, timeSegmentRange(t0t1))) continue;
const PrimRefMB prim(linearBounds(j,t0t1),this->numTimeSegments(),this->time_range,this->numTimeSegments(),geomID,unsigned(j));
pinfo.add_primref(prim);
prims[k++] = prim;
}
return pinfo;
}
};
}
DECLARE_ISA_FUNCTION(QuadMesh*, createQuadMesh, Device*);
}