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OpenSubdiv/opensubdiv/far/catmarkSubdivisionTables.h
Takahito Tejima 8efecb0fca Batching stuffs: generalized kernel batches, table/dispatcher refactoring, multiMeshFactory, drawContext, etc. 
2 client APIs are changed.
- VertexBuffer::UpdateData() takes start vertex offset
- ComputeController::Refine() takes FarKernelBatchVector

Also, ComputeContext no longer holds farmesh.
Client can free farmesh after OsdComputeContext is created.
(but still need FarKernelBatchVector to apply subdivision kernels)
2013-03-07 17:50:15 -08:00

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//
// Copyright (C) Pixar. All rights reserved.
//
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#ifndef FAR_CATMARK_SUBDIVISION_TABLES_H
#define FAR_CATMARK_SUBDIVISION_TABLES_H
#include "../version.h"
#include "../far/subdivisionTables.h"
#include <cassert>
#include <vector>
namespace OpenSubdiv {
namespace OPENSUBDIV_VERSION {
/// \brief Catmark subdivision scheme tables.
///
/// Catmull-Clark tables store the indexing tables required in order to compute
/// the refined positions of a mesh without the help of a hierarchical data
/// structure. The advantage of this representation is its ability to be executed
/// in a massively parallel environment without data dependencies.
///
template <class U> class FarCatmarkSubdivisionTables : public FarSubdivisionTables<U> {
public:
/// Returns the number of indexing tables needed to represent this particular
/// subdivision scheme.
virtual int GetNumTables() const { return 7; }
private:
template <class X, class Y> friend class FarCatmarkSubdivisionTablesFactory;
template <class X, class Y> friend class FarMultiMeshFactory;
template <class CONTROLLER> friend class FarComputeController;
// Private constructor called by factory
FarCatmarkSubdivisionTables( FarMesh<U> * mesh, int maxlevel );
// Compute-kernel applied to vertices resulting from the refinement of a face.
void computeFacePoints(int offset, int level, int start, int end, void * clientdata) const;
// Compute-kernel applied to vertices resulting from the refinement of an edge.
void computeEdgePoints(int offset, int level, int start, int end, void * clientdata) const;
// Compute-kernel applied to vertices resulting from the refinement of a vertex
// Kernel "A" Handles the k_Smooth and k_Dart rules
void computeVertexPointsA(int offset, bool pass, int level, int start, int end, void * clientdata) const;
// Compute-kernel applied to vertices resulting from the refinement of a vertex
// Kernel "B" Handles the k_Crease and k_Corner rules
void computeVertexPointsB(int offset, int level, int start, int end, void * clientdata) const;
};
template <class U>
FarCatmarkSubdivisionTables<U>::FarCatmarkSubdivisionTables( FarMesh<U> * mesh, int maxlevel ) :
FarSubdivisionTables<U>(mesh, maxlevel)
{ }
//
// Face-vertices compute Kernel - completely re-entrant
//
template <class U> void
FarCatmarkSubdivisionTables<U>::computeFacePoints( int offset, int tableOffset, int start, int end, void * clientdata ) const {
assert(this->_mesh);
U * vsrc = &this->_mesh->GetVertices().at(0),
* vdst = vsrc + offset + start;
for (int i=start+tableOffset; i<end+tableOffset; ++i, ++vdst ) {
vdst->Clear(clientdata);
int h = this->_F_ITa[2*i ],
n = this->_F_ITa[2*i+1];
float weight = 1.0f/n;
for (int j=0; j<n; ++j) {
vdst->AddWithWeight( vsrc[ this->_F_IT[h+j] ], weight, clientdata );
vdst->AddVaryingWithWeight( vsrc[ this->_F_IT[h+j] ], weight, clientdata );
}
}
}
//
// Edge-vertices compute Kernel - completely re-entrant
//
template <class U> void
FarCatmarkSubdivisionTables<U>::computeEdgePoints( int offset, int tableOffset, int start, int end, void * clientdata ) const {
assert(this->_mesh);
U * vsrc = &this->_mesh->GetVertices().at(0),
* vdst = vsrc + offset + start;
for (int i=start+tableOffset; i<end+tableOffset; ++i, ++vdst ) {
vdst->Clear(clientdata);
int eidx0 = this->_E_IT[4*i+0],
eidx1 = this->_E_IT[4*i+1],
eidx2 = this->_E_IT[4*i+2],
eidx3 = this->_E_IT[4*i+3];
float vertWeight = this->_E_W[i*2+0];
// Fully sharp edge : vertWeight = 0.5f
vdst->AddWithWeight( vsrc[eidx0], vertWeight, clientdata );
vdst->AddWithWeight( vsrc[eidx1], vertWeight, clientdata );
if (eidx2!=-1) {
// Apply fractional sharpness
float faceWeight = this->_E_W[i*2+1];
vdst->AddWithWeight( vsrc[eidx2], faceWeight, clientdata );
vdst->AddWithWeight( vsrc[eidx3], faceWeight, clientdata );
}
vdst->AddVaryingWithWeight( vsrc[eidx0], 0.5f, clientdata );
vdst->AddVaryingWithWeight( vsrc[eidx1], 0.5f, clientdata );
}
}
//
// Vertex-vertices compute Kernels "A" and "B" - completely re-entrant
//
// multi-pass kernel handling k_Crease and k_Corner rules
template <class U> void
FarCatmarkSubdivisionTables<U>::computeVertexPointsA( int offset, bool pass, int tableOffset, int start, int end, void * clientdata ) const {
assert(this->_mesh);
U * vsrc = &this->_mesh->GetVertices().at(0),
* vdst = vsrc + offset + start;
for (int i=start+tableOffset; i<end+tableOffset; ++i, ++vdst ) {
if (not pass)
vdst->Clear(clientdata);
int n=this->_V_ITa[5*i+1], // number of vertices in the _VO_IT array (valence)
p=this->_V_ITa[5*i+2], // index of the parent vertex
eidx0=this->_V_ITa[5*i+3], // index of the first crease rule edge
eidx1=this->_V_ITa[5*i+4]; // index of the second crease rule edge
float weight = pass ? this->_V_W[i] : 1.0f - this->_V_W[i];
// In the case of fractional weight, the weight must be inverted since
// the value is shared with the k_Smooth kernel (statistically the
// k_Smooth kernel runs much more often than this one)
if (weight>0.0f and weight<1.0f and n>0)
weight=1.0f-weight;
// In the case of a k_Corner / k_Crease combination, the edge indices
// won't be null, so we use a -1 valence to detect that particular case
if (eidx0==-1 or (pass==false and (n==-1)) ) {
// k_Corner case
vdst->AddWithWeight( vsrc[p], weight, clientdata );
} else {
// k_Crease case
vdst->AddWithWeight( vsrc[p], weight * 0.75f, clientdata );
vdst->AddWithWeight( vsrc[eidx0], weight * 0.125f, clientdata );
vdst->AddWithWeight( vsrc[eidx1], weight * 0.125f, clientdata );
}
vdst->AddVaryingWithWeight( vsrc[p], 1.0f, clientdata );
}
}
// multi-pass kernel handling k_Dart and k_Smooth rules
template <class U> void
FarCatmarkSubdivisionTables<U>::computeVertexPointsB( int offset, int tableOffset, int start, int end, void * clientdata ) const {
assert(this->_mesh);
U * vsrc = &this->_mesh->GetVertices().at(0),
* vdst = vsrc + offset + start;
for (int i=start+tableOffset; i<end+tableOffset; ++i, ++vdst ) {
vdst->Clear(clientdata);
int h = this->_V_ITa[5*i ], // offset of the vertices in the _V0_IT array
n = this->_V_ITa[5*i+1], // number of vertices in the _VO_IT array (valence)
p = this->_V_ITa[5*i+2]; // index of the parent vertex
float weight = this->_V_W[i],
wp = 1.0f/(n*n),
wv = (n-2.0f)*n*wp;
vdst->AddWithWeight( vsrc[p], weight * wv, clientdata );
for (int j=0; j<n; ++j) {
vdst->AddWithWeight( vsrc[this->_V_IT[h+j*2 ]], weight * wp, clientdata );
vdst->AddWithWeight( vsrc[this->_V_IT[h+j*2+1]], weight * wp, clientdata );
}
vdst->AddVaryingWithWeight( vsrc[p], 1.0f, clientdata );
}
}
} // end namespace OPENSUBDIV_VERSION
using namespace OPENSUBDIV_VERSION;
} // end namespace OpenSubdiv
#endif /* FAR_CATMARK_SUBDIVISION_TABLES_H */
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