OpenSubdiv/opensubdiv/far/topologyRefiner.h
manuelk 5944ada0f9 Add Options structs to Far::TopologyRefiner refinement methods
- fix all splash damage to tutorials / examples...
2014-12-23 10:07:24 -08:00

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59 KiB
C++

//
// Copyright 2014 DreamWorks Animation LLC.
//
// Licensed under the Apache License, Version 2.0 (the "Apache License")
// with the following modification; you may not use this file except in
// compliance with the Apache License and the following modification to it:
// Section 6. Trademarks. is deleted and replaced with:
//
// 6. Trademarks. This License does not grant permission to use the trade
// names, trademarks, service marks, or product names of the Licensor
// and its affiliates, except as required to comply with Section 4(c) of
// the License and to reproduce the content of the NOTICE file.
//
// You may obtain a copy of the Apache License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the Apache License with the above modification is
// distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
// KIND, either express or implied. See the Apache License for the specific
// language governing permissions and limitations under the Apache License.
//
#ifndef FAR_TOPOLOGY_REFINER_H
#define FAR_TOPOLOGY_REFINER_H
#include "../version.h"
#include "../sdc/type.h"
#include "../sdc/options.h"
#include "../sdc/bilinearScheme.h"
#include "../sdc/catmarkScheme.h"
#include "../sdc/loopScheme.h"
#include "../vtr/level.h"
#include "../vtr/fvarLevel.h"
#include "../vtr/refinement.h"
#include "../vtr/fvarRefinement.h"
#include "../vtr/maskInterfaces.h"
#include "../far/types.h"
#include <vector>
#include <cassert>
#include <cstdio>
namespace OpenSubdiv {
namespace OPENSUBDIV_VERSION {
namespace Vtr { class SparseSelector; }
namespace Far {
template <class MESH> class TopologyRefinerFactory;
///
/// \brief Stores topology data for a specified set of refinement options.
///
class TopologyRefiner {
public:
/// \brief Constructor
TopologyRefiner(Sdc::Type type, Sdc::Options options = Sdc::Options());
/// \brief Destructor
~TopologyRefiner();
/// \brief Returns the subdivision scheme
Sdc::Type GetSchemeType() const { return _subdivType; }
/// \brief Returns the subdivision options
Sdc::Options GetSchemeOptions() const { return _subdivOptions; }
/// \brief Returns true if uniform subdivision has been applied
bool IsUniform() const { return _isUniform; }
/// \ brief Returns true if faces have been tagged as holes
bool HasHoles() const { return _hasHoles; }
/// \brief Returns the highest level of refinement
int GetMaxLevel() const { return _maxLevel; }
// XXXX barfowl -- should cache these internally for trivial return)
/// \brief Returns the total number of vertices in all levels
int GetNumVerticesTotal() const;
/// \brief Returns the total number of edges in all levels
int GetNumEdgesTotal() const;
/// \brief Returns the total number of edges in all levels
int GetNumFacesTotal() const;
/// \brief Returns the total number of face vertices in all levels
int GetNumFaceVerticesTotal() const;
//@{
/// @name High-level refinement and related methods
///
//
// Uniform refinement
//
/// \brief Uniform refinement options
struct UniformOptions {
UniformOptions() :
fullTopologyInLastLevel(false) { }
unsigned int fullTopologyInLastLevel:1; ///< Skip secondary topological relationships
///< at the highest level of refinement.
};
/// \brief Refine the topology uniformly
///
/// @param maxLevel Highest level of subdivision refinement
///
/// @param options Options controlling the creation of the tables
///
void RefineUniform(int maxLevel, UniformOptions options=UniformOptions());
//
// Adaptive refinement
//
/// \brief Adaptive refinement options
struct AdaptiveOptions {
AdaptiveOptions() :
fullTopologyInLastLevel(false),
useSingleCreasePatch(false) { }
unsigned int fullTopologyInLastLevel:1, ///< Skip secondary topological relationships
///< at the highest level of refinement.
useSingleCreasePatch:1; ///< Use 'single-crease' patch and stop
///< isolation where applicable
};
/// \brief Feature Adaptive topology refinement
///
/// @param maxLevel Highest level of subdivision refinement
///
/// @param options Options controlling the creation of the tables
///
void RefineAdaptive(int maxLevel, AdaptiveOptions options=AdaptiveOptions());
/// \brief Unrefine the topology (keep control cage)
void Unrefine();
/// \brief Clear the topology entirely
void Clear();
//@}
//@{
/// @name Primvar data interpolation
///
/// \anchor templating
///
/// \note Interpolation methods template both the source and destination
/// data buffer classes. Client-code is expected to provide interfaces
/// that implement the functions specific to its primitive variable
/// data layout. Template APIs must implement the following:
/// <br><br> \code{.cpp}
///
/// class MySource {
/// MySource & operator[](int index);
/// };
///
/// class MyDestination {
/// void Clear();
/// void AddWithWeight(MySource const & value, float weight);
/// void AddWithWeight(MyDestination const & value, float weight);
///
/// // optional
/// void AddVaryingWithWeight(MySource const & value, float weight);
/// };
///
/// \endcode
/// <br>
/// It is possible to implement a single interface only and use it as
/// both source and destination.
/// <br><br>
/// Primitive variable buffers are expected to be arrays of instances,
/// passed either as direct pointers or with a container
/// (ex. std::vector<MyVertex>).
/// Some interpolation methods however allow passing the buffers by
/// reference: this allows to work transparently with arrays and
/// containers (or other scheme that overload the '[]' operator)
/// <br><br>
/// See the <a href=http://internal-graphics.pixar.com/opensubdiv/docs/tutorials.html>
/// Far tutorials</a> for code examples.
///
/// \brief Apply vertex and varying interpolation weights to a primvar
/// buffer
///
/// The destination buffer must allocate an array of data for all the
/// refined vertices (at least GetNumVerticesTotal()-GetNumVertices(0))
///
/// @param src Source primvar buffer (\ref templating control vertex data)
///
/// @param dst Destination primvar buffer (\ref templating refined vertex data)
///
template <class T, class U> void Interpolate(T const * src, U * dst) const;
/// \brief Apply vertex and varying interpolation weights to a primvar
/// buffer for a single level
/// level of refinement.
///
/// The destination buffer must allocate an array of data for all the
/// refined vertices (at least GetNumVertices(level))
///
/// @param level The refinement level
///
/// @param src Source primvar buffer (\ref templating control vertex data)
///
/// @param dst Destination primvar buffer (\ref templating refined vertex data)
///
template <class T, class U> void Interpolate(int level, T const & src, U & dst) const;
/// \brief Apply only varying interpolation weights to a primvar buffer
///
/// This method can be a useful alternative if the varying primvar data
/// does not need to be re-computed over time.
///
/// The destination buffer must allocate an array of data for all the
/// refined vertices (at least GetNumVerticesTotal()-GetNumVertices(0))
///
/// @param src Source primvar buffer (\ref templating control vertex data)
///
/// @param dst Destination primvar buffer (\ref templating refined vertex data)
///
template <class T, class U> void InterpolateVarying(T const * src, U * dst) const;
/// \brief Apply only varying interpolation weights to a primvar buffer
/// for a single level level of refinement.
///
/// This method can be a useful alternative if the varying primvar data
/// does not need to be re-computed over time.
///
/// The destination buffer must allocate an array of data for all the
/// refined vertices (at least GetNumVertices(level))
///
/// @param level The refinement level
///
/// @param src Source primvar buffer (\ref templating control vertex data)
///
/// @param dst Destination primvar buffer (\ref templating refined vertex data)
///
template <class T, class U> void InterpolateVarying(int level, T const & src, U & dst) const;
/// \brief Apply face-varying interpolation weights to a primvar buffer
// associated with a particular face-varying channel
///
template <class T, class U> void InterpolateFaceVarying(T const * src, U * dst, int channel = 0) const;
template <class T, class U> void InterpolateFaceVarying(int level, T const & src, U & dst, int channel = 0) const;
template <class T, class U> void LimitFaceVarying(T const & src, U * dst, int channel = 0) const;
/// \brief Apply vertex interpolation limit weights to a primvar buffer
///
/// The source buffer must refer to an array of previously interpolated
/// vertex data for the last refinement level. The destination buffer
/// must allocate an array for all vertices at the last refinement level
/// (at least GetNumVertices(GetMaxLevel()))
///
/// @param src Source primvar buffer (refined vertex data) for last level
///
/// @param dst Destination primvar buffer (vertex data at the limit)
///
template <class T, class U> void Limit(T const & src, U * dst) const;
//@}
//@{
/// @name Inspection of components per level
///
/// \brief Returns the number of vertices at a given level of refinement
int GetNumVertices(int level) const {
return _levels[level]->getNumVertices();
}
/// \brief Returns the number of edges at a given level of refinement
int GetNumEdges(int level) const {
return _levels[level]->getNumEdges();
}
/// \brief Returns the number of face vertex indices at a given level of refinement
int GetNumFaces(int level) const {
return _levels[level]->getNumFaces();
}
/// \brief Returns the number of faces marked as holes at the given level
int GetNumHoles(int level) const;
/// \brief Returns the number of faces at a given level of refinement
int GetNumFaceVertices(int level) const {
return _levels[level]->getNumFaceVerticesTotal();
}
/// \brief Returns the sharpness of a given edge (at 'level' of refinement)
float GetEdgeSharpness(int level, Index edge) const {
return _levels[level]->getEdgeSharpness(edge);
}
/// \brief Returns the sharpness of a given vertex (at 'level' of refinement)
float GetVertexSharpness(int level, Index vert) const {
return _levels[level]->getVertexSharpness(vert);
}
/// \brief Returns the subdivision rule of a given vertex (at 'level' of refinement)
Sdc::Crease::Rule GetVertexRule(int level, Index vert) const {
return _levels[level]->getVertexRule(vert);
}
//@}
//@{
/// @name Topological relations -- incident/adjacent components
///
/// \brief Returns the vertices of a 'face' at 'level'
ConstIndexArray GetFaceVertices(int level, Index face) const {
return _levels[level]->getFaceVertices(face);
}
/// \brief Returns the edges of a 'face' at 'level'
ConstIndexArray GetFaceEdges(int level, Index face) const {
return _levels[level]->getFaceEdges(face);
}
/// \brief Returns true if 'face' at 'level' is tagged as a hole
bool IsHole(int level, Index face) const {
return _levels[level]->isHole(face);
}
/// \brief Returns the vertices of an 'edge' at 'level' (2 of them)
ConstIndexArray GetEdgeVertices(int level, Index edge) const {
return _levels[level]->getEdgeVertices(edge);
}
/// \brief Returns the faces incident to 'edge' at 'level'
ConstIndexArray GetEdgeFaces(int level, Index edge) const {
return _levels[level]->getEdgeFaces(edge);
}
/// \brief Returns the faces incident to 'vertex' at 'level'
ConstIndexArray GetVertexFaces(int level, Index vert) const {
return _levels[level]->getVertexFaces(vert);
}
/// \brief Returns the edges incident to 'vertex' at 'level'
ConstIndexArray GetVertexEdges(int level, Index vert) const {
return _levels[level]->getVertexEdges(vert);
}
/// \brief Returns the local face indices of vertex 'vert' at 'level'
ConstLocalIndexArray VertexFaceLocalIndices(int level, Index vert) const {
return _levels[level]->getVertexFaceLocalIndices(vert);
}
/// \brief Returns the local edge indices of vertex 'vert' at 'level'
ConstLocalIndexArray VertexEdgeLocalIndices(int level, Index vert) const {
return _levels[level]->getVertexEdgeLocalIndices(vert);
}
bool FaceIsRegular(int level, Index face) const {
ConstIndexArray fVerts = _levels[level]->getFaceVertices(face);
Vtr::Level::VTag compFaceVertTag =
_levels[level]->getFaceCompositeVTag(fVerts);
return not compFaceVertTag._xordinary;
}
/// \brief Returns the edge with vertices'v0' and 'v1' (or -1 if they are
/// not connected)
Index FindEdge(int level, Index v0, Index v1) const {
return _levels[level]->findEdge(v0, v1);
}
//@}
//@{
/// @name Inspection of face-varying channels and their contents:
///
/// \brief Returns the number of face-varying channels in the tables
int GetNumFVarChannels() const {
return _levels[0]->getNumFVarChannels();
}
/// \brief Returns the total number of face-varying values in all levels
int GetNumFVarValuesTotal(int channel = 0) const;
/// \brief Returns the number of face-varying values at a given level of refinement
int GetNumFVarValues(int level, int channel = 0) const {
return _levels[level]->getNumFVarValues(channel);
}
/// \brief Returns the face-varying values of a 'face' at 'level'
ConstIndexArray const GetFVarFaceValues(int level, Index face, int channel = 0) const {
return _levels[level]->getFVarFaceValues(face, channel);
}
//@}
//@{
/// @name Parent-to-child relationships,
/// Telationships between components in one level
/// and the next (entries may be invalid if sparse):
///
/// \brief Returns the child faces of face 'f' at 'level'
ConstIndexArray GetFaceChildFaces(int level, Index f) const {
return _refinements[level]->getFaceChildFaces(f);
}
/// \brief Returns the child edges of face 'f' at 'level'
ConstIndexArray GetFaceChildEdges(int level, Index f) const {
return _refinements[level]->getFaceChildEdges(f);
}
/// \brief Returns the child edges of edge 'e' at 'level'
ConstIndexArray GetEdgeChildEdges(int level, Index e) const {
return _refinements[level]->getEdgeChildEdges(e);
}
/// \brief Returns the child vertex of face 'f' at 'level'
Index GetFaceChildVertex( int level, Index f) const {
return _refinements[level]->getFaceChildVertex(f);
}
/// \brief Returns the child vertex of edge 'e' at 'level'
Index GetEdgeChildVertex( int level, Index e) const {
return _refinements[level]->getEdgeChildVertex(e);
}
/// \brief Returns the child vertex of vertex 'v' at 'level'
Index GetVertexChildVertex(int level, Index v) const {
return _refinements[level]->getVertexChildVertex(v);
}
//@}
//@{
/// Ptex
///
/// \brief Returns the number of ptex faces in the mesh
int GetNumPtexFaces() const;
/// \brief Returns the ptex face index given a coarse face 'f' or -1
int GetPtexIndex(Index f) const;
/// \brief Returns ptex face adjacency information for a given coarse face
///
/// @param face coarse face index
///
/// @param quadrant quadrant index if 'face' is not a quad (the local ptex
// sub-face index). Must be less than the number of face
// vertices.
///
/// @param adjFaces ptex face indices of adjacent faces
///
/// @param adjEdges ptex edge indices of adjacent faces
///
void GetPtexAdjacency(int face, int quadrant,
int adjFaces[4], int adjEdges[4]) const;
//@}
//@{
/// @name Debugging aides
///
/// \brief Returns true if the topology of 'level' is valid
bool ValidateTopology(int level) const {
return _levels[level]->validateTopology();
}
/// \brief Prints topology information to console
void PrintTopology(int level, bool children = true) const {
_levels[level]->print(children ? _refinements[level] : 0);
}
//@}
protected:
//
// For use by the Factory base and subclasses to construct the base level:
//
template <class MESH>
friend class TopologyRefinerFactory;
friend class TopologyRefinerFactoryBase;
friend class PatchTablesFactory;
friend class GregoryBasisFactory;
int getNumLevels() const { return (int)_levels.size(); }
Vtr::Level & getBaseLevel() { return *_levels.front(); }
Vtr::Level & getLevel(int l) { return *_levels[l]; }
Vtr::Level const & getLevel(int l) const { return *_levels[l]; }
Vtr::Refinement & getRefinement(int l) { return *_refinements[l]; }
Vtr::Refinement const & getRefinement(int l) const { return *_refinements[l]; }
int getNumBaseFaces() const { return GetNumFaces(0); }
int getNumBaseEdges() const { return GetNumEdges(0); }
int getNumBaseVertices() const { return GetNumVertices(0); }
// Sizing specifications required before allocation:
void setNumBaseFaces( int count) { _levels[0]->resizeFaces(count); }
void setNumBaseEdges( int count) { _levels[0]->resizeEdges(count); }
void setNumBaseVertices(int count) { _levels[0]->resizeVertices(count); }
void setNumBaseFaceVertices(Index f, int count) { _levels[0]->resizeFaceVertices(f, count); }
void setNumBaseEdgeFaces( Index e, int count) { _levels[0]->resizeEdgeFaces(e, count); }
void setNumBaseVertexFaces( Index v, int count) { _levels[0]->resizeVertexFaces(v, count); }
void setNumBaseVertexEdges( Index v, int count) { _levels[0]->resizeVertexEdges(v, count); }
// Access to populate the base level topology after allocation:
IndexArray setBaseFaceVertices(Index f) { return _levels[0]->getFaceVertices(f); }
IndexArray setBaseFaceEdges( Index f) { return _levels[0]->getFaceEdges(f); }
IndexArray setBaseEdgeVertices(Index e) { return _levels[0]->getEdgeVertices(e); }
IndexArray setBaseEdgeFaces( Index e) { return _levels[0]->getEdgeFaces(e); }
IndexArray setBaseVertexFaces( Index v) { return _levels[0]->getVertexFaces(v); }
IndexArray setBaseVertexEdges( Index v) { return _levels[0]->getVertexEdges(v); }
// Not sure yet if we will determine these internally...
LocalIndexArray setBaseVertexFaceLocalIndices(Index v) { return _levels[0]->getVertexFaceLocalIndices(v); }
LocalIndexArray setBaseVertexEdgeLocalIndices(Index v) { return _levels[0]->getVertexEdgeLocalIndices(v); }
// Optionally available to get/set sharpness values:
float& baseEdgeSharpness(Index e) { return _levels[0]->getEdgeSharpness(e); }
float& baseVertexSharpness(Index v) { return _levels[0]->getVertexSharpness(v); }
void setBaseFaceHole(Index f, bool b) { _levels[0]->setHole(f, b); _hasHoles |= b; }
// Face-varying modifiers for constructing face-varying channels:
int createFVarChannel(int numValues) {
return _levels[0]->createFVarChannel(numValues, _subdivOptions);
}
int createFVarChannel(int numValues, Sdc::Options const& options) {
return _levels[0]->createFVarChannel(numValues, options);
}
void completeFVarChannelTopology(int channel = 0) { _levels[0]->completeFVarChannelTopology(channel); }
IndexArray getBaseFVarFaceValues(Index face, int channel = 0) { return _levels[0]->getFVarFaceValues(face, channel); }
void populateLocalIndices() {
getBaseLevel().populateLocalIndices();
}
private:
void selectFeatureAdaptiveComponents(Vtr::SparseSelector& selector);
template <Sdc::Type SCHEME, class T, class U> void interpolateChildVertsFromFaces(Vtr::Refinement const &, T const & src, U & dst) const;
template <Sdc::Type SCHEME, class T, class U> void interpolateChildVertsFromEdges(Vtr::Refinement const &, T const & src, U & dst) const;
template <Sdc::Type SCHEME, class T, class U> void interpolateChildVertsFromVerts(Vtr::Refinement const &, T const & src, U & dst) const;
template <class T, class U> void varyingInterpolateChildVertsFromFaces(Vtr::Refinement const &, T const & src, U & dst) const;
template <class T, class U> void varyingInterpolateChildVertsFromEdges(Vtr::Refinement const &, T const & src, U & dst) const;
template <class T, class U> void varyingInterpolateChildVertsFromVerts(Vtr::Refinement const &, T const & src, U & dst) const;
template <Sdc::Type SCHEME, class T, class U> void faceVaryingInterpolateChildVertsFromFaces(Vtr::Refinement const &, T const & src, U & dst, int channel) const;
template <Sdc::Type SCHEME, class T, class U> void faceVaryingInterpolateChildVertsFromEdges(Vtr::Refinement const &, T const & src, U & dst, int channel) const;
template <Sdc::Type SCHEME, class T, class U> void faceVaryingInterpolateChildVertsFromVerts(Vtr::Refinement const &, T const & src, U & dst, int channel) const;
template <Sdc::Type SCHEME, class T, class U> void limit(T const & src, U * dst) const;
template <Sdc::Type SCHEME, class T, class U> void faceVaryingLimit(T const & src, U * dst, int channel) const;
void initializePtexIndices() const;
private:
Sdc::Type _subdivType;
Sdc::Options _subdivOptions;
unsigned char _isUniform : 1,
_hasHoles : 1,
_useSingleCreasePatch : 1,
_maxLevel : 4;
std::vector<Vtr::Level *> _levels;
std::vector<Vtr::Refinement *> _refinements;
std::vector<Index> _ptexIndices;
};
template <class T, class U>
inline void
TopologyRefiner::Interpolate(T const * src, U * dst) const {
for (int level=1; level<=GetMaxLevel(); ++level) {
Interpolate(level, src, dst);
src = dst;
dst += GetNumVertices(level);
}
}
template <class T, class U>
inline void
TopologyRefiner::Interpolate(int level, T const & src, U & dst) const {
assert(level>0 and level<=(int)_refinements.size());
Vtr::Refinement const & refinement = getRefinement(level-1);
switch (_subdivType) {
case Sdc::TYPE_CATMARK:
interpolateChildVertsFromFaces<Sdc::TYPE_CATMARK>(refinement, src, dst);
interpolateChildVertsFromEdges<Sdc::TYPE_CATMARK>(refinement, src, dst);
interpolateChildVertsFromVerts<Sdc::TYPE_CATMARK>(refinement, src, dst);
break;
case Sdc::TYPE_LOOP:
interpolateChildVertsFromFaces<Sdc::TYPE_LOOP>(refinement, src, dst);
interpolateChildVertsFromEdges<Sdc::TYPE_LOOP>(refinement, src, dst);
interpolateChildVertsFromVerts<Sdc::TYPE_LOOP>(refinement, src, dst);
break;
case Sdc::TYPE_BILINEAR:
interpolateChildVertsFromFaces<Sdc::TYPE_BILINEAR>(refinement, src, dst);
interpolateChildVertsFromEdges<Sdc::TYPE_BILINEAR>(refinement, src, dst);
interpolateChildVertsFromVerts<Sdc::TYPE_BILINEAR>(refinement, src, dst);
break;
}
}
template <Sdc::Type SCHEME, class T, class U>
inline void
TopologyRefiner::interpolateChildVertsFromFaces(
Vtr::Refinement const & refinement, T const & src, U & dst) const {
if (refinement.getNumChildVerticesFromFaces() == 0) return;
Sdc::Scheme<SCHEME> scheme(_subdivOptions);
const Vtr::Level& parent = refinement.parent();
float * fVertWeights = (float *)alloca(parent.getMaxValence()*sizeof(float));
for (int face = 0; face < parent.getNumFaces(); ++face) {
Vtr::Index cVert = refinement.getFaceChildVertex(face);
if (!Vtr::IndexIsValid(cVert))
continue;
// Declare and compute mask weights for this vertex relative to its parent face:
ConstIndexArray fVerts = parent.getFaceVertices(face);
float fVaryingWeight = 1.0f / (float) fVerts.size();
Vtr::MaskInterface fMask(fVertWeights, 0, 0);
Vtr::FaceInterface fHood(fVerts.size());
scheme.ComputeFaceVertexMask(fHood, fMask);
// Apply the weights to the parent face's vertices:
dst[cVert].Clear();
for (int i = 0; i < fVerts.size(); ++i) {
dst[cVert].AddWithWeight(src[fVerts[i]], fVertWeights[i]);
dst[cVert].AddVaryingWithWeight(src[fVerts[i]], fVaryingWeight);
}
}
}
template <Sdc::Type SCHEME, class T, class U>
inline void
TopologyRefiner::interpolateChildVertsFromEdges(
Vtr::Refinement const & refinement, T const & src, U & dst) const {
Sdc::Scheme<SCHEME> scheme(_subdivOptions);
const Vtr::Level& parent = refinement.parent();
const Vtr::Level& child = refinement.child();
Vtr::EdgeInterface eHood(parent);
float eVertWeights[2],
* eFaceWeights = (float *)alloca(parent.getMaxEdgeFaces()*sizeof(float));
for (int edge = 0; edge < parent.getNumEdges(); ++edge) {
Vtr::Index cVert = refinement.getEdgeChildVertex(edge);
if (!Vtr::IndexIsValid(cVert))
continue;
// Declare and compute mask weights for this vertex relative to its parent edge:
ConstIndexArray eVerts = parent.getEdgeVertices(edge),
eFaces = parent.getEdgeFaces(edge);
Vtr::MaskInterface eMask(eVertWeights, 0, eFaceWeights);
eHood.SetIndex(edge);
Sdc::Crease::Rule pRule = (parent.getEdgeSharpness(edge) > 0.0f) ? Sdc::Crease::RULE_CREASE : Sdc::Crease::RULE_SMOOTH;
Sdc::Crease::Rule cRule = child.getVertexRule(cVert);
scheme.ComputeEdgeVertexMask(eHood, eMask, pRule, cRule);
// Apply the weights to the parent edges's vertices and (if applicable) to
// the child vertices of its incident faces:
dst[cVert].Clear();
dst[cVert].AddWithWeight(src[eVerts[0]], eVertWeights[0]);
dst[cVert].AddWithWeight(src[eVerts[1]], eVertWeights[1]);
dst[cVert].AddVaryingWithWeight(src[eVerts[0]], 0.5f);
dst[cVert].AddVaryingWithWeight(src[eVerts[1]], 0.5f);
if (eMask.GetNumFaceWeights() > 0) {
for (int i = 0; i < eFaces.size(); ++i) {
if (eMask.AreFaceWeightsForFaceCenters()) {
assert(refinement.getNumChildVerticesFromFaces() > 0);
Vtr::Index cVertOfFace = refinement.getFaceChildVertex(eFaces[i]);
assert(Vtr::IndexIsValid(cVertOfFace));
dst[cVert].AddWithWeight(dst[cVertOfFace], eFaceWeights[i]);
} else {
Vtr::Index pFace = eFaces[i];
ConstIndexArray pFaceEdges = parent.getFaceEdges(pFace),
pFaceVerts = parent.getFaceVertices(pFace);
int eInFace = 0;
for ( ; pFaceEdges[eInFace] != edge; ++eInFace ) ;
int vInFace = eInFace + 2;
if (vInFace >= pFaceVerts.size()) vInFace -= pFaceVerts.size();
Vtr::Index pVertNext = pFaceVerts[vInFace];
dst[cVert].AddWithWeight(src[pVertNext], eFaceWeights[i]);
}
}
}
}
}
template <Sdc::Type SCHEME, class T, class U>
inline void
TopologyRefiner::interpolateChildVertsFromVerts(
Vtr::Refinement const & refinement, T const & src, U & dst) const {
Sdc::Scheme<SCHEME> scheme(_subdivOptions);
const Vtr::Level& parent = refinement.parent();
const Vtr::Level& child = refinement.child();
Vtr::VertexInterface vHood(parent, child);
float * weightBuffer = (float *)alloca(2*parent.getMaxValence()*sizeof(float));
for (int vert = 0; vert < parent.getNumVertices(); ++vert) {
Vtr::Index cVert = refinement.getVertexChildVertex(vert);
if (!Vtr::IndexIsValid(cVert))
continue;
// Declare and compute mask weights for this vertex relative to its parent edge:
ConstIndexArray vEdges = parent.getVertexEdges(vert),
vFaces = parent.getVertexFaces(vert);
float vVertWeight,
* vEdgeWeights = weightBuffer,
* vFaceWeights = vEdgeWeights + vEdges.size();
Vtr::MaskInterface vMask(&vVertWeight, vEdgeWeights, vFaceWeights);
vHood.SetIndex(vert, cVert);
Sdc::Crease::Rule pRule = parent.getVertexRule(vert);
Sdc::Crease::Rule cRule = child.getVertexRule(cVert);
scheme.ComputeVertexVertexMask(vHood, vMask, pRule, cRule);
// Apply the weights to the parent vertex, the vertices opposite its incident
// edges, and the child vertices of its incident faces:
//
// In order to improve numerical precision, its better to apply smaller weights
// first, so begin with the face-weights followed by the edge-weights and the
// vertex weight last.
dst[cVert].Clear();
if (vMask.GetNumFaceWeights() > 0) {
assert(vMask.AreFaceWeightsForFaceCenters());
for (int i = 0; i < vFaces.size(); ++i) {
Vtr::Index cVertOfFace = refinement.getFaceChildVertex(vFaces[i]);
assert(Vtr::IndexIsValid(cVertOfFace));
dst[cVert].AddWithWeight(dst[cVertOfFace], vFaceWeights[i]);
}
}
if (vMask.GetNumEdgeWeights() > 0) {
for (int i = 0; i < vEdges.size(); ++i) {
ConstIndexArray eVerts = parent.getEdgeVertices(vEdges[i]);
Vtr::Index pVertOppositeEdge = (eVerts[0] == vert) ? eVerts[1] : eVerts[0];
dst[cVert].AddWithWeight(src[pVertOppositeEdge], vEdgeWeights[i]);
}
}
dst[cVert].AddWithWeight(src[vert], vVertWeight);
dst[cVert].AddVaryingWithWeight(src[vert], 1.0f);
}
}
//
// Varying only interpolation
//
template <class T, class U>
inline void
TopologyRefiner::InterpolateVarying(T const * src, U * dst) const {
for (int level=1; level<=GetMaxLevel(); ++level) {
InterpolateVarying(level, src, dst);
src = dst;
dst += GetNumVertices(level);
}
}
template <class T, class U>
inline void
TopologyRefiner::InterpolateVarying(int level, T const & src, U & dst) const {
assert(level>0 and level<=(int)_refinements.size());
Vtr::Refinement const & refinement = getRefinement(level-1);
varyingInterpolateChildVertsFromFaces(refinement, src, dst);
varyingInterpolateChildVertsFromEdges(refinement, src, dst);
varyingInterpolateChildVertsFromVerts(refinement, src, dst);
}
template <class T, class U>
inline void
TopologyRefiner::varyingInterpolateChildVertsFromFaces(
Vtr::Refinement const & refinement, T const & src, U & dst) const {
if (refinement.getNumChildVerticesFromFaces() == 0) return;
const Vtr::Level& parent = refinement.parent();
for (int face = 0; face < parent.getNumFaces(); ++face) {
Vtr::Index cVert = refinement.getFaceChildVertex(face);
if (!Vtr::IndexIsValid(cVert))
continue;
ConstIndexArray fVerts = parent.getFaceVertices(face);
float fVaryingWeight = 1.0f / (float) fVerts.size();
// Apply the weights to the parent face's vertices:
dst[cVert].Clear();
for (int i = 0; i < fVerts.size(); ++i) {
dst[cVert].AddVaryingWithWeight(src[fVerts[i]], fVaryingWeight);
}
}
}
template <class T, class U>
inline void
TopologyRefiner::varyingInterpolateChildVertsFromEdges(
Vtr::Refinement const & refinement, T const & src, U & dst) const {
const Vtr::Level& parent = refinement.parent();
for (int edge = 0; edge < parent.getNumEdges(); ++edge) {
Vtr::Index cVert = refinement.getEdgeChildVertex(edge);
if (!Vtr::IndexIsValid(cVert))
continue;
// Declare and compute mask weights for this vertex relative to its parent edge:
ConstIndexArray eVerts = parent.getEdgeVertices(edge);
// Apply the weights to the parent edges's vertices
dst[cVert].Clear();
dst[cVert].AddVaryingWithWeight(src[eVerts[0]], 0.5f);
dst[cVert].AddVaryingWithWeight(src[eVerts[1]], 0.5f);
}
}
template <class T, class U>
inline void
TopologyRefiner::varyingInterpolateChildVertsFromVerts(
Vtr::Refinement const & refinement, T const & src, U & dst) const {
const Vtr::Level& parent = refinement.parent();
for (int vert = 0; vert < parent.getNumVertices(); ++vert) {
Vtr::Index cVert = refinement.getVertexChildVertex(vert);
if (!Vtr::IndexIsValid(cVert))
continue;
// Apply the weights to the parent vertex
dst[cVert].Clear();
dst[cVert].AddVaryingWithWeight(src[vert], 1.0f);
}
}
//
// Face-varying only interpolation
//
template <class T, class U>
inline void
TopologyRefiner::InterpolateFaceVarying(T const * src, U * dst, int channel) const {
for (int level=1; level<=GetMaxLevel(); ++level) {
InterpolateFaceVarying(level, src, dst, channel);
src = dst;
dst += getLevel(level).getNumFVarValues();
}
}
template <class T, class U>
inline void
TopologyRefiner::InterpolateFaceVarying(int level, T const & src, U & dst, int channel) const {
assert(level>0 and level<=(int)_refinements.size());
Vtr::Refinement const & refinement = getRefinement(level-1);
switch (_subdivType) {
case Sdc::TYPE_CATMARK:
faceVaryingInterpolateChildVertsFromFaces<Sdc::TYPE_CATMARK>(refinement, src, dst, channel);
faceVaryingInterpolateChildVertsFromEdges<Sdc::TYPE_CATMARK>(refinement, src, dst, channel);
faceVaryingInterpolateChildVertsFromVerts<Sdc::TYPE_CATMARK>(refinement, src, dst, channel);
break;
case Sdc::TYPE_LOOP:
faceVaryingInterpolateChildVertsFromFaces<Sdc::TYPE_LOOP>(refinement, src, dst, channel);
faceVaryingInterpolateChildVertsFromEdges<Sdc::TYPE_LOOP>(refinement, src, dst, channel);
faceVaryingInterpolateChildVertsFromVerts<Sdc::TYPE_LOOP>(refinement, src, dst, channel);
break;
case Sdc::TYPE_BILINEAR:
faceVaryingInterpolateChildVertsFromFaces<Sdc::TYPE_BILINEAR>(refinement, src, dst, channel);
faceVaryingInterpolateChildVertsFromEdges<Sdc::TYPE_BILINEAR>(refinement, src, dst, channel);
faceVaryingInterpolateChildVertsFromVerts<Sdc::TYPE_BILINEAR>(refinement, src, dst, channel);
break;
}
}
template <Sdc::Type SCHEME, class T, class U>
inline void
TopologyRefiner::faceVaryingInterpolateChildVertsFromFaces(
Vtr::Refinement const & refinement, T const & src, U & dst, int channel) const {
if (refinement.getNumChildVerticesFromFaces() == 0) return;
Sdc::Scheme<SCHEME> scheme(_subdivOptions);
const Vtr::Level& parentLevel = refinement.parent();
const Vtr::Level& childLevel = refinement.child();
const Vtr::FVarLevel& parentFVar = *parentLevel._fvarChannels[channel];
const Vtr::FVarLevel& childFVar = *childLevel._fvarChannels[channel];
float * fValueWeights = (float *)alloca(parentLevel.getMaxValence()*sizeof(float));
for (int face = 0; face < parentLevel.getNumFaces(); ++face) {
Vtr::Index cVert = refinement.getFaceChildVertex(face);
if (!Vtr::IndexIsValid(cVert))
continue;
Vtr::Index cVertValue = childFVar.getVertexValueOffset(cVert);
// The only difference for face-varying here is that we get the values associated
// with each face-vertex directly from the FVarLevel, rather than using the parent
// face-vertices directly. If any face-vertex has any sibling values, then we may
// get the wrong one using the face-vertex index directly.
// Declare and compute mask weights for this vertex relative to its parent face:
ConstIndexArray fValues = parentFVar.getFaceValues(face);
Vtr::MaskInterface fMask(fValueWeights, 0, 0);
Vtr::FaceInterface fHood(fValues.size());
scheme.ComputeFaceVertexMask(fHood, fMask);
// Apply the weights to the parent face's vertices:
dst[cVertValue].Clear();
for (int i = 0; i < fValues.size(); ++i) {
dst[cVertValue].AddWithWeight(src[fValues[i]], fValueWeights[i]);
}
}
}
template <Sdc::Type SCHEME, class T, class U>
inline void
TopologyRefiner::faceVaryingInterpolateChildVertsFromEdges(
Vtr::Refinement const & refinement, T const & src, U & dst, int channel) const {
Sdc::Scheme<SCHEME> scheme(_subdivOptions);
const Vtr::Level& parentLevel = refinement.parent();
const Vtr::Level& childLevel = refinement.child();
const Vtr::FVarRefinement& refineFVar = *refinement._fvarChannels[channel];
const Vtr::FVarLevel& parentFVar = *parentLevel._fvarChannels[channel];
const Vtr::FVarLevel& childFVar = *childLevel._fvarChannels[channel];
//
// Allocate and intialize (if linearly interpolated) interpolation weights for
// the edge mask:
//
float eVertWeights[2],
* eFaceWeights = (float *)alloca(parentLevel.getMaxEdgeFaces()*sizeof(float));
Vtr::MaskInterface eMask(eVertWeights, 0, eFaceWeights);
bool isLinearFVar = parentFVar._isLinear;
if (isLinearFVar) {
eMask.SetNumVertexWeights(2);
eMask.SetNumEdgeWeights(0);
eMask.SetNumFaceWeights(0);
eVertWeights[0] = 0.5f;
eVertWeights[1] = 0.5f;
}
Vtr::EdgeInterface eHood(parentLevel);
for (int edge = 0; edge < parentLevel.getNumEdges(); ++edge) {
Vtr::Index cVert = refinement.getEdgeChildVertex(edge);
if (!Vtr::IndexIsValid(cVert))
continue;
ConstIndexArray cVertValues = childFVar.getVertexValues(cVert);
bool fvarEdgeVertMatchesVertex = childFVar.valueTopologyMatches(cVertValues[0]);
if (fvarEdgeVertMatchesVertex) {
//
// If smoothly interpolated, compute new weights for the edge mask:
//
if (!isLinearFVar) {
eHood.SetIndex(edge);
Sdc::Crease::Rule pRule = (parentLevel.getEdgeSharpness(edge) > 0.0f)
? Sdc::Crease::RULE_CREASE : Sdc::Crease::RULE_SMOOTH;
Sdc::Crease::Rule cRule = childLevel.getVertexRule(cVert);
scheme.ComputeEdgeVertexMask(eHood, eMask, pRule, cRule);
}
// Apply the weights to the parent edges's vertices and (if applicable) to
// the child vertices of its incident faces:
//
// Even though the face-varying topology matches the vertex topology, we need
// to be careful here when getting values corresponding to the two end-vertices.
// While the edge may be continuous, the vertices at their ends may have
// discontinuities elsewhere in their neighborhood (i.e. on the "other side"
// of the end-vertex) and so have sibling values associated with them. In most
// cases the topology for an end-vertex will match and we can use it directly,
// but we must still check and retrieve as needed.
//
// Indices for values corresponding to face-vertices are guaranteed to match,
// so we can use the child-vertex indices directly.
//
// And by "directly", we always use getVertexValue(vertexIndex) to reference
// values in the "src" to account for the possible indirection that may exist at
// level 0 -- where there may be fewer values than vertices and an additional
// indirection is necessary. We can use a vertex index directly for "dst" when
// it matches.
//
Vtr::Index eVertValues[2];
parentFVar.getEdgeFaceValues(edge, 0, eVertValues);
Index cVertValue = cVertValues[0];
dst[cVertValue].Clear();
dst[cVertValue].AddWithWeight(src[eVertValues[0]], eVertWeights[0]);
dst[cVertValue].AddWithWeight(src[eVertValues[1]], eVertWeights[1]);
if (eMask.GetNumFaceWeights() > 0) {
ConstIndexArray eFaces = parentLevel.getEdgeFaces(edge);
for (int i = 0; i < eFaces.size(); ++i) {
if (eMask.AreFaceWeightsForFaceCenters()) {
Vtr::Index cVertOfFace = refinement.getFaceChildVertex(eFaces[i]);
assert(Vtr::IndexIsValid(cVertOfFace));
Vtr::Index cValueOfFace = childFVar.getVertexValueOffset(cVertOfFace);
dst[cVertValue].AddWithWeight(dst[cValueOfFace], eFaceWeights[i]);
} else {
Vtr::Index pFace = eFaces[i];
ConstIndexArray pFaceEdges = parentLevel.getFaceEdges(pFace),
pFaceVerts = parentLevel.getFaceVertices(pFace);
int eInFace = 0;
for ( ; pFaceEdges[eInFace] != edge; ++eInFace ) ;
// Edge "i" spans vertices [i,i+1] so we want i+2...
int vInFace = eInFace + 2;
if (vInFace >= pFaceVerts.size()) vInFace -= pFaceVerts.size();
Vtr::Index pValueNext = parentFVar.getFaceValues(pFace)[vInFace];
dst[cVertValue].AddWithWeight(src[pValueNext], eFaceWeights[i]);
}
}
}
} else {
//
// Mismatched edge-verts should just be linearly interpolated between the pairs of
// values for each sibling of the child edge-vertex -- the question is: which face
// holds that pair of values for a given sibling?
//
// In the manifold case, the sibling and edge-face indices will correspond. We
// will eventually need to update this to account for > 3 incident faces.
//
for (int i = 0; i < cVertValues.size(); ++i) {
Vtr::Index eVertValues[2];
int eFaceIndex = refineFVar.getChildValueParentSource(cVert, i);
assert(eFaceIndex == i);
parentFVar.getEdgeFaceValues(edge, eFaceIndex, eVertValues);
Index cVertValue = cVertValues[i];
dst[cVertValue].Clear();
dst[cVertValue].AddWithWeight(src[eVertValues[0]], 0.5);
dst[cVertValue].AddWithWeight(src[eVertValues[1]], 0.5);
}
}
}
}
template <Sdc::Type SCHEME, class T, class U>
inline void
TopologyRefiner::faceVaryingInterpolateChildVertsFromVerts(
Vtr::Refinement const & refinement, T const & src, U & dst, int channel) const {
Sdc::Scheme<SCHEME> scheme(_subdivOptions);
const Vtr::Level& parentLevel = refinement.parent();
const Vtr::Level& childLevel = refinement.child();
const Vtr::FVarRefinement& refineFVar = *refinement._fvarChannels[channel];
const Vtr::FVarLevel& parentFVar = *parentLevel._fvarChannels[channel];
const Vtr::FVarLevel& childFVar = *childLevel._fvarChannels[channel];
bool isLinearFVar = parentFVar._isLinear;
float * weightBuffer = (float *)alloca(2*parentLevel.getMaxValence()*sizeof(float));
Vtr::Index * vEdgeValues = (Vtr::Index *)alloca(parentLevel.getMaxValence()*sizeof(Vtr::Index));
Vtr::VertexInterface vHood(parentLevel, childLevel);
for (int vert = 0; vert < parentLevel.getNumVertices(); ++vert) {
Vtr::Index cVert = refinement.getVertexChildVertex(vert);
if (!Vtr::IndexIsValid(cVert))
continue;
ConstIndexArray pVertValues = parentFVar.getVertexValues(vert),
cVertValues = childFVar.getVertexValues(cVert);
bool fvarVertVertMatchesVertex = childFVar.valueTopologyMatches(cVertValues[0]);
if (isLinearFVar && fvarVertVertMatchesVertex) {
dst[cVertValues[0]].Clear();
dst[cVertValues[0]].AddWithWeight(src[pVertValues[0]], 1.0f);
continue;
}
if (fvarVertVertMatchesVertex) {
//
// Declare and compute mask weights for this vertex relative to its parent edge:
//
// (We really need to encapsulate this somewhere else for use here and in the
// general case)
//
ConstIndexArray vEdges = parentLevel.getVertexEdges(vert);
float vVertWeight;
float * vEdgeWeights = weightBuffer;
float * vFaceWeights = vEdgeWeights + vEdges.size();
Vtr::MaskInterface vMask(&vVertWeight, vEdgeWeights, vFaceWeights);
vHood.SetIndex(vert, cVert);
Sdc::Crease::Rule pRule = parentLevel.getVertexRule(vert);
Sdc::Crease::Rule cRule = childLevel.getVertexRule(cVert);
scheme.ComputeVertexVertexMask(vHood, vMask, pRule, cRule);
// Apply the weights to the parent vertex, the vertices opposite its incident
// edges, and the child vertices of its incident faces:
//
// Even though the face-varying topology matches the vertex topology, we need
// to be careful here when getting values corresponding to vertices at the
// ends of edges. While the edge may be continuous, the end vertex may have
// discontinuities elsewhere in their neighborhood (i.e. on the "other side"
// of the end-vertex) and so have sibling values associated with them. In most
// cases the topology for an end-vertex will match and we can use it directly,
// but we must still check and retrieve as needed.
//
// Indices for values corresponding to face-vertices are guaranteed to match,
// so we can use the child-vertex indices directly.
//
// And by "directly", we always use getVertexValue(vertexIndex) to reference
// values in the "src" to account for the possible indirection that may exist at
// level 0 -- where there may be fewer values than vertices and an additional
// indirection is necessary. We can use a vertex index directly for "dst" when
// it matches.
//
// As with applying the mask to vertex data, in order to improve numerical
// precision, its better to apply smaller weights first, so begin with the
// face-weights followed by the edge-weights and the vertex weight last.
//
Vtr::Index pVertValue = pVertValues[0];
Vtr::Index cVertValue = cVertValues[0];
dst[cVertValue].Clear();
if (vMask.GetNumFaceWeights() > 0) {
assert(vMask.AreFaceWeightsForFaceCenters());
ConstIndexArray vFaces = parentLevel.getVertexFaces(vert);
for (int i = 0; i < vFaces.size(); ++i) {
Vtr::Index cVertOfFace = refinement.getFaceChildVertex(vFaces[i]);
assert(Vtr::IndexIsValid(cVertOfFace));
Vtr::Index cValueOfFace = childFVar.getVertexValueOffset(cVertOfFace);
dst[cVertValue].AddWithWeight(dst[cValueOfFace], vFaceWeights[i]);
}
}
if (vMask.GetNumEdgeWeights() > 0) {
parentFVar.getVertexEdgeValues(vert, vEdgeValues);
for (int i = 0; i < vEdges.size(); ++i) {
dst[cVertValue].AddWithWeight(src[vEdgeValues[i]], vEdgeWeights[i]);
}
}
dst[cVertValue].AddWithWeight(src[pVertValue], vVertWeight);
} else {
//
// Each FVar value associated with a vertex will be either a corner or a crease,
// or potentially in transition from corner to crease:
// - if the CHILD is a corner, there can be no transition so we have a corner
// - otherwise if the PARENT is a crease, both will be creases (no transition)
// - otherwise the parent must be a corner and the child a crease (transition)
//
Vtr::FVarLevel::ConstValueTagArray pValueTags = parentFVar.getVertexValueTags(vert);
Vtr::FVarLevel::ConstValueTagArray cValueTags = childFVar.getVertexValueTags(cVert);
for (int cSibling = 0; cSibling < cVertValues.size(); ++cSibling) {
int pSibling = refineFVar.getChildValueParentSource(cVert, cSibling);
assert(pSibling == cSibling);
Vtr::Index pVertValue = pVertValues[pSibling];
Vtr::Index cVertValue = cVertValues[cSibling];
dst[cVertValue].Clear();
if (cValueTags[cSibling].isCorner()) {
dst[cVertValue].AddWithWeight(src[pVertValue], 1.0f);
} else {
//
// We have either a crease or a transition from corner to crease -- in
// either case, we need the end values for the full/fractional crease:
//
Index pEndValues[2];
parentFVar.getVertexCreaseEndValues(vert, pSibling, pEndValues);
float vWeight = 0.75f;
float eWeight = 0.125f;
//
// If semisharp we need to apply fractional weighting -- if made sharp because
// of the other sibling (dependent-sharp) use the fractional weight from that
// other sibling (should only occur when there are 2):
//
if (pValueTags[pSibling].isSemiSharp()) {
float wCorner = pValueTags[pSibling].isDepSharp()
? refineFVar.getFractionalWeight(vert, !pSibling, cVert, !cSibling)
: refineFVar.getFractionalWeight(vert, pSibling, cVert, cSibling);
float wCrease = 1.0f - wCorner;
vWeight = wCrease * 0.75f + wCorner;
eWeight = wCrease * 0.125f;
}
dst[cVertValue].AddWithWeight(src[pEndValues[0]], eWeight);
dst[cVertValue].AddWithWeight(src[pEndValues[1]], eWeight);
dst[cVertValue].AddWithWeight(src[pVertValue], vWeight);
}
}
}
}
}
template <class T, class U>
inline void
TopologyRefiner::Limit(T const & src, U * dst) const {
assert(GetMaxLevel() > 0);
switch (_subdivType) {
case Sdc::TYPE_CATMARK:
limit<Sdc::TYPE_CATMARK>(src, dst);
break;
case Sdc::TYPE_LOOP:
limit<Sdc::TYPE_LOOP>(src, dst);
break;
case Sdc::TYPE_BILINEAR:
limit<Sdc::TYPE_BILINEAR>(src, dst);
break;
}
}
template <Sdc::Type SCHEME, class T, class U>
inline void
TopologyRefiner::limit(T const & src, U * dst) const {
//
// Work in progress...
// - does not support tangents yet (unclear how)
// - need to verify that each vertex is "limitable", i.e.:
// - is not semi-sharp, inf-sharp or non-manifold
// - is "complete" wrt its parent (if refinement is sparse)
// - copy (or weight by 1.0) src to dst when not "limitable"
// - currently requires one refinement to get rid of N-sided faces:
// - could limit regular vertices from level 0
//
Sdc::Scheme<SCHEME> scheme(_subdivOptions);
Vtr::Level const & level = getLevel(GetMaxLevel());
int maxWeightsPerMask = 1 + 2 * level.getMaxValence();
float * weightBuffer = (float *)alloca(maxWeightsPerMask * sizeof(float));
// This is a bit obscure -- assign both parent and child as last level
Vtr::VertexInterface vHood(level, level);
for (int vert = 0; vert < level.getNumVertices(); ++vert) {
ConstIndexArray vEdges = level.getVertexEdges(vert);
float * vWeights = weightBuffer,
* eWeights = vWeights + 1,
* fWeights = eWeights + vEdges.size();
Vtr::MaskInterface vMask(vWeights, eWeights, fWeights);
// This is a bit obscure -- child vertex index will be ignored here
vHood.SetIndex(vert, vert);
scheme.ComputeVertexLimitMask(vHood, vMask);
// Apply the weights to the vertex, the vertices opposite its incident
// edges, and the opposite vertices of its incident faces:
//
// As with applying refinment masks to vertex data, in order to improve
// numerical precision, its better to apply smaller weights first, so
// begin with the face-weights followed by the edge-weights and the vertex
// weight last.
dst[vert].Clear();
if (vMask.GetNumFaceWeights() > 0) {
assert(!vMask.AreFaceWeightsForFaceCenters());
ConstIndexArray vFaces = level.getVertexFaces(vert);
ConstLocalIndexArray vInFace = level.getVertexFaceLocalIndices(vert);
for (int i = 0; i < vFaces.size(); ++i) {
ConstIndexArray fVerts = level.getFaceVertices(vFaces[i]);
LocalIndex vOppInFace = (vInFace[i] + 2);
if (vOppInFace >= fVerts.size()) vOppInFace -= (LocalIndex)fVerts.size();
Index vertOppositeFace = level.getFaceVertices(vFaces[i])[vOppInFace];
dst[vert].AddWithWeight(src[vertOppositeFace], fWeights[i]);
}
}
if (vMask.GetNumEdgeWeights() > 0) {
for (int i = 0; i < vEdges.size(); ++i) {
ConstIndexArray eVerts = level.getEdgeVertices(vEdges[i]);
Index vertOppositeEdge = (eVerts[0] == vert) ? eVerts[1] : eVerts[0];
dst[vert].AddWithWeight(src[vertOppositeEdge], eWeights[i]);
}
}
dst[vert].AddWithWeight(src[vert], vWeights[0]);
}
}
template <class T, class U>
inline void
TopologyRefiner::LimitFaceVarying(T const & src, U * dst, int channel) const {
assert(GetMaxLevel() > 0);
switch (_subdivType) {
case Sdc::TYPE_CATMARK:
faceVaryingLimit<Sdc::TYPE_CATMARK>(src, dst, channel);
break;
case Sdc::TYPE_LOOP:
faceVaryingLimit<Sdc::TYPE_LOOP>(src, dst, channel);
break;
case Sdc::TYPE_BILINEAR:
faceVaryingLimit<Sdc::TYPE_BILINEAR>(src, dst, channel);
break;
}
}
template <Sdc::Type SCHEME, class T, class U>
inline void
TopologyRefiner::faceVaryingLimit(T const & src, U * dst, int channel) const {
Sdc::Scheme<SCHEME> scheme(_subdivOptions);
Vtr::Level const & level = getLevel(GetMaxLevel());
Vtr::FVarLevel const & fvarChannel = *level._fvarChannels[channel];
int maxWeightsPerMask = 1 + 2 * level.getMaxValence();
float * weightBuffer = (float *)alloca(maxWeightsPerMask * sizeof(float));
Index * indexBuffer = (Index *)alloca(level.getMaxValence() * sizeof(Index));
// This is a bit obscure -- assign both parent and child as last level
Vtr::VertexInterface vHood(level, level);
for (int vert = 0; vert < level.getNumVertices(); ++vert) {
ConstIndexArray vValues = fvarChannel.getVertexValues(vert);
bool fvarVertMatchesVertex = fvarChannel.valueTopologyMatches(vValues[0]);
if (fvarChannel._isLinear && fvarVertMatchesVertex) {
Vtr::Index srcValueIndex = fvarChannel.getVertexValue(vert);
Vtr::Index dstValueIndex = vValues[0];
dst[dstValueIndex].Clear();
dst[dstValueIndex].AddWithWeight(src[srcValueIndex], 1.0f);
} else if (fvarVertMatchesVertex) {
//
// Compute the limit mask based on vertex topology:
//
ConstIndexArray vEdges = level.getVertexEdges(vert);
float * vWeights = weightBuffer,
* eWeights = vWeights + 1,
* fWeights = eWeights + vEdges.size();
Vtr::MaskInterface vMask(vWeights, eWeights, fWeights);
vHood.SetIndex(vert, vert);
scheme.ComputeVertexLimitMask(vHood, vMask);
//
// Apply mask to corresponding FVar values for neighboring vertices:
//
Vtr::Index vValue = vValues[0];
dst[vValue].Clear();
if (vMask.GetNumFaceWeights() > 0) {
assert(!vMask.AreFaceWeightsForFaceCenters());
ConstIndexArray vFaces = level.getVertexFaces(vert);
ConstLocalIndexArray vInFace = level.getVertexFaceLocalIndices(vert);
for (int i = 0; i < vFaces.size(); ++i) {
ConstIndexArray faceValues = fvarChannel.getFaceValues(vFaces[i]);
LocalIndex vOppInFace = vInFace[i] + 2;
if (vOppInFace >= faceValues.size()) vOppInFace -= faceValues.size();
Index vValueOppositeFace = faceValues[vOppInFace];
dst[vValue].AddWithWeight(src[vValueOppositeFace], fWeights[i]);
}
}
if (vMask.GetNumEdgeWeights() > 0) {
Index * vEdgeValues = indexBuffer;
fvarChannel.getVertexEdgeValues(vert, vEdgeValues);
for (int i = 0; i < vEdges.size(); ++i) {
dst[vValue].AddWithWeight(src[vEdgeValues[i]], eWeights[i]);
}
}
dst[vValue].AddWithWeight(src[vValue], vWeights[0]);
} else {
//
// Sibling FVar values associated with a vertex will be either a corner or a crease:
//
for (int i = 0; i < vValues.size(); ++i) {
Vtr::Index vValue = vValues[i];
dst[vValue].Clear();
if (fvarChannel.getValueTag(vValue).isCorner()) {
dst[vValue].AddWithWeight(src[vValue], 1.0f);
} else {
Index vEndValues[2];
fvarChannel.getVertexCreaseEndValues(vert, i, vEndValues);
dst[vValue].AddWithWeight(src[vEndValues[0]], 1.0f/6.0f);
dst[vValue].AddWithWeight(src[vEndValues[1]], 1.0f/6.0f);
dst[vValue].AddWithWeight(src[vValue], 2.0f/3.0f);
}
}
}
}
}
} // end namespace Far
} // end namespace OPENSUBDIV_VERSION
using namespace OPENSUBDIV_VERSION;
} // end namespace OpenSubdiv
#endif /* FAR_TOPOLOGY_REFINER_H */