// // Copyright 2013 Pixar // // 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 OPENSUBDIV3_FAR_PATCH_TABLE_H #define OPENSUBDIV3_FAR_PATCH_TABLE_H #include "../version.h" #include "../far/patchDescriptor.h" #include "../far/patchParam.h" #include "../far/stencilTable.h" #include "../sdc/options.h" #include namespace OpenSubdiv { namespace OPENSUBDIV_VERSION { namespace Far { /// \brief Container for arrays of parametric patches /// /// PatchTable contains topology and parametric information about the patches /// generated by the Refinement process. Patches in the table are sorted into /// arrays based on their PatchDescriptor Type. /// /// Note : PatchTable can be accessed either using a PatchHandle or a /// combination of array and patch indices. /// /// XXXX manuelk we should add a PatchIterator that can dereference into /// a PatchHandle for fast linear traversal of the table /// class PatchTable { public: /// \brief Handle that can be used as unique patch identifier within PatchTable class PatchHandle { // XXXX manuelk members will eventually be made private public: friend class PatchTable; friend class PatchMap; Index arrayIndex, // Array index of the patch patchIndex, // Absolute Index of the patch vertIndex; // Relative offset to the first CV of the patch in array }; public: /// \brief Copy constructor PatchTable(PatchTable const & src); /// \brief Destructor ~PatchTable(); /// \brief True if the patches are of feature adaptive types bool IsFeatureAdaptive() const; /// \brief Returns the total number of control vertex indices in the table int GetNumControlVerticesTotal() const { return (int)_patchVerts.size(); } /// \brief Returns the total number of patches stored in the table int GetNumPatchesTotal() const; /// \brief Returns max vertex valence int GetMaxValence() const { return _maxValence; } /// \brief Returns the total number of ptex faces in the mesh int GetNumPtexFaces() const { return _numPtexFaces; } //@{ /// @name Individual patches /// /// \anchor individual_patches /// /// \brief Accessors for individual patches /// /// \brief Returns the PatchDescriptor for the patch identified by \p handle PatchDescriptor GetPatchDescriptor(PatchHandle const & handle) const; /// \brief Returns the control vertex indices for the patch identified by \p handle ConstIndexArray GetPatchVertices(PatchHandle const & handle) const; /// \brief Returns a PatchParam for the patch identified by \p handle PatchParam GetPatchParam(PatchHandle const & handle) const; /// \brief Returns the control vertex indices for \p patch in \p array ConstIndexArray GetPatchVertices(int array, int patch) const; /// \brief Returns the PatchParam for \p patch in \p array PatchParam GetPatchParam(int array, int patch) const; //@} //@{ /// @name Arrays of patches /// /// \anchor arrays_of_patches /// /// \brief Accessors for arrays of patches of the same type /// /// \brief Returns the number of patch arrays in the table int GetNumPatchArrays() const; /// \brief Returns the number of patches in \p array int GetNumPatches(int array) const; /// \brief Returns the number of control vertices in \p array int GetNumControlVertices(int array) const; /// \brief Returns the PatchDescriptor for the patches in \p array PatchDescriptor GetPatchArrayDescriptor(int array) const; /// \brief Returns the control vertex indices for the patches in \p array ConstIndexArray GetPatchArrayVertices(int array) const; /// \brief Returns the PatchParams for the patches in \p array ConstPatchParamArray const GetPatchParams(int array) const; //@} //@{ /// @name Change of basis patches /// /// \anchor change_of_basis_patches /// /// \brief Accessors for change of basis patches /// /// /// \brief Returns the number of local vertex points. int GetNumLocalPoints() const; /// \brief Returns the stencil table to compute local point vertex values StencilTable const *GetLocalPointStencilTable() const; /// \brief Returns the stencil table to compute local point vertex values template StencilTableReal const *GetLocalPointStencilTable() const; /// \brief Tests if the precision of the stencil table to compute local point /// vertex values matches the given floating point type \. template bool LocalPointStencilPrecisionMatchesType() const; /// \brief Updates local point vertex values. /// /// @param src Buffer with primvar data for the base and refined /// vertex values /// /// @param dst Destination buffer for the computed local point /// vertex values /// /// For more flexibility computing local vertex points, retrieval of /// the local point stencil table and use of its public methods is /// recommended or often required. /// template void ComputeLocalPointValues(T const *src, T *dst) const; /// \brief Returns the number of local varying points. int GetNumLocalPointsVarying() const; /// \brief Returns the stencil table to compute local point varying values StencilTable const *GetLocalPointVaryingStencilTable() const; /// \brief Returns the stencil table to compute local point varying values template StencilTableReal const *GetLocalPointVaryingStencilTable() const; /// \brief Tests if the precision of the stencil table to compute local point /// varying values matches the given floating point type \. template bool LocalPointVaryingStencilPrecisionMatchesType() const; /// \brief Updates local point varying values. /// /// @param src Buffer with primvar data for the base and refined /// varying values /// /// @param dst Destination buffer for the computed local point /// varying values /// /// For more flexibility computing local varying points, retrieval of /// the local point varying stencil table and use of its public methods /// is recommended or often required. /// template void ComputeLocalPointValuesVarying(T const *src, T *dst) const; /// \brief Returns the number of local face-varying points for \p channel int GetNumLocalPointsFaceVarying(int channel = 0) const; /// \brief Returns the stencil table to compute local point face-varying values StencilTable const *GetLocalPointFaceVaryingStencilTable(int channel = 0) const; /// \brief Returns the stencil table to compute local point face-varying values template StencilTableReal const * GetLocalPointFaceVaryingStencilTable(int channel = 0) const; /// \brief Tests if the precision of the stencil table to compute local point /// face-varying values matches the given floating point type \. template bool LocalPointFaceVaryingStencilPrecisionMatchesType() const; /// \brief Updates local point face-varying values. /// /// @param src Buffer with primvar data for the base and refined /// face-varying values /// /// @param dst Destination buffer for the computed local point /// face-varying values /// /// @param channel face-varying channel /// /// For more flexibility computing local face-varying points, retrieval /// of the local point face-varying stencil table and use of its public /// methods is recommended or often required. /// template void ComputeLocalPointValuesFaceVarying(T const *src, T *dst, int channel = 0) const; //@} //@{ /// @name Legacy gregory patch evaluation buffers /// \brief Accessors for the gregory patch evaluation buffers. /// These methods will be deprecated. /// typedef Vtr::ConstArray ConstQuadOffsetsArray; /// \brief Returns the 'QuadOffsets' for the Gregory patch identified by \p handle ConstQuadOffsetsArray GetPatchQuadOffsets(PatchHandle const & handle) const; typedef std::vector VertexValenceTable; /// \brief Returns the 'VertexValences' table (vertex neighborhoods table) VertexValenceTable const & GetVertexValenceTable() const { return _vertexValenceTable; } //@} //@{ /// @name Single-crease patches /// /// \anchor single_crease_patches /// /// \brief Accessors for single-crease patch edge sharpness /// /// \brief Returns the crease sharpness for the patch identified by \p handle /// if it is a single-crease patch, or 0.0f float GetSingleCreasePatchSharpnessValue(PatchHandle const & handle) const; /// \brief Returns the crease sharpness for the \p patch in \p array /// if it is a single-crease patch, or 0.0f float GetSingleCreasePatchSharpnessValue(int array, int patch) const; //@} //@{ /// @name Varying data /// /// \anchor varying_data /// /// \brief Accessors for varying data /// /// \brief Returns the varying patch descriptor PatchDescriptor GetVaryingPatchDescriptor() const; /// \brief Returns the varying vertex indices for a given patch ConstIndexArray GetPatchVaryingVertices(PatchHandle const & handle) const; /// \brief Returns the varying vertex indices for a given patch ConstIndexArray GetPatchVaryingVertices(int array, int patch) const; /// \brief Returns the varying vertex indices for the patches in \p array ConstIndexArray GetPatchArrayVaryingVertices(int array) const; /// \brief Returns an array of varying vertex indices for the patches. ConstIndexArray GetVaryingVertices() const; //@} //@{ /// @name Face-varying channels /// /// \anchor face_varying_channels /// /// \brief Accessors for face-varying channels /// /// \brief Returns the number of face-varying channels int GetNumFVarChannels() const; /// \brief Returns the regular patch descriptor for \p channel PatchDescriptor GetFVarPatchDescriptorRegular(int channel = 0) const; /// \brief Returns the irregular patch descriptor for \p channel PatchDescriptor GetFVarPatchDescriptorIrregular(int channel = 0) const; /// \brief Returns the default/irregular patch descriptor for \p channel PatchDescriptor GetFVarPatchDescriptor(int channel = 0) const; /// \brief Returns the value indices for a given patch in \p channel ConstIndexArray GetPatchFVarValues(PatchHandle const & handle, int channel = 0) const; /// \brief Returns the value indices for a given patch in \p channel ConstIndexArray GetPatchFVarValues(int array, int patch, int channel = 0) const; /// \brief Returns the value indices for the patches in \p array in \p channel ConstIndexArray GetPatchArrayFVarValues(int array, int channel = 0) const; /// \brief Returns an array of value indices for the patches in \p channel ConstIndexArray GetFVarValues(int channel = 0) const; /// \brief Returns the stride between patches in the value index array of \p channel int GetFVarValueStride(int channel = 0) const; /// \brief Returns the value indices for a given patch in \p channel PatchParam GetPatchFVarPatchParam(PatchHandle const & handle, int channel = 0) const; /// \brief Returns the face-varying params for a given patch \p channel PatchParam GetPatchFVarPatchParam(int array, int patch, int channel = 0) const; /// \brief Returns the face-varying for a given patch in \p array in \p channel ConstPatchParamArray GetPatchArrayFVarPatchParams(int array, int channel = 0) const; /// \brief Returns an array of face-varying patch param for \p channel ConstPatchParamArray GetFVarPatchParams(int channel = 0) const; /// \brief Deprecated @see PatchTable#GetFVarPatchDescriptor Sdc::Options::FVarLinearInterpolation GetFVarChannelLinearInterpolation(int channel = 0) const; //@} //@{ /// @name Direct accessors /// /// \warning These direct accessors are left for convenience, but they are /// likely going to be deprecated in future releases /// typedef std::vector PatchVertsTable; /// \brief Get the table of patch control vertices PatchVertsTable const & GetPatchControlVerticesTable() const { return _patchVerts; } /// \brief Returns the PatchParamTable (PatchParams order matches patch array sorting) PatchParamTable const & GetPatchParamTable() const { return _paramTable; } /// \brief Returns a sharpness index table for each patch (if exists) std::vector const &GetSharpnessIndexTable() const { return _sharpnessIndices; } /// \brief Returns sharpness values table std::vector const &GetSharpnessValues() const { return _sharpnessValues; } typedef std::vector QuadOffsetsTable; /// \brief Returns the quad-offsets table QuadOffsetsTable const & GetQuadOffsetsTable() const { return _quadOffsetsTable; } //@} /// debug helper void print() const; public: //@{ /// @name Evaluation methods /// /// \brief Evaluate basis functions for position and derivatives at a /// given (u,v) parametric location of a patch. /// /// @param handle A patch handle identifying the sub-patch containing the /// (u,v) location /// /// @param u Patch coordinate (in base face normalized space) /// /// @param v Patch coordinate (in base face normalized space) /// /// @param wP Weights (evaluated basis functions) for the position /// /// @param wDu Weights (evaluated basis functions) for derivative wrt u /// /// @param wDv Weights (evaluated basis functions) for derivative wrt v /// /// @param wDuu Weights (evaluated basis functions) for 2nd derivative wrt u /// /// @param wDuv Weights (evaluated basis functions) for 2nd derivative wrt u and v /// /// @param wDvv Weights (evaluated basis functions) for 2nd derivative wrt v /// template void EvaluateBasis(PatchHandle const & handle, REAL u, REAL v, REAL wP[], REAL wDu[] = 0, REAL wDv[] = 0, REAL wDuu[] = 0, REAL wDuv[] = 0, REAL wDvv[] = 0) const; /// \brief An overloaded version to assist template parameter resolution /// when explicitly declaring unused array arguments as 0. void EvaluateBasis(PatchHandle const & handle, float u, float v, float wP[], float wDu[] = 0, float wDv[] = 0, float wDuu[] = 0, float wDuv[] = 0, float wDvv[] = 0) const; /// \brief An overloaded version to assist template parameter resolution /// when explicitly declaring unused array arguments as 0. void EvaluateBasis(PatchHandle const & handle, double u, double v, double wP[], double wDu[] = 0, double wDv[] = 0, double wDuu[] = 0, double wDuv[] = 0, double wDvv[] = 0) const; /// \brief Evaluate basis functions for a varying value and /// derivatives at a given (u,v) parametric location of a patch. /// /// @param handle A patch handle identifying the sub-patch containing the /// (u,v) location /// /// @param u Patch coordinate (in base face normalized space) /// /// @param v Patch coordinate (in base face normalized space) /// /// @param wP Weights (evaluated basis functions) for the position /// /// @param wDu Weights (evaluated basis functions) for derivative wrt u /// /// @param wDv Weights (evaluated basis functions) for derivative wrt v /// /// @param wDuu Weights (evaluated basis functions) for 2nd derivative wrt u /// /// @param wDuv Weights (evaluated basis functions) for 2nd derivative wrt u and v /// /// @param wDvv Weights (evaluated basis functions) for 2nd derivative wrt v /// template void EvaluateBasisVarying(PatchHandle const & handle, REAL u, REAL v, REAL wP[], REAL wDu[] = 0, REAL wDv[] = 0, REAL wDuu[] = 0, REAL wDuv[] = 0, REAL wDvv[] = 0) const; /// \brief An overloaded version to assist template parameter resolution /// when explicitly declaring unused array arguments as 0. void EvaluateBasisVarying(PatchHandle const & handle, float u, float v, float wP[], float wDu[] = 0, float wDv[] = 0, float wDuu[] = 0, float wDuv[] = 0, float wDvv[] = 0) const; /// \brief An overloaded version to assist template parameter resolution /// when explicitly declaring unused array arguments as 0. void EvaluateBasisVarying(PatchHandle const & handle, double u, double v, double wP[], double wDu[] = 0, double wDv[] = 0, double wDuu[] = 0, double wDuv[] = 0, double wDvv[] = 0) const; /// \brief Evaluate basis functions for a face-varying value and /// derivatives at a given (u,v) parametric location of a patch. /// /// @param handle A patch handle identifying the sub-patch containing the /// (u,v) location /// /// @param u Patch coordinate (in base face normalized space) /// /// @param v Patch coordinate (in base face normalized space) /// /// @param wP Weights (evaluated basis functions) for the position /// /// @param wDu Weights (evaluated basis functions) for derivative wrt u /// /// @param wDv Weights (evaluated basis functions) for derivative wrt v /// /// @param wDuu Weights (evaluated basis functions) for 2nd derivative wrt u /// /// @param wDuv Weights (evaluated basis functions) for 2nd derivative wrt u and v /// /// @param wDvv Weights (evaluated basis functions) for 2nd derivative wrt v /// /// @param channel face-varying channel /// template void EvaluateBasisFaceVarying(PatchHandle const & handle, REAL u, REAL v, REAL wP[], REAL wDu[] = 0, REAL wDv[] = 0, REAL wDuu[] = 0, REAL wDuv[] = 0, REAL wDvv[] = 0, int channel = 0) const; /// \brief An overloaded version to assist template parameter resolution /// when explicitly declaring unused array arguments as 0. void EvaluateBasisFaceVarying(PatchHandle const & handle, float u, float v, float wP[], float wDu[] = 0, float wDv[] = 0, float wDuu[] = 0, float wDuv[] = 0, float wDvv[] = 0, int channel = 0) const; /// \brief An overloaded version to assist template parameter resolution /// when explicitly declaring unused array arguments as 0. void EvaluateBasisFaceVarying(PatchHandle const & handle, double u, double v, double wP[], double wDu[] = 0, double wDv[] = 0, double wDuu[] = 0, double wDuv[] = 0, double wDvv[] = 0, int channel = 0) const; //@} protected: friend class PatchTableBuilder; // Factory constructor PatchTable(int maxvalence); Index getPatchIndex(int array, int patch) const; PatchParamArray getPatchParams(int arrayIndex); Index * getSharpnessIndices(Index arrayIndex); float * getSharpnessValues(Index arrayIndex); private: // // Patch arrays // struct PatchArray; typedef std::vector PatchArrayVector; PatchArray & getPatchArray(Index arrayIndex); PatchArray const & getPatchArray(Index arrayIndex) const; void reservePatchArrays(int numPatchArrays); void pushPatchArray(PatchDescriptor desc, int npatches, Index * vidx, Index * pidx, Index * qoidx=0); IndexArray getPatchArrayVertices(int arrayIndex); Index findPatchArray(PatchDescriptor desc); // // Varying patch arrays // IndexArray getPatchArrayVaryingVertices(int arrayIndex); void allocateVaryingVertices( PatchDescriptor desc, int numPatches); void populateVaryingVertices(); // // Face-varying patch channels // struct FVarPatchChannel; typedef std::vector FVarPatchChannelVector; FVarPatchChannel & getFVarPatchChannel(int channel); FVarPatchChannel const & getFVarPatchChannel(int channel) const; void allocateFVarPatchChannels(int numChannels); void allocateFVarPatchChannelValues( PatchDescriptor regDesc, PatchDescriptor irregDesc, int numPatches, int channel); // deprecated void setFVarPatchChannelLinearInterpolation( Sdc::Options::FVarLinearInterpolation interpolation, int channel); IndexArray getFVarValues(int channel); ConstIndexArray getPatchFVarValues(int patch, int channel) const; PatchParamArray getFVarPatchParams(int channel); PatchParam getPatchFVarPatchParam(int patch, int channel) const; private: // // Simple private class to hold stencil table pointers of varying precision, // where the discriminant of the precision is external. // // NOTE that this is a simple pointer container and NOT a smart pointer that // manages the ownership of the object referred to by it. // class StencilTablePtr { private: typedef StencilTableReal float_type; typedef StencilTableReal double_type; union { float_type * _fPtr; double_type * _dPtr; }; public: StencilTablePtr() { _fPtr = 0; } StencilTablePtr(float_type * ptr) { _fPtr = ptr; } StencilTablePtr(double_type * ptr) { _dPtr = ptr; } operator bool() const { return _fPtr != 0; } void Set() { _fPtr = 0; } void Set(float_type * ptr) { _fPtr = ptr; } void Set(double_type * ptr) { _dPtr = ptr; } template StencilTableReal * Get() const; }; private: // // Topology // int _maxValence, // highest vertex valence found in the mesh _numPtexFaces; // total number of ptex faces PatchArrayVector _patchArrays; // Vector of descriptors for arrays of patches std::vector _patchVerts; // Indices of the control vertices of the patches PatchParamTable _paramTable; // PatchParam bitfields (one per patch) // // Extraordinary vertex closed-form evaluation / endcap basis conversion // // XXXtakahito: these data will probably be replaced with mask coefficient or something // SchemeWorker populates. // QuadOffsetsTable _quadOffsetsTable; // Quad offsets (for Gregory patches) VertexValenceTable _vertexValenceTable; // Vertex valence table (for Gregory patches) StencilTablePtr _localPointStencils; // local point conversion stencils StencilTablePtr _localPointVaryingStencils; // local point varying stencils // // Varying data // PatchDescriptor _varyingDesc; std::vector _varyingVerts; // // Face-varying data // FVarPatchChannelVector _fvarChannels; std::vector _localPointFaceVaryingStencils; // // 'single-crease' patch sharpness tables // std::vector _sharpnessIndices; // Indices of single-crease sharpness (one per patch) std::vector _sharpnessValues; // Sharpness values. // // Construction history -- relevant to at least one public query: // unsigned int _isUniformLinear : 1; // // Precision -- only applies to local-point stencil tables // unsigned int _vertexPrecisionIsDouble : 1; unsigned int _varyingPrecisionIsDouble : 1; unsigned int _faceVaryingPrecisionIsDouble : 1; }; // // Template specializations for float/double -- to be defined before used: // template <> inline StencilTableReal * PatchTable::StencilTablePtr::Get() const { return _fPtr; } template <> inline StencilTableReal * PatchTable::StencilTablePtr::Get() const { return _dPtr; } template <> inline bool PatchTable::LocalPointStencilPrecisionMatchesType() const { return !_vertexPrecisionIsDouble; } template <> inline bool PatchTable::LocalPointVaryingStencilPrecisionMatchesType() const { return !_varyingPrecisionIsDouble; } template <> inline bool PatchTable::LocalPointFaceVaryingStencilPrecisionMatchesType() const { return !_faceVaryingPrecisionIsDouble; } template <> inline bool PatchTable::LocalPointStencilPrecisionMatchesType() const { return _vertexPrecisionIsDouble; } template <> inline bool PatchTable::LocalPointVaryingStencilPrecisionMatchesType() const { return _varyingPrecisionIsDouble; } template <> inline bool PatchTable::LocalPointFaceVaryingStencilPrecisionMatchesType() const { return _faceVaryingPrecisionIsDouble; } // // StencilTable access -- backward compatible and generic: // inline StencilTable const * PatchTable::GetLocalPointStencilTable() const { assert(LocalPointStencilPrecisionMatchesType()); return static_cast(_localPointStencils.Get()); } inline StencilTable const * PatchTable::GetLocalPointVaryingStencilTable() const { assert(LocalPointVaryingStencilPrecisionMatchesType()); return static_cast( _localPointVaryingStencils.Get()); } inline StencilTable const * PatchTable::GetLocalPointFaceVaryingStencilTable(int channel) const { assert(LocalPointFaceVaryingStencilPrecisionMatchesType()); if (channel >= 0 && channel < (int)_localPointFaceVaryingStencils.size()) { return static_cast( _localPointFaceVaryingStencils[channel].Get()); } return NULL; } template inline StencilTableReal const * PatchTable::GetLocalPointStencilTable() const { assert(LocalPointStencilPrecisionMatchesType()); return _localPointStencils.Get(); } template inline StencilTableReal const * PatchTable::GetLocalPointVaryingStencilTable() const { assert(LocalPointVaryingStencilPrecisionMatchesType()); return _localPointVaryingStencils.Get(); } template inline StencilTableReal const * PatchTable::GetLocalPointFaceVaryingStencilTable(int channel) const { assert(LocalPointFaceVaryingStencilPrecisionMatchesType()); if (channel >= 0 && channel < (int)_localPointFaceVaryingStencils.size()) { return _localPointFaceVaryingStencils[channel].Get(); } return NULL; } // // Computation of local point values: // template inline void PatchTable::ComputeLocalPointValues(T const *src, T *dst) const { assert(LocalPointStencilPrecisionMatchesType()); if (_localPointStencils) { _localPointStencils.Get()->UpdateValues(src, dst); } } template inline void PatchTable::ComputeLocalPointValuesVarying(T const *src, T *dst) const { assert(LocalPointVaryingStencilPrecisionMatchesType()); if (_localPointVaryingStencils) { _localPointVaryingStencils.Get()->UpdateValues(src, dst); } } template inline void PatchTable::ComputeLocalPointValuesFaceVarying(T const *src, T *dst, int channel) const { assert(LocalPointFaceVaryingStencilPrecisionMatchesType()); if (channel >= 0 && channel < (int)_localPointFaceVaryingStencils.size()) { if (_localPointFaceVaryingStencils[channel]) { _localPointFaceVaryingStencils[channel].Get()->UpdateValues(src, dst); } } } // // Basis evaluation overloads // inline void PatchTable::EvaluateBasis(PatchHandle const & handle, float u, float v, float wP[], float wDu[], float wDv[], float wDuu[], float wDuv[], float wDvv[]) const { EvaluateBasis(handle, u, v, wP, wDu, wDv, wDuu, wDuv, wDvv); } inline void PatchTable::EvaluateBasis(PatchHandle const & handle, double u, double v, double wP[], double wDu[], double wDv[], double wDuu[], double wDuv[], double wDvv[]) const { EvaluateBasis(handle, u, v, wP, wDu, wDv, wDuu, wDuv, wDvv); } inline void PatchTable::EvaluateBasisVarying(PatchHandle const & handle, float u, float v, float wP[], float wDu[], float wDv[], float wDuu[], float wDuv[], float wDvv[]) const { EvaluateBasisVarying(handle, u, v, wP, wDu, wDv, wDuu, wDuv, wDvv); } inline void PatchTable::EvaluateBasisVarying(PatchHandle const & handle, double u, double v, double wP[], double wDu[], double wDv[], double wDuu[], double wDuv[], double wDvv[]) const { EvaluateBasisVarying(handle, u, v, wP, wDu, wDv, wDuu, wDuv, wDvv); } inline void PatchTable::EvaluateBasisFaceVarying(PatchHandle const & handle, float u, float v, float wP[], float wDu[], float wDv[], float wDuu[], float wDuv[], float wDvv[], int channel) const { EvaluateBasisFaceVarying(handle, u, v, wP, wDu, wDv, wDuu, wDuv, wDvv, channel); } inline void PatchTable::EvaluateBasisFaceVarying(PatchHandle const & handle, double u, double v, double wP[], double wDu[], double wDv[], double wDuu[], double wDuv[], double wDvv[], int channel) const { EvaluateBasisFaceVarying(handle, u, v, wP, wDu, wDv, wDuu, wDuv, wDvv, channel); } } // end namespace Far } // end namespace OPENSUBDIV_VERSION using namespace OPENSUBDIV_VERSION; } // end namespace OpenSubdiv #endif /* OPENSUBDIV3_FAR_PATCH_TABLE */