//============================================================================ // Copyright (c) Kitware, Inc. // All rights reserved. // See LICENSE.txt for details. // // This software is distributed WITHOUT ANY WARRANTY; without even // the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR // PURPOSE. See the above copyright notice for more information. //============================================================================ #ifndef vtk_m_filter_particle_density_cic_hxx #define vtk_m_filter_particle_density_cic_hxx #include #include #include #include #include namespace vtkm { namespace worklet { class CICWorklet : public vtkm::worklet::WorkletMapField { public: using ControlSignature = void(FieldIn coords, FieldIn field, ExecObject locator, WholeCellSetIn cellSet, AtomicArrayInOut density); using ExecutionSignature = void(_1, _2, _3, _4, _5); template VTKM_EXEC void operator()(const Point& point, const T value, const CellLocatorExecObj& locator, const CellSet& cellSet, AtomicArray& density) const { vtkm::Id cellId{}; vtkm::Vec3f parametric; if (locator.FindCell(point, cellId, parametric) == vtkm::ErrorCode::Success) { // iterate through all the points of the cell and deposit with correct weight. auto indices = cellSet.GetIndices(cellId); auto rparametric = vtkm::Vec3f{ 1, 1, 1 } - parametric; // deposit the scalar field value in proportion to the volume of the sub-hexahedron // the vertex is in. density.Add(indices[0], value * parametric[0] * parametric[1] * parametric[2]); density.Add(indices[1], value * rparametric[0] * parametric[1] * parametric[2]); density.Add(indices[2], value * rparametric[0] * rparametric[1] * parametric[2]); density.Add(indices[3], value * parametric[0] * rparametric[1] * parametric[2]); density.Add(indices[4], value * parametric[0] * parametric[1] * rparametric[2]); density.Add(indices[5], value * rparametric[0] * parametric[1] * rparametric[2]); density.Add(indices[6], value * rparametric[0] * rparametric[1] * rparametric[2]); density.Add(indices[7], value * parametric[0] * rparametric[1] * rparametric[2]); } // We simply ignore that particular particle when it is not in the mesh. } }; } // worklet } // vtkm namespace vtkm { namespace filter { inline VTKM_CONT ParticleDensityCloudInCell::ParticleDensityCloudInCell(const vtkm::Id3& dimension, const vtkm::Vec3f& origin, const vtkm::Vec3f& spacing) : Superclass(dimension, origin, spacing) { } inline VTKM_CONT ParticleDensityCloudInCell::ParticleDensityCloudInCell(const Id3& dimension, const vtkm::Bounds& bounds) : Superclass(dimension, bounds) { } template inline VTKM_CONT vtkm::cont::DataSet ParticleDensityCloudInCell::DoExecute( const cont::DataSet& dataSet, const cont::ArrayHandle& field, const vtkm::filter::FieldMetadata&, PolicyBase) { // Unlike ParticleDensityNGP, particle deposit mass on the grid points, thus it is natural to // return the density as PointField; auto uniform = vtkm::cont::DataSetBuilderUniform::Create( this->Dimension + vtkm::Id3{ 1, 1, 1 }, this->Origin, this->Spacing); vtkm::cont::CellLocatorUniformGrid locator; locator.SetCellSet(uniform.GetCellSet()); locator.SetCoordinates(uniform.GetCoordinateSystem()); locator.Update(); auto coords = dataSet.GetCoordinateSystem().GetDataAsMultiplexer(); vtkm::cont::ArrayHandle density; vtkm::cont::ArrayCopy(vtkm::cont::ArrayHandleConstant(0, uniform.GetNumberOfPoints()), density); this->Invoke(vtkm::worklet::CICWorklet{}, coords, field, locator, uniform.GetCellSet().template Cast>(), density); if (DivideByVolume) { auto volume = this->Spacing[0] * this->Spacing[1] * this->Spacing[2]; this->Invoke(DivideByVolumeWorklet{ volume }, density); } uniform.AddField(vtkm::cont::make_FieldPoint("density", density)); return uniform; } } } #endif // vtk_m_filter_particle_density_cic_hxx