mirror of
https://gitlab.kitware.com/vtk/vtk-m
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8859636672
VTK-m has been updated to replace old per device worklet testing executables with a device dependent shared library so that it's able to accept a device adapter at runtime. Meanwhile, it updates the testing infrastructure APIs. vtkm::cont::testing::Run function would call ForceDevice when needed and if users need the device adapter info at runtime, RunOnDevice function would pass the adapter into the functor. Optional Parser is bumped from 1.3 to 1.7.
433 lines
16 KiB
C++
433 lines
16 KiB
C++
//============================================================================
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// Copyright (c) Kitware, Inc.
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// All rights reserved.
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// See LICENSE.txt for details.
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// This software is distributed WITHOUT ANY WARRANTY; without even
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// the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
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// PURPOSE. See the above copyright notice for more information.
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//
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// Copyright 2014 National Technology & Engineering Solutions of Sandia, LLC (NTESS).
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// Copyright 2014 UT-Battelle, LLC.
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// Copyright 2014 Los Alamos National Security.
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//
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// Under the terms of Contract DE-NA0003525 with NTESS,
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// the U.S. Government retains certain rights in this software.
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//
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// Under the terms of Contract DE-AC52-06NA25396 with Los Alamos National
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// Laboratory (LANL), the U.S. Government retains certain rights in
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// this software.
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//============================================================================
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#ifndef vtk_m_worklet_StreamLineUniformGrid_h
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#define vtk_m_worklet_StreamLineUniformGrid_h
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#include <vtkm/cont/Algorithm.h>
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#include <vtkm/cont/ArrayHandle.h>
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#include <vtkm/cont/ArrayHandleCounting.h>
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#include <vtkm/cont/CellSetExplicit.h>
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#include <vtkm/cont/CellSetStructured.h>
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#include <vtkm/cont/DataSet.h>
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#include <vtkm/cont/DeviceAdapter.h>
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#include <vtkm/cont/Field.h>
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#include <vtkm/worklet/DispatcherMapField.h>
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#include <vtkm/worklet/ScatterUniform.h>
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#include <vtkm/worklet/WorkletMapField.h>
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namespace vtkm
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{
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// Take this out when defined in CellShape.h
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const vtkm::UInt8 CELL_SHAPE_POLY_LINE = 4;
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namespace worklet
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{
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namespace internal
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{
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enum StreamLineMode
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{
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FORWARD = 0,
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BACKWARD = 1,
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BOTH = 2
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};
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// Trilinear interpolation to calculate vector data at position
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template <typename FieldType, typename PortalType>
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VTKM_EXEC vtkm::Vec<FieldType, 3> VecDataAtPos(vtkm::Vec<FieldType, 3> pos,
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const vtkm::Id3& vdims,
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const vtkm::Id& planesize,
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const vtkm::Id& rowsize,
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const PortalType& vecdata)
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{
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// Adjust initial position to be within bounding box of grid
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for (vtkm::IdComponent d = 0; d < 3; d++)
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{
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if (pos[d] < 0.0f)
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pos[d] = 0.0f;
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if (pos[d] > static_cast<FieldType>(vdims[d] - 1))
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pos[d] = static_cast<FieldType>(vdims[d] - 1);
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}
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// Set the eight corner indices with no wraparound
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vtkm::Id3 idx000, idx001, idx010, idx011, idx100, idx101, idx110, idx111;
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idx000[0] = static_cast<vtkm::Id>(floor(pos[0]));
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idx000[1] = static_cast<vtkm::Id>(floor(pos[1]));
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idx000[2] = static_cast<vtkm::Id>(floor(pos[2]));
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idx001 = idx000;
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idx001[0] = (idx001[0] + 1) <= vdims[0] - 1 ? idx001[0] + 1 : vdims[0] - 1;
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idx010 = idx000;
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idx010[1] = (idx010[1] + 1) <= vdims[1] - 1 ? idx010[1] + 1 : vdims[1] - 1;
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idx011 = idx010;
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idx011[0] = (idx011[0] + 1) <= vdims[0] - 1 ? idx011[0] + 1 : vdims[0] - 1;
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idx100 = idx000;
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idx100[2] = (idx100[2] + 1) <= vdims[2] - 1 ? idx100[2] + 1 : vdims[2] - 1;
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idx101 = idx100;
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idx101[0] = (idx101[0] + 1) <= vdims[0] - 1 ? idx101[0] + 1 : vdims[0] - 1;
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idx110 = idx100;
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idx110[1] = (idx110[1] + 1) <= vdims[1] - 1 ? idx110[1] + 1 : vdims[1] - 1;
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idx111 = idx110;
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idx111[0] = (idx111[0] + 1) <= vdims[0] - 1 ? idx111[0] + 1 : vdims[0] - 1;
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// Get the vecdata at the eight corners
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vtkm::Vec<FieldType, 3> v000, v001, v010, v011, v100, v101, v110, v111;
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v000 = vecdata.Get(idx000[2] * planesize + idx000[1] * rowsize + idx000[0]);
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v001 = vecdata.Get(idx001[2] * planesize + idx001[1] * rowsize + idx001[0]);
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v010 = vecdata.Get(idx010[2] * planesize + idx010[1] * rowsize + idx010[0]);
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v011 = vecdata.Get(idx011[2] * planesize + idx011[1] * rowsize + idx011[0]);
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v100 = vecdata.Get(idx100[2] * planesize + idx100[1] * rowsize + idx100[0]);
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v101 = vecdata.Get(idx101[2] * planesize + idx101[1] * rowsize + idx101[0]);
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v110 = vecdata.Get(idx110[2] * planesize + idx110[1] * rowsize + idx110[0]);
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v111 = vecdata.Get(idx111[2] * planesize + idx111[1] * rowsize + idx111[0]);
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// Interpolation in X
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vtkm::Vec<FieldType, 3> v00, v01, v10, v11;
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FieldType a = pos[0] - static_cast<FieldType>(floor(pos[0]));
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v00[0] = (1.0f - a) * v000[0] + a * v001[0];
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v00[1] = (1.0f - a) * v000[1] + a * v001[1];
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v00[2] = (1.0f - a) * v000[2] + a * v001[2];
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v01[0] = (1.0f - a) * v010[0] + a * v011[0];
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v01[1] = (1.0f - a) * v010[1] + a * v011[1];
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v01[2] = (1.0f - a) * v010[2] + a * v011[2];
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v10[0] = (1.0f - a) * v100[0] + a * v101[0];
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v10[1] = (1.0f - a) * v100[1] + a * v101[1];
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v10[2] = (1.0f - a) * v100[2] + a * v101[2];
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v11[0] = (1.0f - a) * v110[0] + a * v111[0];
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v11[1] = (1.0f - a) * v110[1] + a * v111[1];
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v11[2] = (1.0f - a) * v110[2] + a * v111[2];
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// Interpolation in Y
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vtkm::Vec<FieldType, 3> v0, v1;
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a = pos[1] - static_cast<FieldType>(floor(pos[1]));
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v0[0] = (1.0f - a) * v00[0] + a * v01[0];
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v0[1] = (1.0f - a) * v00[1] + a * v01[1];
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v0[2] = (1.0f - a) * v00[2] + a * v01[2];
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v1[0] = (1.0f - a) * v10[0] + a * v11[0];
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v1[1] = (1.0f - a) * v10[1] + a * v11[1];
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v1[2] = (1.0f - a) * v10[2] + a * v11[2];
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// Interpolation in Z
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vtkm::Vec<FieldType, 3> v;
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a = pos[2] - static_cast<FieldType>(floor(pos[2]));
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v[0] = (1.0f - a) * v0[0] + v1[0];
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v[1] = (1.0f - a) * v0[1] + v1[1];
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v[2] = (1.0f - a) * v0[2] + v1[2];
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return v;
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}
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}
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/// \brief Compute the streamline
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template <typename FieldType, typename DeviceAdapter>
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class StreamLineFilterUniformGrid
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{
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public:
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struct IsUnity
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{
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template <typename T>
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VTKM_EXEC_CONT bool operator()(const T& x) const
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{
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return x == T(1);
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}
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};
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using FieldHandle = vtkm::cont::ArrayHandle<vtkm::Vec<FieldType, 3>>;
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using FieldPortalConstType =
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typename FieldHandle::template ExecutionTypes<DeviceAdapter>::PortalConst;
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class MakeStreamLines : public vtkm::worklet::WorkletMapField
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{
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public:
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using ControlSignature = void(FieldIn<IdType> seedId,
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FieldIn<> position,
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WholeArrayOut<IdComponentType> numIndices,
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WholeArrayOut<IdComponentType> validPoint,
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WholeArrayOut<Vec3> streamLines);
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using ExecutionSignature = void(_1, _2, _3, _4, _5, VisitIndex);
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using InputDomain = _1;
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using ScatterType = vtkm::worklet::ScatterUniform<2>;
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FieldPortalConstType field;
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const vtkm::Id3 vdims;
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const vtkm::Id maxsteps;
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const FieldType timestep;
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const vtkm::Id planesize;
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const vtkm::Id rowsize;
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const vtkm::Id streammode;
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VTKM_CONT
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MakeStreamLines(const FieldType tStep,
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const vtkm::Id sMode,
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const vtkm::Id nSteps,
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const vtkm::Id3 dims,
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FieldPortalConstType fieldArray)
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: field(fieldArray)
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, vdims(dims)
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, maxsteps(nSteps)
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, timestep(tStep)
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, planesize(dims[0] * dims[1])
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, rowsize(dims[0])
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, streammode(sMode)
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{
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}
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template <typename IdComponentPortalType, typename FieldVec3PortalType>
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VTKM_EXEC void operator()(vtkm::Id& seedId,
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vtkm::Vec<FieldType, 3>& seedPos,
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IdComponentPortalType& numIndices,
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IdComponentPortalType& validPoint,
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FieldVec3PortalType& slLists,
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vtkm::IdComponent visitIndex) const
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{
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// Set initial offset into the output streams array
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vtkm::Vec<FieldType, 3> pos = seedPos;
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vtkm::Vec<FieldType, 3> pre_pos = seedPos;
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// Forward tracing
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if (visitIndex == 0 && (streammode == vtkm::worklet::internal::FORWARD ||
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streammode == vtkm::worklet::internal::BOTH))
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{
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vtkm::Id index = (seedId * 2) * maxsteps;
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bool done = false;
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vtkm::Id step = 0;
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validPoint.Set(index, 1);
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slLists.Set(index++, pos);
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while (done != true && step < maxsteps)
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{
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vtkm::Vec<FieldType, 3> vdata, adata, bdata, cdata, ddata;
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vdata = internal::VecDataAtPos<FieldType, FieldPortalConstType>(
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pos, vdims, planesize, rowsize, field);
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for (vtkm::IdComponent d = 0; d < 3; d++)
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{
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adata[d] = timestep * vdata[d];
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pos[d] += adata[d] / 2.0f;
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}
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vdata = internal::VecDataAtPos<FieldType, FieldPortalConstType>(
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pos, vdims, planesize, rowsize, field);
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for (vtkm::IdComponent d = 0; d < 3; d++)
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{
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bdata[d] = timestep * vdata[d];
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pos[d] += bdata[d] / 2.0f;
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}
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vdata = internal::VecDataAtPos<FieldType, FieldPortalConstType>(
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pos, vdims, planesize, rowsize, field);
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for (vtkm::IdComponent d = 0; d < 3; d++)
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{
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cdata[d] = timestep * vdata[d];
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pos[d] += cdata[d] / 2.0f;
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}
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vdata = internal::VecDataAtPos<FieldType, FieldPortalConstType>(
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pos, vdims, planesize, rowsize, field);
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for (vtkm::IdComponent d = 0; d < 3; d++)
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{
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ddata[d] = timestep * vdata[d];
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pos[d] += (adata[d] + (2.0f * bdata[d]) + (2.0f * cdata[d]) + ddata[d]) / 6.0f;
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}
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if (pos[0] < 0.0f || pos[0] > static_cast<FieldType>(vdims[0]) || pos[1] < 0.0f ||
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pos[1] > static_cast<FieldType>(vdims[1]) || pos[2] < 0.0f ||
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pos[2] > static_cast<FieldType>(vdims[2]))
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{
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pos = pre_pos;
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done = true;
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}
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else
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{
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validPoint.Set(index, 1);
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slLists.Set(index++, pos);
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pre_pos = pos;
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}
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step++;
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}
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numIndices.Set(seedId * 2, static_cast<vtkm::IdComponent>(step));
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}
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// Backward tracing
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if (visitIndex == 1 && (streammode == vtkm::worklet::internal::BACKWARD ||
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streammode == vtkm::worklet::internal::BOTH))
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{
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vtkm::Id index = (seedId * 2 + 1) * maxsteps;
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bool done = false;
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vtkm::Id step = 0;
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validPoint.Set(index, 1);
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slLists.Set(index++, pos);
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while (done != true && step < maxsteps)
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{
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vtkm::Vec<FieldType, 3> vdata, adata, bdata, cdata, ddata;
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vdata = internal::VecDataAtPos<FieldType, FieldPortalConstType>(
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pos, vdims, planesize, rowsize, field);
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for (vtkm::IdComponent d = 0; d < 3; d++)
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{
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adata[d] = timestep * (0.0f - vdata[d]);
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pos[d] += adata[d] / 2.0f;
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}
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vdata = internal::VecDataAtPos<FieldType, FieldPortalConstType>(
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pos, vdims, planesize, rowsize, field);
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for (vtkm::IdComponent d = 0; d < 3; d++)
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{
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bdata[d] = timestep * (0.0f - vdata[d]);
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pos[d] += bdata[d] / 2.0f;
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}
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vdata = internal::VecDataAtPos<FieldType, FieldPortalConstType>(
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pos, vdims, planesize, rowsize, field);
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for (vtkm::IdComponent d = 0; d < 3; d++)
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{
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cdata[d] = timestep * (0.0f - vdata[d]);
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pos[d] += cdata[d] / 2.0f;
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}
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vdata = internal::VecDataAtPos<FieldType, FieldPortalConstType>(
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pos, vdims, planesize, rowsize, field);
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for (vtkm::IdComponent d = 0; d < 3; d++)
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{
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ddata[d] = timestep * (0.0f - vdata[d]);
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pos[d] += (adata[d] + (2.0f * bdata[d]) + (2.0f * cdata[d]) + ddata[d]) / 6.0f;
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}
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if (pos[0] < 0.0f || pos[0] > static_cast<FieldType>(vdims[0]) || pos[1] < 0.0f ||
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pos[1] > static_cast<FieldType>(vdims[1]) || pos[2] < 0.0f ||
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pos[2] > static_cast<FieldType>(vdims[2]))
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{
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pos = pre_pos;
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done = true;
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}
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else
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{
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validPoint.Set(index, 1);
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slLists.Set(index++, pos);
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pre_pos = pos;
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}
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step++;
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}
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numIndices.Set((seedId * 2) + 1, static_cast<vtkm::IdComponent>(step));
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}
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}
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};
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StreamLineFilterUniformGrid() {}
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vtkm::cont::DataSet Run(const vtkm::cont::DataSet& InDataSet,
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vtkm::Id streamMode,
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vtkm::Id numSeeds,
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vtkm::Id maxSteps,
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FieldType timeStep)
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{
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using DeviceAlgorithm = vtkm::cont::Algorithm;
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// Get information from input dataset
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vtkm::cont::CellSetStructured<3> inCellSet;
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InDataSet.GetCellSet(0).CopyTo(inCellSet);
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vtkm::Id3 vdims = inCellSet.GetSchedulingRange(vtkm::TopologyElementTagPoint());
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vtkm::cont::ArrayHandle<vtkm::Vec<FieldType, 3>> fieldArray;
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InDataSet.GetField("vecData").GetData().CopyTo(fieldArray);
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// Generate random seeds for starting streamlines
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std::vector<vtkm::Vec<FieldType, 3>> seeds;
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for (vtkm::Id i = 0; i < numSeeds; i++)
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{
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vtkm::Vec<FieldType, 3> seed;
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seed[0] = static_cast<FieldType>(rand() % vdims[0]);
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seed[1] = static_cast<FieldType>(rand() % vdims[1]);
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seed[2] = static_cast<FieldType>(rand() % vdims[2]);
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seeds.push_back(seed);
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}
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vtkm::cont::ArrayHandle<vtkm::Vec<FieldType, 3>> seedPosArray =
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vtkm::cont::make_ArrayHandle(&seeds[0], numSeeds);
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vtkm::cont::ArrayHandleCounting<vtkm::Id> seedIdArray(0, 1, numSeeds);
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// Number of streams * number of steps * [forward, backward]
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vtkm::Id numCells = numSeeds * 2;
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vtkm::Id maxConnectivityLen = numCells * maxSteps;
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// Stream array at max size will be filled with stream coordinates
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vtkm::cont::ArrayHandle<vtkm::Vec<FieldType, 3>> streamArray;
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streamArray.Allocate(maxConnectivityLen);
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// NumIndices per polyline cell filled in by MakeStreamLines
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vtkm::cont::ArrayHandle<vtkm::IdComponent> numIndices;
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numIndices.Allocate(numCells);
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// All cells are polylines
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vtkm::cont::ArrayHandle<vtkm::UInt8> cellTypes;
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cellTypes.Allocate(numCells);
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vtkm::cont::ArrayHandleConstant<vtkm::UInt8> polyLineShape(vtkm::CELL_SHAPE_POLY_LINE,
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numCells);
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DeviceAlgorithm::Copy(polyLineShape, cellTypes);
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// Possible maxSteps points but if less use stencil
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vtkm::cont::ArrayHandle<vtkm::IdComponent> validPoint;
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vtkm::cont::ArrayHandleConstant<vtkm::Id> zeros(0, maxConnectivityLen);
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validPoint.Allocate(maxConnectivityLen);
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DeviceAlgorithm::Copy(zeros, validPoint);
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// Worklet to make the streamlines
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MakeStreamLines makeStreamLines(
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timeStep, streamMode, maxSteps, vdims, fieldArray.PrepareForInput(DeviceAdapter()));
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using MakeStreamLinesDispatcher = vtkm::worklet::DispatcherMapField<MakeStreamLines>;
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MakeStreamLinesDispatcher makeStreamLinesDispatcher(makeStreamLines);
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makeStreamLinesDispatcher.Invoke(
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seedIdArray, seedPosArray, numIndices, validPoint, streamArray);
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// Size of connectivity based on size of returned streamlines
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vtkm::cont::ArrayHandle<vtkm::IdComponent> numIndicesOut;
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vtkm::IdComponent connectivityLen = DeviceAlgorithm::ScanExclusive(numIndices, numIndicesOut);
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// Connectivity is sequential
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vtkm::cont::ArrayHandleCounting<vtkm::Id> connCount(0, 1, connectivityLen);
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vtkm::cont::ArrayHandle<vtkm::Id> connectivity;
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DeviceAlgorithm::Copy(connCount, connectivity);
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// Compact the stream array so it only has valid points
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vtkm::cont::ArrayHandle<vtkm::Vec<FieldType, 3>> coordinates;
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DeviceAlgorithm::CopyIf(streamArray, validPoint, coordinates, IsUnity());
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// Create the output data set
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vtkm::cont::DataSet OutDataSet;
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vtkm::cont::CellSetExplicit<> outCellSet;
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outCellSet.Fill(coordinates.GetNumberOfValues(), cellTypes, numIndices, connectivity);
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OutDataSet.AddCellSet(outCellSet);
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OutDataSet.AddCoordinateSystem(vtkm::cont::CoordinateSystem("coordinates", coordinates));
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return OutDataSet;
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}
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};
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}
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}
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#endif // vtk_m_worklet_StreamLineUniformGrid_h
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