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https://gitlab.kitware.com/vtk/vtk-m
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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
20 KiB
C++
433 lines
20 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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// Copyright (c) 2016, Los Alamos National Security, LLC
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// All rights reserved.
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//
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// Copyright 2016. Los Alamos National Security, LLC.
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// This software was produced under U.S. Government contract DE-AC52-06NA25396
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// for Los Alamos National Laboratory (LANL), which is operated by
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// Los Alamos National Security, LLC for the U.S. Department of Energy.
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// The U.S. Government has rights to use, reproduce, and distribute this
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// software. NEITHER THE GOVERNMENT NOR LOS ALAMOS NATIONAL SECURITY, LLC
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// MAKES ANY WARRANTY, EXPRESS OR IMPLIED, OR ASSUMES ANY LIABILITY FOR THE
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// USE OF THIS SOFTWARE. If software is modified to produce derivative works,
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// such modified software should be clearly marked, so as not to confuse it
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// with the version available from LANL.
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//
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// Additionally, redistribution and use in source and binary forms, with or
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// without modification, are permitted provided that the following conditions
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// are met:
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//
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// 1. Redistributions of source code must retain the above copyright notice,
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// this list of conditions and the following disclaimer.
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// 2. Redistributions in binary form must reproduce the above copyright notice,
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// this list of conditions and the following disclaimer in the documentation
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// and/or other materials provided with the distribution.
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// 3. Neither the name of Los Alamos National Security, LLC, Los Alamos
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// National Laboratory, LANL, the U.S. Government, nor the names of its
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// contributors may be used to endorse or promote products derived from
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// this software without specific prior written permission.
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//
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// THIS SOFTWARE IS PROVIDED BY LOS ALAMOS NATIONAL SECURITY, LLC AND
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// CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING,
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// BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
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// FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL LOS ALAMOS
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// NATIONAL SECURITY, LLC OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
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// INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
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// BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF
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// USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
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// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
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// THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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//============================================================================
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#ifndef vtkm_worklet_cosmotools_cosmotools_centerfinder_h
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#define vtkm_worklet_cosmotools_cosmotools_centerfinder_h
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#include <vtkm/worklet/cosmotools/CosmoTools.h>
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namespace vtkm
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{
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namespace worklet
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{
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namespace cosmotools
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{
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///////////////////////////////////////////////////////////////////////////////
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//
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// Center finder for particles in FOF halo using estimations but with exact final answer
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// MBP (Most Bound Particle) is particle with the minimum potential energy
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//
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///////////////////////////////////////////////////////////////////////////////
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template <typename T, typename StorageType>
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vtkm::Id CosmoTools<T, StorageType>::MBPCenterFinderMxN(T* mxnPotential)
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{
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vtkm::cont::ArrayHandle<vtkm::Id> partId;
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vtkm::cont::ArrayHandle<vtkm::Id> binId;
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vtkm::cont::ArrayHandle<vtkm::Id> uniqueBins;
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vtkm::cont::ArrayHandle<vtkm::Id> partPerBin;
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vtkm::cont::ArrayHandle<vtkm::Id> particleOffset;
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vtkm::cont::ArrayHandle<vtkm::Id> binX;
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vtkm::cont::ArrayHandle<vtkm::Id> binY;
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vtkm::cont::ArrayHandle<vtkm::Id> binZ;
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// Bin all particles in the halo into bins of size linking length
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BinParticlesHalo(partId, binId, uniqueBins, partPerBin, particleOffset, binX, binY, binZ);
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#ifdef DEBUG_PRINT
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DebugPrint("uniqueBins", uniqueBins);
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DebugPrint("partPerBin", partPerBin);
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#endif
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// Compute the estimated potential per bin using 27 contiguous bins
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vtkm::cont::ArrayHandle<T> partPotential;
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MBPCenterFindingByKey(binId, partId, partPotential);
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// Reduce by key to get the estimated minimum potential per bin within 27 neighbors
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vtkm::cont::ArrayHandle<vtkm::Id> tempId;
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vtkm::cont::ArrayHandle<T> minPotential;
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DeviceAlgorithm::ReduceByKey(binId, partPotential, tempId, minPotential, vtkm::Minimum());
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// Reduce by key to get the estimated maximum potential per bin within 27 neighbors
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vtkm::cont::ArrayHandle<T> maxPotential;
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DeviceAlgorithm::ReduceByKey(binId, partPotential, tempId, maxPotential, vtkm::Maximum());
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#ifdef DEBUG_PRINT
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DebugPrint("minPotential", minPotential);
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DebugPrint("maxPotential", maxPotential);
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#endif
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// Compute potentials estimate for a bin using all other bins
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// Particles in the other bins are located at the closest point to this bin
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vtkm::cont::ArrayHandleIndex uniqueIndex(uniqueBins.GetNumberOfValues());
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vtkm::cont::ArrayHandle<T> bestEstPotential;
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vtkm::cont::ArrayHandle<T> worstEstPotential;
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// Initialize each bin potential with the nxn for that bin
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DeviceAlgorithm::Copy(minPotential, bestEstPotential);
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DeviceAlgorithm::Copy(maxPotential, worstEstPotential);
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// Estimate only across the uniqueBins that contain particles
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ComputePotentialBin<T> computePotentialBin(uniqueBins.GetNumberOfValues(), particleMass, linkLen);
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vtkm::worklet::DispatcherMapField<ComputePotentialBin<T>> computePotentialBinDispatcher(
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computePotentialBin);
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computePotentialBinDispatcher.Invoke(uniqueIndex, // input
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partPerBin, // input (whole array)
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binX, // input (whole array)
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binY, // input (whole array)
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binZ, // input (whole array)
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bestEstPotential, // input/output
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worstEstPotential); // input/output
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#ifdef DEBUG_PRINT
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DebugPrint("bestEstPotential", bestEstPotential);
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DebugPrint("worstEstPotential", worstEstPotential);
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std::cout << "Number of bestEstPotential " << bestEstPotential.GetNumberOfValues() << std::endl;
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std::cout << "Number of worstEstPotential " << worstEstPotential.GetNumberOfValues() << std::endl;
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#endif
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// Sort everything by the best estimated potential per bin
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vtkm::cont::ArrayHandle<T> tempBest;
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DeviceAlgorithm::Copy(bestEstPotential, tempBest);
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DeviceAlgorithm::SortByKey(tempBest, worstEstPotential);
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// Use the worst estimate for the first selected bin to compare to best of all others
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// Any bin that passes is a candidate for having the MBP
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T cutoffPotential = worstEstPotential.GetPortalControl().Get(0);
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vtkm::cont::ArrayHandle<vtkm::Id> candidate;
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DeviceAlgorithm::Copy(vtkm::cont::ArrayHandleConstant<vtkm::Id>(0, nParticles), candidate);
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SetCandidateParticles<T> setCandidateParticles(cutoffPotential);
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vtkm::worklet::DispatcherMapField<SetCandidateParticles<T>> setCandidateParticlesDispatcher(
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setCandidateParticles);
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setCandidateParticlesDispatcher.Invoke(bestEstPotential, // input
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particleOffset, // input
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partPerBin, // input
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candidate); // output (whole array)
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// Copy the M candidate particles to a new array
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vtkm::cont::ArrayHandle<vtkm::Id> mparticles;
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DeviceAlgorithm::CopyIf(partId, candidate, mparticles);
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// Compute potentials only on the candidate particles
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vtkm::cont::ArrayHandle<T> mpotential;
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ComputePotentialOnCandidates<T> computePotentialOnCandidates(nParticles, particleMass);
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vtkm::worklet::DispatcherMapField<ComputePotentialOnCandidates<T>>
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computePotentialOnCandidatesDispatcher(computePotentialOnCandidates);
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computePotentialOnCandidatesDispatcher.Invoke(mparticles,
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xLoc, // input (whole array)
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yLoc, // input (whole array)
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zLoc, // input (whole array)
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mpotential); // output
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// Of the M candidate particles which has the minimum potential
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DeviceAlgorithm::SortByKey(mpotential, mparticles);
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#ifdef DEBUG_PRINT
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DebugPrint("mparticles", mparticles);
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DebugPrint("mpotential", mpotential);
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#endif
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// Return the found MBP particle and its potential
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vtkm::Id mxnMBP = mparticles.GetPortalControl().Get(0);
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*mxnPotential = mpotential.GetPortalControl().Get(0);
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return mxnMBP;
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}
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///////////////////////////////////////////////////////////////////////////////
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//
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// Bin particles in one halo for quick MBP finding
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//
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///////////////////////////////////////////////////////////////////////////////
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template <typename T, typename StorageType>
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void CosmoTools<T, StorageType>::BinParticlesHalo(vtkm::cont::ArrayHandle<vtkm::Id>& partId,
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vtkm::cont::ArrayHandle<vtkm::Id>& binId,
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vtkm::cont::ArrayHandle<vtkm::Id>& uniqueBins,
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vtkm::cont::ArrayHandle<vtkm::Id>& partPerBin,
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vtkm::cont::ArrayHandle<vtkm::Id>& particleOffset,
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vtkm::cont::ArrayHandle<vtkm::Id>& binX,
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vtkm::cont::ArrayHandle<vtkm::Id>& binY,
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vtkm::cont::ArrayHandle<vtkm::Id>& binZ)
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{
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// Compute number of bins and ranges for each bin
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vtkm::Vec<T, 2> xRange(xLoc.GetPortalConstControl().Get(0));
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vtkm::Vec<T, 2> yRange(yLoc.GetPortalConstControl().Get(0));
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vtkm::Vec<T, 2> zRange(zLoc.GetPortalConstControl().Get(0));
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xRange = DeviceAlgorithm::Reduce(xLoc, xRange, vtkm::MinAndMax<T>());
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T minX = xRange[0];
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T maxX = xRange[1];
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yRange = DeviceAlgorithm::Reduce(yLoc, yRange, vtkm::MinAndMax<T>());
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T minY = yRange[0];
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T maxY = yRange[1];
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zRange = DeviceAlgorithm::Reduce(zLoc, zRange, vtkm::MinAndMax<T>());
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T minZ = zRange[0];
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T maxZ = zRange[1];
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numBinsX = static_cast<vtkm::Id>(vtkm::Floor((maxX - minX) / linkLen));
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numBinsY = static_cast<vtkm::Id>(vtkm::Floor((maxY - minY) / linkLen));
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numBinsZ = static_cast<vtkm::Id>(vtkm::Floor((maxZ - minZ) / linkLen));
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vtkm::Id maxBins = 1048576;
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numBinsX = std::min(maxBins, numBinsX);
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numBinsY = std::min(maxBins, numBinsY);
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numBinsZ = std::min(maxBins, numBinsZ);
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vtkm::Id minBins = 1;
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numBinsX = std::max(minBins, numBinsX);
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numBinsY = std::max(minBins, numBinsY);
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numBinsZ = std::max(minBins, numBinsZ);
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#ifdef DEBUG_PRINT
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std::cout << std::endl
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<< "** BinParticlesHalo (" << numBinsX << ", " << numBinsY << ", " << numBinsZ << ") ("
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<< minX << ", " << minY << ", " << minZ << ") (" << maxX << ", " << maxY << ", " << maxZ
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<< ")" << std::endl;
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#endif
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// Compute which bin each particle is in
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ComputeBins<T> computeBins(minX,
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maxX, // Physical range on domain
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minY,
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maxY,
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minZ,
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maxZ,
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numBinsX,
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numBinsY,
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numBinsZ); // Size of superimposed mesh
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vtkm::worklet::DispatcherMapField<ComputeBins<T>> computeBinsDispatcher(computeBins);
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computeBinsDispatcher.Invoke(xLoc, // input
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yLoc, // input
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zLoc, // input
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binId); // output
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vtkm::cont::ArrayHandleIndex indexArray(nParticles);
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DeviceAlgorithm::Copy(indexArray, partId);
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#ifdef DEBUG_PRINT
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DebugPrint("xLoc", xLoc);
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DebugPrint("yLoc", yLoc);
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DebugPrint("zLoc", zLoc);
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DebugPrint("partId", partId);
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DebugPrint("binId", binId);
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#endif
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// Sort the particles by bin
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DeviceAlgorithm::SortByKey(binId, partId);
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// Count the number of particles per bin
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vtkm::cont::ArrayHandleConstant<vtkm::Id> constArray(1, nParticles);
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DeviceAlgorithm::ReduceByKey(binId, constArray, uniqueBins, partPerBin, vtkm::Add());
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#ifdef DEBUG_PRINT
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DebugPrint("sorted binId", binId);
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DebugPrint("sorted partId", partId);
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DebugPrint("uniqueBins", uniqueBins);
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DebugPrint("partPerBin", partPerBin);
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#endif
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// Calculate the bin indices
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ComputeBinIndices<T> computeBinIndices(numBinsX, numBinsY, numBinsZ);
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vtkm::worklet::DispatcherMapField<ComputeBinIndices<T>> computeBinIndicesDispatcher(
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computeBinIndices);
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computeBinIndicesDispatcher.Invoke(uniqueBins, // input
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binX, // input
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binY, // input
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binZ); // input
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DeviceAlgorithm::ScanExclusive(partPerBin, particleOffset);
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}
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///////////////////////////////////////////////////////////////////////////////
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//
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// Center finder for all particles given location, particle id and key id
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// Assumed that key and particles are already sorted
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// MBP (Most Bound Particle) is particle with the minimum potential energy
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// Method uses ScanInclusiveByKey() and ArrayHandleReverse
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//
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///////////////////////////////////////////////////////////////////////////////
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template <typename T, typename StorageType>
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void CosmoTools<T, StorageType>::MBPCenterFindingByKey(vtkm::cont::ArrayHandle<vtkm::Id>& keyId,
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vtkm::cont::ArrayHandle<vtkm::Id>& partId,
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vtkm::cont::ArrayHandle<T>& minPotential)
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{
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// Compute starting and ending indices of each key (bin or halo)
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vtkm::cont::ArrayHandleIndex indexArray(nParticles);
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vtkm::cont::ArrayHandle<T> potential;
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vtkm::cont::ArrayHandleReverse<vtkm::cont::ArrayHandle<vtkm::Id>> keyReverse(keyId);
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vtkm::cont::ArrayHandleReverse<vtkm::cont::ArrayHandle<T>> minPotReverse(minPotential);
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// Compute indices of all left neighbor bins per bin not per particle
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vtkm::cont::ArrayHandle<vtkm::Id> leftNeighbor;
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vtkm::cont::ArrayHandle<vtkm::Id> rightNeighbor;
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leftNeighbor.Allocate(NUM_NEIGHBORS * nParticles);
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rightNeighbor.Allocate(NUM_NEIGHBORS * nParticles);
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vtkm::cont::ArrayHandleIndex countArray(nParticles);
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ComputeNeighborBins computeNeighborBins(numBinsX, numBinsY, numBinsZ, NUM_NEIGHBORS);
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vtkm::worklet::DispatcherMapField<ComputeNeighborBins> computeNeighborBinsDispatcher(
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computeNeighborBins);
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computeNeighborBinsDispatcher.Invoke(countArray, keyId, leftNeighbor);
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// Compute indices of all right neighbor bins
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ComputeBinRange computeBinRange(numBinsX);
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vtkm::worklet::DispatcherMapField<ComputeBinRange> computeBinRangeDispatcher(computeBinRange);
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computeBinRangeDispatcher.Invoke(leftNeighbor, rightNeighbor);
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// Convert bin range to particle range within the bins
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DeviceAlgorithm::LowerBounds(keyId, leftNeighbor, leftNeighbor);
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DeviceAlgorithm::UpperBounds(keyId, rightNeighbor, rightNeighbor);
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#ifdef DEBUG_PRINT
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DebugPrint("leftNeighbor", leftNeighbor);
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DebugPrint("rightNeighbor", rightNeighbor);
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#endif
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// Initialize halo id of each particle to itself
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// Compute potentials on particles in 27 neighbors to find minimum
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ComputePotentialNeighbors<T> computePotentialNeighbors(
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numBinsX, numBinsY, numBinsZ, NUM_NEIGHBORS, particleMass);
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vtkm::worklet::DispatcherMapField<ComputePotentialNeighbors<T>>
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computePotentialNeighborsDispatcher(computePotentialNeighbors);
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computePotentialNeighborsDispatcher.Invoke(indexArray,
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keyId, // input (whole array)
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partId, // input (whole array)
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xLoc, // input (whole array)
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yLoc, // input (whole array)
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zLoc, // input (whole array)
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leftNeighbor, // input (whole array)
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rightNeighbor, // input (whole array)
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potential); // output
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// Find minimum potential for all particles in a halo
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DeviceAlgorithm::ScanInclusiveByKey(keyId, potential, minPotential, vtkm::Minimum());
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DeviceAlgorithm::ScanInclusiveByKey(keyReverse, minPotReverse, minPotReverse, vtkm::Minimum());
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#ifdef DEBUG_PRINT
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DebugPrint("potential", potential);
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DebugPrint("minPotential", minPotential);
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#endif
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// Find the particle id matching the minimum potential
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vtkm::cont::ArrayHandle<vtkm::Id> centerId;
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EqualsMinimumPotential<T> equalsMinimumPotential;
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vtkm::worklet::DispatcherMapField<EqualsMinimumPotential<T>> equalsMinimumPotentialDispatcher(
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equalsMinimumPotential);
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equalsMinimumPotentialDispatcher.Invoke(partId, potential, minPotential, centerId);
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}
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///////////////////////////////////////////////////////////////////////////////
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//
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// Center finder for particles in a single halo given location and particle id
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// MBP (Most Bound Particle) is particle with the minimum potential energy
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// Method uses ScanInclusiveByKey() and ArrayHandleReverse
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//
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///////////////////////////////////////////////////////////////////////////////
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template <typename T, typename StorageType>
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vtkm::Id CosmoTools<T, StorageType>::MBPCenterFinderNxN(T* nxnPotential)
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{
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vtkm::cont::ArrayHandle<T> potential;
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vtkm::cont::ArrayHandle<T> minPotential;
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vtkm::cont::ArrayHandleReverse<vtkm::cont::ArrayHandle<T>> minPotReverse(minPotential);
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vtkm::cont::ArrayHandleIndex particleIndex(nParticles);
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// Compute potentials (Worklet)
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ComputePotentialNxN<T> computePotentialHalo(nParticles, particleMass);
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vtkm::worklet::DispatcherMapField<ComputePotentialNxN<T>> computePotentialHaloDispatcher(
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computePotentialHalo);
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computePotentialHaloDispatcher.Invoke(particleIndex, // input
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xLoc, // input (whole array)
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yLoc, // input (whole array)
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zLoc, // input (whole array)
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potential); // output
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// Find minimum potential for all particles in a halo
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DeviceAlgorithm::ScanInclusive(potential, minPotential, vtkm::Minimum());
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DeviceAlgorithm::ScanInclusive(minPotReverse, minPotReverse, vtkm::Minimum());
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// Find the particle id matching the minimum potential
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vtkm::cont::ArrayHandle<vtkm::Id> centerId;
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EqualsMinimumPotential<T> equalsMinimumPotential;
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vtkm::worklet::DispatcherMapField<EqualsMinimumPotential<T>> equalsMinimumPotentialDispatcher(
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equalsMinimumPotential);
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equalsMinimumPotentialDispatcher.Invoke(particleIndex, potential, minPotential, centerId);
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// Fill out entire array with center index
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vtkm::cont::ArrayHandleReverse<vtkm::cont::ArrayHandle<vtkm::Id>> centerIdReverse(centerId);
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DeviceAlgorithm::ScanInclusive(centerId, centerId, vtkm::Maximum());
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DeviceAlgorithm::ScanInclusive(centerIdReverse, centerIdReverse, vtkm::Maximum());
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vtkm::Id nxnMBP = centerId.GetPortalConstControl().Get(0);
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*nxnPotential = potential.GetPortalConstControl().Get(nxnMBP);
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return nxnMBP;
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}
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}
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}
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}
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|
#endif
|