/* Copyright 2022 David Grote * * This file is part of WarpX. * * License: BSD-3-Clause-LBNL */ #include "WarpX.H" #include "LatticeElementFinder.H" #include "LatticeElements/HardEdgedQuadrupole.H" #include "LatticeElements/HardEdgedPlasmaLens.H" #include #include using namespace amrex::literals; void LatticeElementFinder::InitElementFinder (int const lev, amrex::MFIter const& a_mfi, AcceleratorLattice const& accelerator_lattice) { // The lattice is assumed to extend in the z-direction // Get the number of nodes where indices will be setup const amrex::Box box = a_mfi.tilebox(); m_nz = box.size()[WARPX_ZINDEX]; m_dz = WarpX::CellSize(lev)[2]; m_gamma_boost = WarpX::gamma_boost; m_uz_boost = std::sqrt(WarpX::gamma_boost*WarpX::gamma_boost - 1._prt)*PhysConst::c; AllocateIndices(accelerator_lattice); UpdateIndices(lev, a_mfi, accelerator_lattice); } void LatticeElementFinder::AllocateIndices (AcceleratorLattice const& accelerator_lattice) { // Allocate the space for the indices for each element type. // Note that this uses m_nz since the information is saved per node. if (accelerator_lattice.h_quad.nelements > 0) { d_quad_indices.resize(m_nz); } if (accelerator_lattice.h_plasmalens.nelements > 0) { d_plasmalens_indices.resize(m_nz); } } void LatticeElementFinder::UpdateIndices (int const lev, amrex::MFIter const& a_mfi, AcceleratorLattice const& accelerator_lattice) { auto& warpx = WarpX::GetInstance(); // Update the location of the index grid. // Note that the current box is used since the box may have been updated since // the initialization in InitElementFinder. const amrex::Box box = a_mfi.tilebox(); m_zmin = WarpX::LowerCorner(box, lev, 0._rt)[2]; m_time = warpx.gett_new(lev); if (accelerator_lattice.h_quad.nelements > 0) { setup_lattice_indices(accelerator_lattice.h_quad.d_zs, accelerator_lattice.h_quad.d_ze, d_quad_indices); } if (accelerator_lattice.h_plasmalens.nelements > 0) { setup_lattice_indices(accelerator_lattice.h_plasmalens.d_zs, accelerator_lattice.h_plasmalens.d_ze, d_plasmalens_indices); } } LatticeElementFinderDevice LatticeElementFinder::GetFinderDeviceInstance (WarpXParIter const& a_pti, int const a_offset, AcceleratorLattice const& accelerator_lattice) { LatticeElementFinderDevice result; result.InitLatticeElementFinderDevice(a_pti, a_offset, accelerator_lattice, *this); return result; } void LatticeElementFinderDevice::InitLatticeElementFinderDevice (WarpXParIter const& a_pti, int const a_offset, AcceleratorLattice const& accelerator_lattice, LatticeElementFinder const & h_finder) { auto& warpx = WarpX::GetInstance(); int const lev = a_pti.GetLevel(); m_get_position = GetParticlePosition(a_pti, a_offset); auto& attribs = a_pti.GetAttribs(); m_ux = attribs[PIdx::ux].dataPtr() + a_offset; m_uy = attribs[PIdx::uy].dataPtr() + a_offset; m_uz = attribs[PIdx::uz].dataPtr() + a_offset; m_dt = warpx.getdt(lev); m_gamma_boost = WarpX::gamma_boost; m_uz_boost = std::sqrt(WarpX::gamma_boost*WarpX::gamma_boost - 1._prt)*PhysConst::c; m_zmin = h_finder.m_zmin; m_dz = h_finder.m_dz; m_time = h_finder.m_time; if (accelerator_lattice.h_quad.nelements > 0) { d_quad = accelerator_lattice.h_quad.GetDeviceInstance(); d_quad_indices_arr = h_finder.d_quad_indices.data(); } if (accelerator_lattice.h_plasmalens.nelements > 0) { d_plasmalens = accelerator_lattice.h_plasmalens.GetDeviceInstance(); d_plasmalens_indices_arr = h_finder.d_plasmalens_indices.data(); } }