HybridPICModel.H

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/* Copyright 2023 The WarpX Community
 *
 * This file is part of WarpX.
 *
 * Authors: Roelof Groenewald (TAE Technologies)
 *
 * License: BSD-3-Clause-LBNL
 */
 
#ifndef WARPX_HYBRIDPICMODEL_H_
#define WARPX_HYBRIDPICMODEL_H_
 
#include "HybridPICModel_fwd.H"
 
#include "FieldSolver/FiniteDifferenceSolver/FiniteDifferenceSolver.H"
#include "Utils/Parser/ParserUtils.H"
#include "Utils/WarpXConst.H"
#include "Utils/WarpXProfilerWrapper.H"
#include "WarpX.H"
 
#include <AMReX_Array.H>
#include <AMReX_REAL.H>
 
 
class HybridPICModel
{
public:
    HybridPICModel (int nlevs_max); // constructor
 
    void ReadParameters ();
 
    void AllocateMFs (int nlevs_max);
    void AllocateLevelMFs (int lev, const amrex::BoxArray& ba, const amrex::DistributionMapping& dm,
                           int ncomps, const amrex::IntVect& ngJ, const amrex::IntVect& ngRho,
                           const amrex::IntVect& jx_nodal_flag, const amrex::IntVect& jy_nodal_flag,
                           const amrex::IntVect& jz_nodal_flag, const amrex::IntVect& rho_nodal_flag);
 
    void ClearLevel (int lev);
 
    void InitData ();
 
    void GetCurrentExternal (
        amrex::Vector<std::array< std::unique_ptr<amrex::MultiFab>, 3>> const& edge_lengths
    );
    void GetCurrentExternal (
        std::array< std::unique_ptr<amrex::MultiFab>, 3> const& edge_lengths,
        int lev
    );
 
    void CalculateCurrentAmpere (
        amrex::Vector<std::array< std::unique_ptr<amrex::MultiFab>, 3>> const& Bfield,
        amrex::Vector<std::array< std::unique_ptr<amrex::MultiFab>, 3>> const& edge_lengths
    );
    void CalculateCurrentAmpere (
        std::array< std::unique_ptr<amrex::MultiFab>, 3> const& Bfield,
        std::array< std::unique_ptr<amrex::MultiFab>, 3> const& edge_lengths,
        int lev
    );
 
    void HybridPICSolveE (
        amrex::Vector<std::array< std::unique_ptr<amrex::MultiFab>, 3>>& Efield,
        amrex::Vector<std::array< std::unique_ptr<amrex::MultiFab>, 3>> const& Jfield,
        amrex::Vector<std::array< std::unique_ptr<amrex::MultiFab>, 3>> const& Bfield,
        amrex::Vector<std::unique_ptr<amrex::MultiFab>> const& rhofield,
        amrex::Vector<std::array< std::unique_ptr<amrex::MultiFab>, 3>> const& edge_lengths,
        bool include_resistivity_term);
 
    void HybridPICSolveE (
        std::array< std::unique_ptr<amrex::MultiFab>, 3>& Efield,
        std::array< std::unique_ptr<amrex::MultiFab>, 3> const& Jfield,
        std::array< std::unique_ptr<amrex::MultiFab>, 3> const& Bfield,
        std::unique_ptr<amrex::MultiFab> const& rhofield,
        std::array< std::unique_ptr<amrex::MultiFab>, 3> const& edge_lengths,
        int lev, bool include_resistivity_term);
 
    void HybridPICSolveE (
        std::array< std::unique_ptr<amrex::MultiFab>, 3>& Efield,
        std::array< std::unique_ptr<amrex::MultiFab>, 3> const& Jfield,
        std::array< std::unique_ptr<amrex::MultiFab>, 3> const& Bfield,
        std::unique_ptr<amrex::MultiFab> const& rhofield,
        std::array< std::unique_ptr<amrex::MultiFab>, 3> const& edge_lengths,
        int lev, PatchType patch_type, bool include_resistivity_term);
 
    void CalculateElectronPressure (          DtType a_dt_type);
    void CalculateElectronPressure (int lev,  DtType a_dt_type);
 
    void FillElectronPressureMF (
        std::unique_ptr<amrex::MultiFab> const& Pe_field,
        amrex::MultiFab* const& rho_field );
 
    // Declare variables to hold hybrid-PIC model parameters
    int m_substeps = 100;
 
    amrex::Real m_elec_temp;
    amrex::Real m_n0_ref = 1.0;
    amrex::Real m_gamma = 5.0/3.0;
 
    amrex::Real m_n_floor = 1.0;
 
    std::string m_eta_expression = "0.0";
    std::unique_ptr<amrex::Parser> m_resistivity_parser;
    amrex::ParserExecutor<1> m_eta;
 
    std::string m_Jx_ext_grid_function = "0.0";
    std::string m_Jy_ext_grid_function = "0.0";
    std::string m_Jz_ext_grid_function = "0.0";
    std::array< std::unique_ptr<amrex::Parser>, 3> m_J_external_parser;
    std::array< amrex::ParserExecutor<4>, 3> m_J_external;
    bool m_external_field_has_time_dependence = false;
 
    // Declare multifabs specifically needed for the hybrid-PIC model
    amrex::Vector<            std::unique_ptr<amrex::MultiFab>      > rho_fp_temp;
    amrex::Vector<std::array< std::unique_ptr<amrex::MultiFab>, 3 > > current_fp_temp;
    amrex::Vector<std::array< std::unique_ptr<amrex::MultiFab>, 3 > > current_fp_ampere;
    amrex::Vector<std::array< std::unique_ptr<amrex::MultiFab>, 3 > > current_fp_external;
    amrex::Vector<            std::unique_ptr<amrex::MultiFab>      > electron_pressure_fp;
 
    // Helper functions to retrieve hybrid-PIC multifabs
    [[nodiscard]] amrex::MultiFab*
    get_pointer_current_fp_ampere  (int lev, int direction) const
    {
        return current_fp_ampere[lev][direction].get();
    }
 
    [[nodiscard]] amrex::MultiFab*
    get_pointer_electron_pressure_fp  (int lev) const
    {
        return electron_pressure_fp[lev].get();
    }
 
    amrex::GpuArray<int, 3> Jx_IndexType;
    amrex::GpuArray<int, 3> Jy_IndexType;
    amrex::GpuArray<int, 3> Jz_IndexType;
    amrex::GpuArray<int, 3> Bx_IndexType;
    amrex::GpuArray<int, 3> By_IndexType;
    amrex::GpuArray<int, 3> Bz_IndexType;
    amrex::GpuArray<int, 3> Ex_IndexType;
    amrex::GpuArray<int, 3> Ey_IndexType;
    amrex::GpuArray<int, 3> Ez_IndexType;
};
 
struct ElectronPressure {
 
    AMREX_GPU_HOST_DEVICE AMREX_FORCE_INLINE
    static amrex::Real get_pressure (amrex::Real const n0,
                                     amrex::Real const T0,
                                     amrex::Real const gamma,
                                     amrex::Real const rho) {
        return n0 * T0 * std::pow((rho/PhysConst::q_e)/n0, gamma);
    }
};
 
#endif // WARPX_HYBRIDPICMODEL_H_