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/* Copyright 2021 Neil Zaim

 *

 * This file is part of WarpX.

 *

 * License: BSD-3-Clause-LBNL

 */


#ifndef WARPX_NUCLEAR_FUSION_FUNC_H_

#define WARPX_NUCLEAR_FUSION_FUNC_H_


#include "SingleNuclearFusionEvent.H"


#include "Particles/Collision/BinaryCollision/BinaryCollisionUtils.H"

#include "Particles/Pusher/GetAndSetPosition.H"

#include "Particles/MultiParticleContainer.H"

#include "Particles/WarpXParticleContainer.H"

#include "Utils/Parser/ParserUtils.H"

#include "Utils/TextMsg.H"


#include <AMReX_Algorithm.H>

#include <AMReX_DenseBins.H>

#include <AMReX_ParmParse.H>

#include <AMReX_Random.H>

#include <AMReX_REAL.H>

#include <AMReX_Vector.H>


class NuclearFusionFunc

{

    // Define shortcuts for frequently-used type names

    using ParticleType = WarpXParticleContainer::ParticleType;

    using ParticleTileType = WarpXParticleContainer::ParticleTileType;

    using ParticleTileDataType = ParticleTileType::ParticleTileDataType;

    using ParticleBins = amrex::DenseBins<ParticleTileDataType>;

    using index_type = ParticleBins::index_type;

    using SoaData_type = WarpXParticleContainer::ParticleTileType::ParticleTileDataType;


public:

    NuclearFusionFunc () = default;


    NuclearFusionFunc (const std::string& collision_name, MultiParticleContainer const * const mypc,

                       const bool isSameSpecies):

        m_fusion_multiplier{amrex::ParticleReal{1.0}}, // default fusion multiplier

        m_probability_threshold{amrex::ParticleReal{0.02}}, // default fusion probability threshold

        m_probability_target_value{amrex::ParticleReal{0.002}}, // default fusion probability target_value

        m_fusion_type{BinaryCollisionUtils::get_nuclear_fusion_type(collision_name, mypc)},

        m_isSameSpecies{isSameSpecies}

    {


#ifdef AMREX_SINGLE_PRECISION_PARTICLES

        WARPX_ABORT_WITH_MESSAGE("Nuclear fusion module does not currently work with single precision");

#endif


        const amrex::ParmParse pp_collision_name(collision_name);

        utils::parser::queryWithParser(

            pp_collision_name, "event_multiplier", m_fusion_multiplier);

        utils::parser::queryWithParser(

            pp_collision_name, "probability_threshold", m_probability_threshold);

        utils::parser::queryWithParser(

            pp_collision_name, "probability_target_value",

            m_probability_target_value);


        m_exe.m_fusion_multiplier = m_fusion_multiplier;

        m_exe.m_probability_threshold = m_probability_threshold;

        m_exe.m_probability_target_value = m_probability_target_value;

        m_exe.m_fusion_type = m_fusion_type;

        m_exe.m_isSameSpecies = m_isSameSpecies;

    }


    struct Executor {

        AMREX_GPU_HOST_DEVICE AMREX_INLINE


        void operator() (

            index_type const I1s, index_type const I1e,

            index_type const I2s, index_type const I2e,

            index_type const* AMREX_RESTRICT I1,

            index_type const* AMREX_RESTRICT I2,

            const SoaData_type& soa_1, const SoaData_type& soa_2,

            GetParticlePosition<PIdx> /*get_position_1*/, GetParticlePosition<PIdx> /*get_position_2*/,

            amrex::ParticleReal const /*n1*/, amrex::ParticleReal const /*n2*/,

            amrex::ParticleReal const /*T1*/, amrex::ParticleReal const /*T2*/,

            amrex::Real const /*global_lamdb*/,

            amrex::ParticleReal const  /*q1*/, amrex::ParticleReal const  /*q2*/,

            amrex::ParticleReal const  m1, amrex::ParticleReal const  m2,

            amrex::Real const  dt, amrex::Real const dV, index_type coll_idx,

            index_type const cell_start_pair, index_type* AMREX_RESTRICT p_mask,

            index_type* AMREX_RESTRICT p_pair_indices_1, index_type* AMREX_RESTRICT p_pair_indices_2,

            amrex::ParticleReal* AMREX_RESTRICT p_pair_reaction_weight,

            amrex::ParticleReal* /*p_product_data*/,

            amrex::RandomEngine const& engine) const

        {

            amrex::ParticleReal * const AMREX_RESTRICT w1 = soa_1.m_rdata[PIdx::w];

            amrex::ParticleReal * const AMREX_RESTRICT u1x = soa_1.m_rdata[PIdx::ux];

            amrex::ParticleReal * const AMREX_RESTRICT u1y = soa_1.m_rdata[PIdx::uy];

            amrex::ParticleReal * const AMREX_RESTRICT u1z = soa_1.m_rdata[PIdx::uz];

            uint64_t* AMREX_RESTRICT idcpu1 = soa_1.m_idcpu;


            amrex::ParticleReal * const AMREX_RESTRICT w2 = soa_2.m_rdata[PIdx::w];

            amrex::ParticleReal * const AMREX_RESTRICT u2x = soa_2.m_rdata[PIdx::ux];

            amrex::ParticleReal * const AMREX_RESTRICT u2y = soa_2.m_rdata[PIdx::uy];

            amrex::ParticleReal * const AMREX_RESTRICT u2z = soa_2.m_rdata[PIdx::uz];

            uint64_t* AMREX_RESTRICT idcpu2 = soa_2.m_idcpu;


            // Number of macroparticles of each species

            const index_type NI1 = I1e - I1s;

            const index_type NI2 = I2e - I2s;

            const index_type max_N = amrex::max(NI1,NI2);

            const index_type min_N = amrex::min(NI1,NI2);


            index_type pair_index = cell_start_pair + coll_idx;


            // multiplier ratio to take into account unsampled pairs

            const auto multiplier_ratio = static_cast<int>(

                m_isSameSpecies ? min_N + max_N - 1 : min_N);


#if (defined WARPX_DIM_RZ)

            amrex::ParticleReal * const AMREX_RESTRICT theta1 = soa_1.m_rdata[PIdx::theta];

            amrex::ParticleReal * const AMREX_RESTRICT theta2 = soa_2.m_rdata[PIdx::theta];

#endif

            index_type i1 = I1s + coll_idx;

            index_type i2 = I2s + coll_idx;

            // we will start from collision number = coll_idx and then add

            // stride (smaller set size) until we do all collisions (larger set size)

            for (index_type k = coll_idx; k < max_N; k += min_N)

            {


                // do not check for collision if a particle's weight was

                // reduced to zero from a previous collision

                if (idcpu1[ I1[i1] ]==amrex::ParticleIdCpus::Invalid ||

                    idcpu2[ I2[i2] ]==amrex::ParticleIdCpus::Invalid ) {

                    p_mask[pair_index] = false;

                }

                else {


#if (defined WARPX_DIM_RZ)

                    /* In RZ geometry, macroparticles can collide with other macroparticles

                     * in the same *cylindrical* cell. For this reason, collisions between macroparticles

                     * are actually not local in space. In this case, the underlying assumption is that

                     * particles within the same cylindrical cell represent a cylindrically-symmetry

                     * momentum distribution function. Therefore, here, we temporarily rotate the

                     * momentum of one of the macroparticles in agreement with this cylindrical symmetry.

                     * (This is technically only valid if we use only the m=0 azimuthal mode in the simulation;

                     * there is a corresponding assert statement at initialization.) */

                    amrex::ParticleReal const theta = theta2[I2[i2]]-theta1[I1[i1]];

                    amrex::ParticleReal const u1xbuf = u1x[I1[i1]];

                    u1x[I1[i1]] = u1xbuf*std::cos(theta) - u1y[I1[i1]]*std::sin(theta);

                    u1y[I1[i1]] = u1xbuf*std::sin(theta) + u1y[I1[i1]]*std::cos(theta);

#endif


                    SingleNuclearFusionEvent(

                        u1x[ I1[i1] ], u1y[ I1[i1] ], u1z[ I1[i1] ],

                        u2x[ I2[i2] ], u2y[ I2[i2] ], u2z[ I2[i2] ],

                        m1, m2, w1[ I1[i1] ], w2[ I2[i2] ],

                        dt, dV, static_cast<int>(pair_index), p_mask, p_pair_reaction_weight,

                        m_fusion_multiplier, multiplier_ratio,

                        m_probability_threshold,

                        m_probability_target_value,

                        m_fusion_type, engine);


#if (defined WARPX_DIM_RZ)

                    amrex::ParticleReal const u1xbuf_new = u1x[I1[i1]];

                    u1x[I1[i1]] = u1xbuf_new*std::cos(-theta) - u1y[I1[i1]]*std::sin(-theta);

                    u1y[I1[i1]] = u1xbuf_new*std::sin(-theta) + u1y[I1[i1]]*std::cos(-theta);

#endif


                    // Remove pair reaction weight from the colliding particles' weights

                    if (p_mask[pair_index]) {

                        BinaryCollisionUtils::remove_weight_from_colliding_particle(

                            w1[ I1[i1] ], idcpu1[ I1[i1] ], p_pair_reaction_weight[pair_index]);

                        BinaryCollisionUtils::remove_weight_from_colliding_particle(

                            w2[ I2[i2] ], idcpu2[ I2[i2] ], p_pair_reaction_weight[pair_index]);

                    }


                }


                p_pair_indices_1[pair_index] = I1[i1];

                p_pair_indices_2[pair_index] = I2[i2];

                if (max_N == NI1) { i1 += min_N; }

                if (max_N == NI2) { i2 += min_N; }

                pair_index += min_N;

            }

        }


        amrex::ParticleReal m_fusion_multiplier;

        amrex::ParticleReal m_probability_threshold;

        amrex::ParticleReal m_probability_target_value;

        NuclearFusionType m_fusion_type;

        bool m_computeSpeciesDensities = false;

        bool m_computeSpeciesTemperatures = false;

        bool m_need_product_data = false;

        bool m_isSameSpecies;

    };


    [[nodiscard]] Executor const& executor () const { return m_exe; }


    bool use_global_debye_length() { return false; }


private:

    // Factor used to increase the number of fusion reaction by decreasing the weight of the

    // produced particles

    amrex::ParticleReal m_fusion_multiplier;

    // If the fusion multiplier is too high and results in a fusion probability that approaches

    // 1, there is a risk of underestimating the total fusion yield. In these cases, we reduce

    // the fusion multiplier used in a given collision. m_probability_threshold is the fusion

    // probability threshold above which we reduce the fusion multiplier.

    // m_probability_target_value is the target probability used to determine by how much

    // the fusion multiplier should be reduced.

    amrex::ParticleReal m_probability_threshold;

    amrex::ParticleReal m_probability_target_value;

    NuclearFusionType m_fusion_type;

    bool m_isSameSpecies;


    Executor m_exe;

};


#endif // WARPX_NUCLEAR_FUSION_FUNC_H_

AMReX_Algorithm.H

AMReX_DenseBins.H

AMREX_RESTRICT
#define AMREX_RESTRICT

AMREX_INLINE
#define AMREX_INLINE

AMREX_GPU_HOST_DEVICE
#define AMREX_GPU_HOST_DEVICE

AMReX_ParmParse.H

AMReX_REAL.H

AMReX_Random.H

AMReX_Vector.H

BinaryCollisionUtils.H

NuclearFusionType
NuclearFusionType
Definition BinaryCollisionUtils.H:29

GetAndSetPosition.H

MultiParticleContainer.H

ParserUtils.H

SingleNuclearFusionEvent.H

SingleNuclearFusionEvent
AMREX_GPU_HOST_DEVICE AMREX_INLINE void SingleNuclearFusionEvent(const amrex::ParticleReal &u1x, const amrex::ParticleReal &u1y, const amrex::ParticleReal &u1z, const amrex::ParticleReal &u2x, const amrex::ParticleReal &u2y, const amrex::ParticleReal &u2z, const amrex::ParticleReal &m1, const amrex::ParticleReal &m2, amrex::ParticleReal w1, amrex::ParticleReal w2, const amrex::Real &dt, const amrex::ParticleReal &dV, const int &pair_index, index_type *AMREX_RESTRICT p_mask, amrex::ParticleReal *AMREX_RESTRICT p_pair_reaction_weight, const amrex::ParticleReal &fusion_multiplier, const int &multiplier_ratio, const amrex::ParticleReal &probability_threshold, const amrex::ParticleReal &probability_target_value, const NuclearFusionType &fusion_type, const amrex::RandomEngine &engine)
This function computes whether the collision between two particles result in a nuclear fusion event,...
Definition SingleNuclearFusionEvent.H:54

TextMsg.H

WARPX_ABORT_WITH_MESSAGE
#define WARPX_ABORT_WITH_MESSAGE(MSG)
Definition TextMsg.H:15

WarpXParticleContainer.H

MultiParticleContainer
Definition MultiParticleContainer.H:68

NuclearFusionFunc::NuclearFusionFunc
NuclearFusionFunc(const std::string &collision_name, MultiParticleContainer const *const mypc, const bool isSameSpecies)
Constructor of the NuclearFusionFunc class.
Definition NuclearFusionFunc.H:58

NuclearFusionFunc::NuclearFusionFunc
NuclearFusionFunc()=default
Default constructor of the NuclearFusionFunc class.

NuclearFusionFunc::m_fusion_multiplier
amrex::ParticleReal m_fusion_multiplier
Definition NuclearFusionFunc.H:254

NuclearFusionFunc::m_isSameSpecies
bool m_isSameSpecies
Definition NuclearFusionFunc.H:264

NuclearFusionFunc::ParticleTileType
WarpXParticleContainer::ParticleTileType ParticleTileType
Definition NuclearFusionFunc.H:39

NuclearFusionFunc::ParticleBins
amrex::DenseBins< ParticleTileDataType > ParticleBins
Definition NuclearFusionFunc.H:41

NuclearFusionFunc::ParticleType
WarpXParticleContainer::ParticleType ParticleType
Definition NuclearFusionFunc.H:38

NuclearFusionFunc::index_type
ParticleBins::index_type index_type
Definition NuclearFusionFunc.H:42

NuclearFusionFunc::m_probability_threshold
amrex::ParticleReal m_probability_threshold
Definition NuclearFusionFunc.H:261

NuclearFusionFunc::SoaData_type
WarpXParticleContainer::ParticleTileType::ParticleTileDataType SoaData_type
Definition NuclearFusionFunc.H:43

NuclearFusionFunc::m_exe
Executor m_exe
Definition NuclearFusionFunc.H:266

NuclearFusionFunc::m_probability_target_value
amrex::ParticleReal m_probability_target_value
Definition NuclearFusionFunc.H:262

NuclearFusionFunc::executor
Executor const & executor() const
Definition NuclearFusionFunc.H:247

NuclearFusionFunc::use_global_debye_length
bool use_global_debye_length()
Definition NuclearFusionFunc.H:249

NuclearFusionFunc::m_fusion_type
NuclearFusionType m_fusion_type
Definition NuclearFusionFunc.H:263

NuclearFusionFunc::ParticleTileDataType
ParticleTileType::ParticleTileDataType ParticleTileDataType
Definition NuclearFusionFunc.H:40

amrex::DenseBins

amrex::DenseBins< ParticleTileDataType >::index_type
int index_type

amrex::ParmParse

amrex::ParticleContainer_impl< SoAParticle< T_NArrayReal, T_NArrayInt >, T_NArrayReal, T_NArrayInt, Allocator, CellAssignor >::ParticleTileType
ParticleTile< ParticleType, NArrayReal, NArrayInt, Allocator > ParticleTileType

amrex::ParticleContainer_impl< SoAParticle< T_NArrayReal, T_NArrayInt >, T_NArrayReal, T_NArrayInt, Allocator, CellAssignor >::ParticleType
T_ParticleType ParticleType

BinaryCollisionUtils
Definition BinaryCollisionUtils.cpp:20

BinaryCollisionUtils::remove_weight_from_colliding_particle
AMREX_GPU_HOST_DEVICE AMREX_INLINE void remove_weight_from_colliding_particle(amrex::ParticleReal &weight, uint64_t &idcpu, const amrex::ParticleReal reaction_weight)
Subtract given weight from particle and set its ID to invalid if the weight reaches zero.
Definition BinaryCollisionUtils.H:148

amrex::ParticleIdCpus::Invalid
constexpr std::uint64_t Invalid

amrex

amrex::min
__host__ __device__ constexpr const T & min(const T &a, const T &b) noexcept

amrex::max
__host__ __device__ constexpr const T & max(const T &a, const T &b) noexcept

utils::parser::queryWithParser
int queryWithParser(const amrex::ParmParse &a_pp, char const *const str, T &val)
Definition ParserUtils.H:102

GetParticlePosition
Functor that can be used to extract the positions of the macroparticles inside a ParallelFor kernel.
Definition GetAndSetPosition.H:75

NuclearFusionFunc::Executor
Definition NuclearFusionFunc.H:87

NuclearFusionFunc::Executor::m_fusion_type
NuclearFusionType m_fusion_type
Definition NuclearFusionFunc.H:240

NuclearFusionFunc::Executor::m_probability_target_value
amrex::ParticleReal m_probability_target_value
Definition NuclearFusionFunc.H:239

NuclearFusionFunc::Executor::m_computeSpeciesTemperatures
bool m_computeSpeciesTemperatures
Definition NuclearFusionFunc.H:242

NuclearFusionFunc::Executor::m_computeSpeciesDensities
bool m_computeSpeciesDensities
Definition NuclearFusionFunc.H:241

NuclearFusionFunc::Executor::m_isSameSpecies
bool m_isSameSpecies
Definition NuclearFusionFunc.H:244

NuclearFusionFunc::Executor::m_probability_threshold
amrex::ParticleReal m_probability_threshold
Definition NuclearFusionFunc.H:238

NuclearFusionFunc::Executor::operator()
AMREX_GPU_HOST_DEVICE AMREX_INLINE void operator()(index_type const I1s, index_type const I1e, index_type const I2s, index_type const I2e, index_type const *AMREX_RESTRICT I1, index_type const *AMREX_RESTRICT I2, const SoaData_type &soa_1, const SoaData_type &soa_2, GetParticlePosition< PIdx >, GetParticlePosition< PIdx >, amrex::ParticleReal const, amrex::ParticleReal const, amrex::ParticleReal const, amrex::ParticleReal const, amrex::Real const, amrex::ParticleReal const, amrex::ParticleReal const, amrex::ParticleReal const m1, amrex::ParticleReal const m2, amrex::Real const dt, amrex::Real const dV, index_type coll_idx, index_type const cell_start_pair, index_type *AMREX_RESTRICT p_mask, index_type *AMREX_RESTRICT p_pair_indices_1, index_type *AMREX_RESTRICT p_pair_indices_2, amrex::ParticleReal *AMREX_RESTRICT p_pair_reaction_weight, amrex::ParticleReal *, amrex::RandomEngine const &engine) const
Executor of the NuclearFusionFunc class. Performs nuclear fusions at the cell level using the algorit...
Definition NuclearFusionFunc.H:126

NuclearFusionFunc::Executor::m_need_product_data
bool m_need_product_data
Definition NuclearFusionFunc.H:243

NuclearFusionFunc::Executor::m_fusion_multiplier
amrex::ParticleReal m_fusion_multiplier
Definition NuclearFusionFunc.H:237

PIdx::theta
@ theta
RZ needs all three position components.
Definition WarpXParticleContainer.H:72

PIdx::uz
@ uz
Definition WarpXParticleContainer.H:70

PIdx::w
@ w
weight
Definition WarpXParticleContainer.H:69

PIdx::uy
@ uy
Definition WarpXParticleContainer.H:70

PIdx::ux
@ ux
Definition WarpXParticleContainer.H:70

amrex::ParticleTile< ParticleType, NArrayReal, NArrayInt, Allocator >::ParticleTileDataType
ParticleTileData< StorageParticleType, NArrayReal, NArrayInt > ParticleTileDataType

amrex::RandomEngine