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fix_eph_coloured.h
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fix_eph_coloured.h
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/*
* Authors of the extension Artur Tamm, Alfredo Correa
* e-mail: [email protected]
*/
#ifdef FIX_CLASS
FixStyle(eph/coloured,FixEPHColoured)
#else
#ifndef LMP_FIX_EPH_COLOURED_H
#define LMP_FIX_EPH_COLOURED_H
// external headers
#include <memory>
#include <vector>
#include <cstddef>
// lammps headers
#include "fix.h"
// internal headers
#include "eph_beta.h"
#include "eph_fdm.h"
namespace LAMMPS_NS {
class FixEPHColoured : public Fix {
public:
// enumeration for tracking fix state, this is used in comm forward
enum class FixState : unsigned int {
NONE,
XIX,
XIY,
XIZ,
RHO,
WX,
WY,
WZ,
XI,
WI
};
// enumeration for selecting fix functionality
enum Flag : int {
FRICTION = 0x01,
RANDOM = 0x02,
FDM = 0x04,
NOINT = 0x08, // disable integration
NOFRICTION = 0x10, // disable effect of friction force
NORANDOM = 0x20 // disable effect of random force
};
FixEPHColoured(class LAMMPS *, int, char **); // constructor
~FixEPHColoured(); // destructor
void init() override; // called by lammps after constructor
void init_list(int id, NeighList *ptr) override; // called by lammps after constructor
int setmask() override; // called by lammps
void post_force(int) override; // called by lammps after pair_potential
void end_of_step() override; // called by lammps before next step
void reset_dt() override; // called by lammps if dt changes
void grow_arrays(int) override; // called by lammps if number of atoms changes for some task
double compute_vector(int) override; // called by lammps if a value is requested
double memory_usage() override; // prints the memory usage // TODO
void post_run() override; // called by lammps after run ends
/* integrator functionality */
void initial_integrate(int) override; // called in the beginning of a step
void final_integrate() override; // called in the end of the step
// forward communication copies information of owned local atoms to ghost
// atoms, reverse communication does the opposite
int pack_forward_comm(int, int *, double *, int, int *) override;
void unpack_forward_comm(int, int, double *) override;
protected:
static constexpr size_t max_file_length = 256; // max filename length
int myID; // mpi rank for current instance
int nrPS; // number of processes
FixState state; // tracks the state of the fix
int eph_flag; // term flags
int eph_model; // model selection
int types; // number of different types
int* type_map; // TODO: type map // change this to vector
//Container<uint8_t, Allocator<uint8_t> type_map; // type map // change this to vector
Beta beta; // instance for beta(rho) parametrisation
EPH_FDM fdm; // electronic FDM grid
/** integrator functionality **/
double dtv;
double dtf;
double r_cutoff; // cutoff for rho(r)
double r_cutoff_sq;
double rho_cutoff; // cutoff for beta(rho)
int T_freq; // frequency for printing electronic temperatures to files
char T_out[max_file_length]; // this will print temperature heatmap
char T_state[max_file_length]; // this will store the final state into file
double eta_factor; // this is for the conversion from energy/ps -> force
int seed; // seed for random number generator
class RanMars *random; // rng
// Neighbor list
class NeighList *list;
// energy of the electronic system
double Ee;
size_t n; // size of peratom arrays
// friction force
double **f_EPH; // size = [nlocal][3] // TODO: try switching to vector
// random force
double **f_RNG; // size = [nlocal][3] // TODO: try switching to vector
// Electronic density at each atom
double* rho_i; // size = [nlocal] // TODO: try switching to vector
// Inverse of electronic density in order to avoid 1./rho_i
double* inv_rho_i; // size = [nlocal] // TODO: try switching to vector
// dissipation vector W_ij v_j
double** w_i; // size = [nlocal][3] // TODO: try switching to vector
// random numbers
double **xi_i; // size = [nlocal][3] // TODO: try switching to vector
// electronic temperature per atom
double* T_e_i; // size = [nlocal + nghost]
// per atom array
double **array; // size = [nlocal][8] // TODO: try switching to vector
// private member functions
void calculate_environment(); // calculate the site density and coupling for every atom
void force_prl(); // PRL model with full functionality
// TODO: remove
static Float get_scalar(const Float* x, const Float* y)
{
return x[0]*y[0] + x[1]*y[1] + x[2]*y[2];
}
static Float get_norm(const Float* x)
{
return x[0]*x[0] + x[1]*x[1] + x[2]*x[2];
}
static Float get_distance_sq(const Float* x, const Float* y)
{
Float dxy[3];
dxy[0] = x[0] - y[0];
dxy[1] = x[1] - y[1];
dxy[2] = x[2] - y[2];
return get_norm(dxy);
}
// TODO: add restrict
static Float get_difference_sq(const Float* x, const Float* y, Float* __restrict z)
{
z[0] = x[0] - y[0];
z[1] = x[1] - y[1];
z[2] = x[2] - y[2];
return get_norm(z);
}
};
}
#endif
#endif