pair_tersoff_table.cpp
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Created: Fri, Jun 21, 13:54

pair_tersoff_table.cpp
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	/* ----------------------------------------------------------------------
	LAMMPS - Large-scale Atomic/Molecular Massively Parallel Simulator
	http://lammps.sandia.gov, Sandia National Laboratories
	Steve Plimpton, sjplimp@sandia.gov

	Copyright (2003) Sandia Corporation. Under the terms of Contract
	DE-AC04-94AL85000 with Sandia Corporation, the U.S. Government retains
	certain rights in this software. This software is distributed under
	the GNU General Public License.

	See the README file in the top-level LAMMPS directory.
	------------------------------------------------------------------------- */

	/* ----------------------------------------------------------------------
	Contributing author: Luca Ferraro (CASPUR)
	email: luca.ferraro@caspur.it

	Tersoff Potential
	References: (referenced as tersoff_2 functional form in LAMMPS manual)
	1) Tersoff, Phys. Rev. B 39, 5566 (1988)
	------------------------------------------------------------------------- */

	#include "math.h"
	#include "stdio.h"
	#include "stdlib.h"
	#include "string.h"
	#include "pair_tersoff_table.h"
	#include "atom.h"
	#include "neighbor.h"
	#include "neigh_list.h"
	#include "neigh_request.h"
	#include "force.h"
	#include "comm.h"
	#include "memory.h"

	#include "error.h"

	using namespace LAMMPS_NS;

	#define MAXLINE 1024
	#define DELTA 4

	#define GRIDSTART 0.1
	#define GRIDDENSITY_FCUTOFF 5000
	#define GRIDDENSITY_EXP 12000
	#define GRIDDENSITY_GTETA 12000
	#define GRIDDENSITY_BIJ 7500

	// max number of interaction per atom for environment potential

	#define leadingDimensionInteractionList 64

	/* ---------------------------------------------------------------------- */

	PairTersoffTable::PairTersoffTable(LAMMPS *lmp) : Pair(lmp)
	{
	single_enable = 0;
	one_coeff = 1;
	manybody_flag = 1;

	nelements = 0;
	elements = NULL;
	nparams = maxparam = 0;
	params = NULL;
	elem2param = NULL;
	allocated = 0;

	preGtetaFunction = preGtetaFunctionDerived = NULL;
	preCutoffFunction = preCutoffFunctionDerived = NULL;
	}

	/* ----------------------------------------------------------------------
	check if allocated, since class can be destructed when incomplete
	------------------------------------------------------------------------- */

	PairTersoffTable::~PairTersoffTable()
	{
	if (elements)
	for (int i = 0; i < nelements; i++) delete [] elements[i];
	delete [] elements;
	memory->destroy(params);
	memory->destroy(elem2param);

	if (allocated) {
	memory->destroy(setflag);
	memory->destroy(cutsq);
	delete [] map;

	deallocateGrids();
	deallocatePreLoops();
	}
	}

	/* ---------------------------------------------------------------------- */

	void PairTersoffTable::compute(int eflag, int vflag)
	{
	int i,j,k,ii,inum,jnum;
	int itype,jtype,ktype,ijparam,ikparam,ijkparam;
	double xtmp,ytmp,ztmp;
	double fxtmp,fytmp,fztmp;
	int ilist,jlist,numneigh,*firstneigh;


	int interpolIDX;
	double directorCos_ij_x, directorCos_ij_y, directorCos_ij_z, directorCos_ik_x, directorCos_ik_y, directorCos_ik_z;
	double invR_ij, invR_ik, cosTeta;
	double repulsivePotential, attractivePotential;
	double exponentRepulsivePotential, exponentAttractivePotential,interpolTMP,interpolDeltaX,interpolY1;
	double interpolY2, cutoffFunctionIJ, attractiveExponential, repulsiveExponential, cutoffFunctionDerivedIJ,zeta;
	double gtetaFunctionIJK,gtetaFunctionDerivedIJK,cutoffFunctionIK;
	double cutoffFunctionDerivedIK,factor_force3_ij,factor_1_force3_ik;
	double factor_2_force3_ik,betaZetaPowerIJK,betaZetaPowerDerivedIJK,factor_force_tot;
	double factor_force_ij;
	double gtetaFunctionDerived_temp,gtetaFunction_temp;

	double evdwl = 0.0;

	if (eflag \|\| vflag) ev_setup(eflag,vflag);
	else evflag = vflag_fdotr = 0;

	double **x = atom->x;
	double **f = atom->f;
	int *type = atom->type;
	int nlocal = atom->nlocal;
	int newton_pair = force->newton_pair;

	inum = list->inum;
	ilist = list->ilist;
	numneigh = list->numneigh;
	firstneigh = list->firstneigh;

	// loop over full neighbor list of my atoms
	for (ii = 0; ii < inum; ii++) {

	i = ilist[ii];
	itype = map[type[i]];
	xtmp = x[i][0];
	ytmp = x[i][1];
	ztmp = x[i][2];
	fxtmp = fytmp = fztmp = 0.0;

	jlist = firstneigh[i];
	jnum = numneigh[i];

	if (jnum > leadingDimensionInteractionList) {
	char errmsg[256];
	sprintf(errmsg,"Too many neighbors for interaction list: %d vs %d.\n"
	"Check your system or increase 'leadingDimensionInteractionList'",
	jnum, leadingDimensionInteractionList);
	error->one(FLERR,errmsg);
	}

	// Pre-calculate gteta and cutoff function
	for (int neighbor_j = 0; neighbor_j < jnum; neighbor_j++) {

	double dr_ij[3], r_ij;

	j = jlist[neighbor_j];
	j &= NEIGHMASK;

	dr_ij[0] = xtmp - x[j][0];
	dr_ij[1] = ytmp - x[j][1];
	dr_ij[2] = ztmp - x[j][2];
	r_ij = dr_ij[0]dr_ij[0] + dr_ij[1]dr_ij[1] + dr_ij[2]*dr_ij[2];

	jtype = map[type[j]];
	ijparam = elem2param[itype][jtype][jtype];

	if (r_ij > params[ijparam].cutsq) continue;

	r_ij = sqrt(r_ij);

	invR_ij = 1.0 / r_ij;

	directorCos_ij_x = invR_ij * dr_ij[0];
	directorCos_ij_y = invR_ij * dr_ij[1];
	directorCos_ij_z = invR_ij * dr_ij[2];

	// preCutoffFunction
	interpolDeltaX = r_ij - GRIDSTART;
	interpolTMP = (interpolDeltaX * GRIDDENSITY_FCUTOFF);
	interpolIDX = (int) interpolTMP;
	interpolY1 = cutoffFunction[itype][jtype][interpolIDX];
	interpolY2 = cutoffFunction[itype][jtype][interpolIDX+1];
	preCutoffFunction[neighbor_j] = interpolY1 + (interpolY2 - interpolY1) * (interpolTMP - interpolIDX);
	// preCutoffFunctionDerived
	interpolY1 = cutoffFunctionDerived[itype][jtype][interpolIDX];
	interpolY2 = cutoffFunctionDerived[itype][jtype][interpolIDX+1];
	preCutoffFunctionDerived[neighbor_j] = interpolY1 + (interpolY2 - interpolY1) * (interpolTMP - interpolIDX);


	for (int neighbor_k = neighbor_j + 1; neighbor_k < jnum; neighbor_k++) {
	double dr_ik[3], r_ik;

	k = jlist[neighbor_k];
	k &= NEIGHMASK;
	ktype = map[type[k]];
	ikparam = elem2param[itype][ktype][ktype];
	ijkparam = elem2param[itype][jtype][ktype];

	dr_ik[0] = xtmp -x[k][0];
	dr_ik[1] = ytmp -x[k][1];
	dr_ik[2] = ztmp -x[k][2];
	r_ik = dr_ik[0]dr_ik[0] + dr_ik[1]dr_ik[1] + dr_ik[2]*dr_ik[2];

	if (r_ik > params[ikparam].cutsq) continue;

	r_ik = sqrt(r_ik);

	invR_ik = 1.0 / r_ik;

	directorCos_ik_x = invR_ik * dr_ik[0];
	directorCos_ik_y = invR_ik * dr_ik[1];
	directorCos_ik_z = invR_ik * dr_ik[2];

	cosTeta = directorCos_ij_x * directorCos_ik_x + directorCos_ij_y * directorCos_ik_y + directorCos_ij_z * directorCos_ik_z;

	// preGtetaFunction
	interpolDeltaX=cosTeta+1.0;
	interpolTMP = (interpolDeltaX * GRIDDENSITY_GTETA);
	interpolIDX = (int) interpolTMP;
	interpolY1 = gtetaFunction[itype][interpolIDX];
	interpolY2 = gtetaFunction[itype][interpolIDX+1];
	gtetaFunction_temp = interpolY1 + (interpolY2 - interpolY1) * (interpolTMP - interpolIDX);
	// preGtetaFunctionDerived
	interpolY1 = gtetaFunctionDerived[itype][interpolIDX];
	interpolY2 = gtetaFunctionDerived[itype][interpolIDX+1];
	gtetaFunctionDerived_temp = interpolY1 + (interpolY2 - interpolY1) * (interpolTMP - interpolIDX);

	preGtetaFunction[neighbor_j][neighbor_k]=params[ijkparam].gamma*gtetaFunction_temp;
	preGtetaFunctionDerived[neighbor_j][neighbor_k]=params[ijkparam].gamma*gtetaFunctionDerived_temp;
	preGtetaFunction[neighbor_k][neighbor_j]=params[ijkparam].gamma*gtetaFunction_temp;
	preGtetaFunctionDerived[neighbor_k][neighbor_j]=params[ijkparam].gamma*gtetaFunctionDerived_temp;

	} // loop on K

	} // loop on J


	// loop over neighbors of atom i
	for (int neighbor_j = 0; neighbor_j < jnum; neighbor_j++) {

	double dr_ij[3], r_ij, f_ij[3];

	j = jlist[neighbor_j];
	j &= NEIGHMASK;

	dr_ij[0] = xtmp - x[j][0];
	dr_ij[1] = ytmp - x[j][1];
	dr_ij[2] = ztmp - x[j][2];
	r_ij = dr_ij[0]dr_ij[0] + dr_ij[1]dr_ij[1] + dr_ij[2]*dr_ij[2];

	jtype = map[type[j]];
	ijparam = elem2param[itype][jtype][jtype];

	if (r_ij > params[ijparam].cutsq) continue;

	r_ij = sqrt(r_ij);
	invR_ij = 1.0 / r_ij;

	directorCos_ij_x = invR_ij * dr_ij[0];
	directorCos_ij_y = invR_ij * dr_ij[1];
	directorCos_ij_z = invR_ij * dr_ij[2];

	exponentRepulsivePotential = params[ijparam].lam1 * r_ij;
	exponentAttractivePotential = params[ijparam].lam2 * r_ij;

	// repulsiveExponential
	interpolDeltaX = exponentRepulsivePotential - minArgumentExponential;
	interpolTMP = (interpolDeltaX * GRIDDENSITY_EXP);
	interpolIDX = (int) interpolTMP;
	interpolY1 = exponential[interpolIDX];
	interpolY2 = exponential[interpolIDX+1];
	repulsiveExponential = interpolY1 + (interpolY2 - interpolY1) * (interpolTMP - interpolIDX);
	// attractiveExponential
	interpolDeltaX = exponentAttractivePotential - minArgumentExponential;
	interpolTMP = (interpolDeltaX * GRIDDENSITY_EXP);
	interpolIDX = (int) interpolTMP;
	interpolY1 = exponential[interpolIDX];
	interpolY2 = exponential[interpolIDX+1];
	attractiveExponential = interpolY1 + (interpolY2 - interpolY1) * (interpolTMP - interpolIDX);

	repulsivePotential = params[ijparam].biga * repulsiveExponential;
	attractivePotential = -params[ijparam].bigb * attractiveExponential;

	cutoffFunctionIJ = preCutoffFunction[neighbor_j];
	cutoffFunctionDerivedIJ = preCutoffFunctionDerived[neighbor_j];

	zeta = 0.0;

	// first loop over neighbors of atom i except j - part 1/2
	for (int neighbor_k = 0; neighbor_k < neighbor_j; neighbor_k++) {
	double dr_ik[3], r_ik;

	k = jlist[neighbor_k];
	k &= NEIGHMASK;
	ktype = map[type[k]];
	ikparam = elem2param[itype][ktype][ktype];
	ijkparam = elem2param[itype][jtype][ktype];

	dr_ik[0] = xtmp -x[k][0];
	dr_ik[1] = ytmp -x[k][1];
	dr_ik[2] = ztmp -x[k][2];
	r_ik = dr_ik[0]dr_ik[0] + dr_ik[1]dr_ik[1] + dr_ik[2]*dr_ik[2];

	if (r_ik > params[ikparam].cutsq) continue;

	r_ik = sqrt(r_ik);

	invR_ik = 1.0 / r_ik;

	gtetaFunctionIJK = preGtetaFunction[neighbor_j][neighbor_k];

	cutoffFunctionIK = preCutoffFunction[neighbor_k];

	zeta += cutoffFunctionIK * gtetaFunctionIJK;

	}

	// first loop over neighbors of atom i except j - part 2/2
	for (int neighbor_k = neighbor_j+1; neighbor_k < jnum; neighbor_k++) {
	double dr_ik[3], r_ik;

	k = jlist[neighbor_k];
	k &= NEIGHMASK;
	ktype = map[type[k]];
	ikparam = elem2param[itype][ktype][ktype];
	ijkparam = elem2param[itype][jtype][ktype];

	dr_ik[0] = xtmp -x[k][0];
	dr_ik[1] = ytmp -x[k][1];
	dr_ik[2] = ztmp -x[k][2];
	r_ik = dr_ik[0]dr_ik[0] + dr_ik[1]dr_ik[1] + dr_ik[2]*dr_ik[2];

	if (r_ik > params[ikparam].cutsq) continue;

	r_ik = sqrt(r_ik);
	invR_ik = 1.0 / r_ik;

	directorCos_ik_x = invR_ik * dr_ik[0];
	directorCos_ik_y = invR_ik * dr_ik[1];
	directorCos_ik_z = invR_ik * dr_ik[2];

	gtetaFunctionIJK = preGtetaFunction[neighbor_j][neighbor_k];

	cutoffFunctionIK = preCutoffFunction[neighbor_k];

	zeta += cutoffFunctionIK * gtetaFunctionIJK;
	}

	// betaZetaPowerIJK
	interpolDeltaX= params[ijparam].beta * zeta;
	interpolTMP = (interpolDeltaX * GRIDDENSITY_BIJ);
	interpolIDX = (int) interpolTMP;
	interpolY1 = betaZetaPower[itype][interpolIDX];
	interpolY2 = betaZetaPower[itype][interpolIDX+1];
	betaZetaPowerIJK = (interpolY1 + (interpolY2 - interpolY1) * (interpolTMP - interpolIDX));
	// betaZetaPowerDerivedIJK
	interpolY1 = betaZetaPowerDerived[itype][interpolIDX];
	interpolY2 = betaZetaPowerDerived[itype][interpolIDX+1];
	betaZetaPowerDerivedIJK = params[ijparam].beta(interpolY1 + (interpolY2 - interpolY1) (interpolTMP - interpolIDX));

	// Forces and virial
	factor_force_ij = 0.5cutoffFunctionDerivedIJ(repulsivePotential + attractivePotential * betaZetaPowerIJK)+0.5cutoffFunctionIJ(-repulsivePotentialparams[ijparam].lam1-betaZetaPowerIJKattractivePotential*params[ijparam].lam2);

	f_ij[0] = factor_force_ij * directorCos_ij_x;
	f_ij[1] = factor_force_ij * directorCos_ij_y;
	f_ij[2] = factor_force_ij * directorCos_ij_z;

	f[j][0] += f_ij[0];
	f[j][1] += f_ij[1];
	f[j][2] += f_ij[2];

	fxtmp -= f_ij[0];
	fytmp -= f_ij[1];
	fztmp -= f_ij[2];

	// potential energy
	evdwl = cutoffFunctionIJ * repulsivePotential + cutoffFunctionIJ * attractivePotential * betaZetaPowerIJK;

	if (evflag) ev_tally(i, j, nlocal, newton_pair, 0.5 * evdwl, 0.0,
	-factor_force_ij*invR_ij, dr_ij[0], dr_ij[1], dr_ij[2]);

	factor_force_tot= 0.5cutoffFunctionIJattractivePotential*betaZetaPowerDerivedIJK;

	// second loop over neighbors of atom i except j, forces and virial only - part 1/2
	for (int neighbor_k = 0; neighbor_k < neighbor_j; neighbor_k++) {
	double dr_ik[3], r_ik, f_ik[3];

	k = jlist[neighbor_k];
	k &= NEIGHMASK;
	ktype = map[type[k]];
	ikparam = elem2param[itype][ktype][ktype];
	ijkparam = elem2param[itype][jtype][ktype];

	dr_ik[0] = xtmp -x[k][0];
	dr_ik[1] = ytmp -x[k][1];
	dr_ik[2] = ztmp -x[k][2];
	r_ik = dr_ik[0]dr_ik[0] + dr_ik[1]dr_ik[1] + dr_ik[2]*dr_ik[2];

	if (r_ik > params[ikparam].cutsq) continue;

	r_ik = sqrt(r_ik);
	invR_ik = 1.0 / r_ik;

	directorCos_ik_x = invR_ik * dr_ik[0];
	directorCos_ik_y = invR_ik * dr_ik[1];
	directorCos_ik_z = invR_ik * dr_ik[2];

	cosTeta = directorCos_ij_x * directorCos_ik_x + directorCos_ij_y * directorCos_ik_y + directorCos_ij_z * directorCos_ik_z;

	gtetaFunctionIJK = preGtetaFunction[neighbor_j][neighbor_k];

	gtetaFunctionDerivedIJK = preGtetaFunctionDerived[neighbor_j][neighbor_k];

	cutoffFunctionIK = preCutoffFunction[neighbor_k];

	cutoffFunctionDerivedIK = preCutoffFunctionDerived[neighbor_k];

	factor_force3_ij= cutoffFunctionIK * gtetaFunctionDerivedIJK * invR_ij *factor_force_tot;

	f_ij[0] = factor_force3_ij * (directorCos_ij_x*cosTeta - directorCos_ik_x);
	f_ij[1] = factor_force3_ij * (directorCos_ij_y*cosTeta - directorCos_ik_y);
	f_ij[2] = factor_force3_ij * (directorCos_ij_z*cosTeta - directorCos_ik_z);

	factor_1_force3_ik = (cutoffFunctionIK * gtetaFunctionDerivedIJK * invR_ik)*factor_force_tot;
	factor_2_force3_ik = -(cutoffFunctionDerivedIK * gtetaFunctionIJK)*factor_force_tot;

	f_ik[0] = factor_1_force3_ik * (directorCos_ik_xcosTeta - directorCos_ij_x) + factor_2_force3_ik directorCos_ik_x;
	f_ik[1] = factor_1_force3_ik * (directorCos_ik_ycosTeta - directorCos_ij_y) + factor_2_force3_ik directorCos_ik_y;
	f_ik[2] = factor_1_force3_ik * (directorCos_ik_zcosTeta - directorCos_ij_z) + factor_2_force3_ik directorCos_ik_z;

	f[j][0] -= f_ij[0];
	f[j][1] -= f_ij[1];
	f[j][2] -= f_ij[2];

	f[k][0] -= f_ik[0];
	f[k][1] -= f_ik[1];
	f[k][2] -= f_ik[2];

	fxtmp += f_ij[0] + f_ik[0];
	fytmp += f_ij[1] + f_ik[1];
	fztmp += f_ij[2] + f_ik[2];

	// potential energy
	evdwl = 0.0;

	if (evflag) ev_tally3(i,j,k,evdwl,0.0,f_ij,f_ik,dr_ij,dr_ik);
	}

	// second loop over neighbors of atom i except j, forces and virial only - part 2/2
	for (int neighbor_k = neighbor_j+1; neighbor_k < jnum; neighbor_k++) {
	double dr_ik[3], r_ik, f_ik[3];

	k = jlist[neighbor_k];
	k &= NEIGHMASK;
	ktype = map[type[k]];
	ikparam = elem2param[itype][ktype][ktype];
	ijkparam = elem2param[itype][jtype][ktype];

	dr_ik[0] = xtmp -x[k][0];
	dr_ik[1] = ytmp -x[k][1];
	dr_ik[2] = ztmp -x[k][2];
	r_ik = dr_ik[0]dr_ik[0] + dr_ik[1]dr_ik[1] + dr_ik[2]*dr_ik[2];

	if (r_ik > params[ikparam].cutsq) continue;

	r_ik = sqrt(r_ik);
	invR_ik = 1.0 / r_ik;

	directorCos_ik_x = invR_ik * dr_ik[0];
	directorCos_ik_y = invR_ik * dr_ik[1];
	directorCos_ik_z = invR_ik * dr_ik[2];

	cosTeta = directorCos_ij_x * directorCos_ik_x + directorCos_ij_y * directorCos_ik_y + directorCos_ij_z * directorCos_ik_z;

	gtetaFunctionIJK = preGtetaFunction[neighbor_j][neighbor_k];

	gtetaFunctionDerivedIJK = preGtetaFunctionDerived[neighbor_j][neighbor_k];

	cutoffFunctionIK = preCutoffFunction[neighbor_k];

	cutoffFunctionDerivedIK = preCutoffFunctionDerived[neighbor_k];

	factor_force3_ij= cutoffFunctionIK * gtetaFunctionDerivedIJK * invR_ij *factor_force_tot;

	f_ij[0] = factor_force3_ij * (directorCos_ij_x*cosTeta - directorCos_ik_x);
	f_ij[1] = factor_force3_ij * (directorCos_ij_y*cosTeta - directorCos_ik_y);
	f_ij[2] = factor_force3_ij * (directorCos_ij_z*cosTeta - directorCos_ik_z);

	factor_1_force3_ik = (cutoffFunctionIK * gtetaFunctionDerivedIJK * invR_ik)*factor_force_tot;
	factor_2_force3_ik = -(cutoffFunctionDerivedIK * gtetaFunctionIJK)*factor_force_tot;

	f_ik[0] = factor_1_force3_ik * (directorCos_ik_xcosTeta - directorCos_ij_x) + factor_2_force3_ik directorCos_ik_x;
	f_ik[1] = factor_1_force3_ik * (directorCos_ik_ycosTeta - directorCos_ij_y) + factor_2_force3_ik directorCos_ik_y;
	f_ik[2] = factor_1_force3_ik * (directorCos_ik_zcosTeta - directorCos_ij_z) + factor_2_force3_ik directorCos_ik_z;

	f[j][0] -= f_ij[0];
	f[j][1] -= f_ij[1];
	f[j][2] -= f_ij[2];

	f[k][0] -= f_ik[0];
	f[k][1] -= f_ik[1];
	f[k][2] -= f_ik[2];

	fxtmp += f_ij[0] + f_ik[0];
	fytmp += f_ij[1] + f_ik[1];
	fztmp += f_ij[2] + f_ik[2];

	// potential energy
	evdwl = 0.0;

	if (evflag) ev_tally3(i,j,k,evdwl,0.0,f_ij,f_ik,dr_ij,dr_ik);

	}
	} // loop on J
	f[i][0] += fxtmp;
	f[i][1] += fytmp;
	f[i][2] += fztmp;
	} // loop on I

	if (vflag_fdotr) virial_fdotr_compute();
	}

	/* ---------------------------------------------------------------------- */

	void PairTersoffTable::deallocatePreLoops(void)
	{
	memory->destroy(preGtetaFunction);
	memory->destroy(preGtetaFunctionDerived);
	memory->destroy(preCutoffFunction);
	memory->destroy(preCutoffFunctionDerived);
	}

	void PairTersoffTable::allocatePreLoops(void)
	{
	memory->create(preGtetaFunction,leadingDimensionInteractionList,leadingDimensionInteractionList,"tersofftable:preGtetaFunction");

	memory->create(preGtetaFunctionDerived,leadingDimensionInteractionList,leadingDimensionInteractionList,"tersofftable:preGtetaFunctionDerived");

	memory->create(preCutoffFunction,leadingDimensionInteractionList,"tersofftable:preCutoffFunction");

	memory->create(preCutoffFunctionDerived,leadingDimensionInteractionList,"tersofftable:preCutoffFunctionDerived");
	}

	void PairTersoffTable::deallocateGrids()
	{
	memory->destroy(exponential);
	memory->destroy(gtetaFunction);
	memory->destroy(gtetaFunctionDerived);
	memory->destroy(cutoffFunction);
	memory->destroy(cutoffFunctionDerived);
	memory->destroy(betaZetaPower);
	memory->destroy(betaZetaPowerDerived);
	}

	void PairTersoffTable::allocateGrids(void)
	{
	int i, j, l;

	int numGridPointsExponential, numGridPointsGtetaFunction, numGridPointsOneCutoffFunction;
	int numGridPointsNotOneCutoffFunction, numGridPointsCutoffFunction, numGridPointsBetaZetaPower;
	// double minArgumentExponential;
	double deltaArgumentCutoffFunction, deltaArgumentExponential, deltaArgumentBetaZetaPower;
	double deltaArgumentGtetaFunction;
	double r, minMu, maxLambda, maxCutoff;
	double const PI=acos(-1.0);

	// exponential

	// find min and max argument
	minMu=params[0].lam2;
	maxLambda=params[0].lam1;
	for (i=1; i<nparams; i++) {
	if (params[i].lam2 < minMu) minMu = params[i].lam2;
	if (params[i].lam1 > maxLambda) maxLambda = params[i].lam1;
	}
	maxCutoff=cutmax;

	minArgumentExponential=minMu*GRIDSTART;

	numGridPointsExponential=(int)((maxLambdamaxCutoff-minArgumentExponential)GRIDDENSITY_EXP)+2;

	memory->create(exponential,numGridPointsExponential,"tersofftable:exponential");

	r = minArgumentExponential;
	deltaArgumentExponential = 1.0 / GRIDDENSITY_EXP;
	for (i = 0; i < numGridPointsExponential; i++)
	{
	exponential[i] = exp(-r);
	r += deltaArgumentExponential;
	}


	// gtetaFunction

	numGridPointsGtetaFunction=(int)(2.0*GRIDDENSITY_GTETA)+2;

	memory->create(gtetaFunction,nelements,numGridPointsGtetaFunction,"tersofftable:gtetaFunction");
	memory->create(gtetaFunctionDerived,nelements,numGridPointsGtetaFunction,"tersofftable:gtetaFunctionDerived");

	r = minArgumentExponential;
	for (i=0; i<nelements; i++) {
	r = -1.0;
	deltaArgumentGtetaFunction = 1.0 / GRIDDENSITY_GTETA;

	int iparam = elem2param[i][i][i];
	double c = params[iparam].c;
	double d = params[iparam].d;
	double h = params[iparam].h;

	for (j = 0; j < numGridPointsGtetaFunction; j++) {
	gtetaFunction[i][j]=1.0+(cc)/(dd)-(cc)/(dd+(h-r)*(h-r));
	gtetaFunctionDerived[i][j]= -2.0 * c * c * (h-r) / ((dd+(h-r)(h-r))(dd+(h-r)*(h-r)));
	r += deltaArgumentGtetaFunction;
	}
	}


	// cutoffFunction, zetaFunction, find grids.

	int ngrid_max = -1;
	int zeta_max = -1;

	for (i=0; i<nelements; i++) {

	int iparam = elem2param[i][i][i];
	double c = params[iparam].c;
	double d = params[iparam].d;
	double beta = params[iparam].beta;

	numGridPointsBetaZetaPower=(int)(((1.0+(cc)/(dd)-(cc)/(dd+4))betaleadingDimensionInteractionList*GRIDDENSITY_BIJ))+2;
	zeta_max = MAX(zeta_max,numGridPointsBetaZetaPower);

	for (j=0; j<nelements; j++) {
	for (j=0; j<nelements; j++) {

	int ijparam = elem2param[i][j][j];
	double cutoffR = params[ijparam].cutoffR;
	double cutoffS = params[ijparam].cutoffS;

	numGridPointsOneCutoffFunction=(int) ((cutoffR-GRIDSTART)*GRIDDENSITY_FCUTOFF)+1;
	numGridPointsNotOneCutoffFunction=(int) ((cutoffS-cutoffR)*GRIDDENSITY_FCUTOFF)+2;
	numGridPointsCutoffFunction=numGridPointsOneCutoffFunction+numGridPointsNotOneCutoffFunction;

	ngrid_max = MAX(ngrid_max,numGridPointsCutoffFunction);
	}
	}
	}

	memory->create(cutoffFunction,nelements,nelements,ngrid_max,"tersoff:cutfunc");
	memory->create(cutoffFunctionDerived,nelements,nelements,ngrid_max,"tersoff:cutfuncD");

	// cutoffFunction, compute.

	for (i=0; i<nelements; i++) {
	for (j=0; j<nelements; j++) {
	for (j=0; j<nelements; j++) {
	int ijparam = elem2param[i][j][j];
	double cutoffR = params[ijparam].cutoffR;
	double cutoffS = params[ijparam].cutoffS;

	numGridPointsOneCutoffFunction=(int) ((cutoffR-GRIDSTART)*GRIDDENSITY_FCUTOFF)+1;
	numGridPointsNotOneCutoffFunction=(int) ((cutoffS-cutoffR)*GRIDDENSITY_FCUTOFF)+2;
	numGridPointsCutoffFunction=numGridPointsOneCutoffFunction+numGridPointsNotOneCutoffFunction;

	r = GRIDSTART;
	deltaArgumentCutoffFunction = 1.0 / GRIDDENSITY_FCUTOFF;

	for (l = 0; l < numGridPointsOneCutoffFunction; l++) {
	cutoffFunction[i][j][l] = 1.0;
	cutoffFunctionDerived[i][j][l]=0.0;
	r += deltaArgumentCutoffFunction;
	}

	for (l = numGridPointsOneCutoffFunction; l < numGridPointsCutoffFunction; l++) {
	cutoffFunction[i][j][l] = 0.5 + 0.5 * cos (PI * (r - cutoffR)/(cutoffS-cutoffR)) ;
	cutoffFunctionDerived[i][j][l] = -0.5 * PI * sin (PI * (r - cutoffR)/(cutoffS-cutoffR)) / (cutoffS-cutoffR) ;
	r += deltaArgumentCutoffFunction;
	}
	}
	}
	}

	// betaZetaPower, compute

	memory->create(betaZetaPower,nelements,zeta_max,"tersoff:zetafunc");
	memory->create(betaZetaPowerDerived,nelements,zeta_max,"tersoff:zetafuncD");

	for (i=0; i<nelements; i++) {

	int iparam = elem2param[i][i][i];
	double c = params[iparam].c;
	double d = params[iparam].d;
	double beta = params[iparam].beta;

	numGridPointsBetaZetaPower=(int)(((1.0+(cc)/(dd)-(cc)/(dd+4))betaleadingDimensionInteractionList*GRIDDENSITY_BIJ))+2;

	r=0.0;
	deltaArgumentBetaZetaPower = 1.0 / GRIDDENSITY_BIJ;

	betaZetaPower[i][0]=1.0;

	r += deltaArgumentBetaZetaPower;

	for (j = 1; j < numGridPointsBetaZetaPower; j++) {
	double powern=params[iparam].powern;
	betaZetaPower[i][j]=pow((1+pow(r,powern)),-1/(2*powern));
	betaZetaPowerDerived[i][j]=-0.5pow(r,powern-1.0)pow((1+pow(r,powern)),-1/(2*powern)-1) ;
	r += deltaArgumentBetaZetaPower;
	}
	betaZetaPowerDerived[i][0]=(betaZetaPower[i][1]-1.0)*GRIDDENSITY_BIJ;
	}
	}

	void PairTersoffTable::allocate()
	{
	allocated = 1;
	int n = atom->ntypes;

	memory->create(setflag,n+1,n+1,"pair:setflag");
	memory->create(cutsq,n+1,n+1,"pair:cutsq");

	map = new int[n+1];
	}

	/* ----------------------------------------------------------------------
	global settings
	------------------------------------------------------------------------- */

	void PairTersoffTable::settings(int narg, char **arg)
	{
	if (narg != 0) error->all(FLERR,"Illegal pair_style command");
	}

	/* ----------------------------------------------------------------------
	set coeffs for one or more type pairs
	------------------------------------------------------------------------- */

	void PairTersoffTable::coeff(int narg, char **arg)
	{
	int i,j,n;

	if (!allocated) allocate();

	if (narg != 3 + atom->ntypes)
	error->all(FLERR,"Incorrect args for pair coefficients");

	// insure I,J args are * *

	if (strcmp(arg[0],"") != 0 \|\| strcmp(arg[1],"") != 0)
	error->all(FLERR,"Incorrect args for pair coefficients");

	// read args that map atom types to elements in potential file
	// map[i] = which element the Ith atom type is, -1 if NULL
	// nelements = # of unique elements
	// elements = list of element names

	if (elements) {
	for (i = 0; i < nelements; i++) delete [] elements[i];
	delete [] elements;
	}
	elements = new char*[atom->ntypes];
	for (i = 0; i < atom->ntypes; i++) elements[i] = NULL;

	nelements = 0;
	for (i = 3; i < narg; i++) {
	if (strcmp(arg[i],"NULL") == 0) {
	map[i-2] = -1;
	continue;
	}
	for (j = 0; j < nelements; j++)
	if (strcmp(arg[i],elements[j]) == 0) break;
	map[i-2] = j;
	if (j == nelements) {
	n = strlen(arg[i]) + 1;
	elements[j] = new char[n];
	strcpy(elements[j],arg[i]);
	nelements++;
	}
	}

	// read potential file and initialize potential parameters

	read_file(arg[2]);
	setup();

	// clear setflag since coeff() called once with I,J = * *

	n = atom->ntypes;
	for (int i = 1; i <= n; i++)
	for (int j = i; j <= n; j++)
	setflag[i][j] = 0;

	// set setflag i,j for type pairs where both are mapped to elements

	int count = 0;
	for (int i = 1; i <= n; i++)
	for (int j = i; j <= n; j++)
	if (map[i] >= 0 && map[j] >= 0) {
	setflag[i][j] = 1;
	count++;
	}

	if (count == 0) error->all(FLERR,"Incorrect args for pair coefficients");

	// allocate tables and internal structures
	allocatePreLoops();
	allocateGrids();
	}

	/* ----------------------------------------------------------------------
	init specific to this pair style
	------------------------------------------------------------------------- */

	void PairTersoffTable::init_style()
	{
	if (force->newton_pair == 0)
	error->all(FLERR,"Pair style Tersoff requires newton pair on");

	// need a full neighbor list

	int irequest = neighbor->request(this);
	neighbor->requests[irequest]->half = 0;
	neighbor->requests[irequest]->full = 1;
	}

	/* ----------------------------------------------------------------------
	init for one type pair i,j and corresponding j,i
	------------------------------------------------------------------------- */

	double PairTersoffTable::init_one(int i, int j)
	{
	if (setflag[i][j] == 0) error->all(FLERR,"All pair coeffs are not set");

	return cutmax;
	}

	/* ---------------------------------------------------------------------- */

	void PairTersoffTable::read_file(char *file)
	{
	int params_per_line = 17;
	char *words = new char[params_per_line+1];

	memory->sfree(params);
	params = NULL;
	nparams = maxparam = 0;

	// open file on proc 0

	FILE *fp;
	if (comm->me == 0) {
	fp = force->open_potential(file);
	if (fp == NULL) {
	char str[128];
	sprintf(str,"Cannot open Tersoff potential file %s",file);
	error->one(FLERR,str);
	}
	}

	// read each set of params from potential file
	// one set of params can span multiple lines
	// store params if all 3 element tags are in element list

	int n,nwords,ielement,jelement,kelement;
	char line[MAXLINE],*ptr;
	int eof = 0;

	while (1) {
	if (comm->me == 0) {
	ptr = fgets(line,MAXLINE,fp);
	if (ptr == NULL) {
	eof = 1;
	fclose(fp);
	} else n = strlen(line) + 1;
	}
	MPI_Bcast(&eof,1,MPI_INT,0,world);
	if (eof) break;
	MPI_Bcast(&n,1,MPI_INT,0,world);
	MPI_Bcast(line,n,MPI_CHAR,0,world);

	// strip comment, skip line if blank

	if ((ptr = strchr(line,'#'))) *ptr = '\0';
	nwords = atom->count_words(line);
	if (nwords == 0) continue;

	// concatenate additional lines until have params_per_line words

	while (nwords < params_per_line) {
	n = strlen(line);
	if (comm->me == 0) {
	ptr = fgets(&line[n],MAXLINE-n,fp);
	if (ptr == NULL) {
	eof = 1;
	fclose(fp);
	} else n = strlen(line) + 1;
	}
	MPI_Bcast(&eof,1,MPI_INT,0,world);
	if (eof) break;
	MPI_Bcast(&n,1,MPI_INT,0,world);
	MPI_Bcast(line,n,MPI_CHAR,0,world);
	if ((ptr = strchr(line,'#'))) *ptr = '\0';
	nwords = atom->count_words(line);
	}

	if (nwords != params_per_line)
	error->all(FLERR,"Incorrect format in Tersoff potential file");

	// words = ptrs to all words in line

	nwords = 0;
	words[nwords++] = strtok(line," \t\n\r\f");
	while ((words[nwords++] = strtok(NULL," \t\n\r\f"))) continue;

	// ielement,jelement,kelement = 1st args
	// if all 3 args are in element list, then parse this line
	// else skip to next entry in file

	for (ielement = 0; ielement < nelements; ielement++)
	if (strcmp(words[0],elements[ielement]) == 0) break;
	if (ielement == nelements) continue;
	for (jelement = 0; jelement < nelements; jelement++)
	if (strcmp(words[1],elements[jelement]) == 0) break;
	if (jelement == nelements) continue;
	for (kelement = 0; kelement < nelements; kelement++)
	if (strcmp(words[2],elements[kelement]) == 0) break;
	if (kelement == nelements) continue;

	// load up parameter settings and error check their values

	if (nparams == maxparam) {
	maxparam += DELTA;
	params = (Param ) memory->srealloc(params,maxparamsizeof(Param),
	"pair:params");
	}

	params[nparams].ielement = ielement;
	params[nparams].jelement = jelement;
	params[nparams].kelement = kelement;
	params[nparams].powerm = atof(words[3]); // not used (only tersoff_2 is implemented)
	params[nparams].gamma = atof(words[4]); // not used (only tersoff_2 is implemented)
	params[nparams].lam3 = atof(words[5]); // not used (only tersoff_2 is implemented)
	params[nparams].c = atof(words[6]);
	params[nparams].d = atof(words[7]);
	params[nparams].h = atof(words[8]);
	params[nparams].powern = atof(words[9]);
	params[nparams].beta = atof(words[10]);
	params[nparams].lam2 = atof(words[11]);
	params[nparams].bigb = atof(words[12]);
	// current implementation is based on functional form
	// of tersoff_2 as reported in the reference paper
	double bigr = atof(words[13]);
	double bigd = atof(words[14]);
	params[nparams].cutoffR = bigr - bigd;
	params[nparams].cutoffS = bigr + bigd;
	params[nparams].lam1 = atof(words[15]);
	params[nparams].biga = atof(words[16]);

	// currently only allow m exponent of 1 or 3
	params[nparams].powermint = int(params[nparams].powerm);

	if (params[nparams].c < 0.0 \|\| params[nparams].d < 0.0 \|\|
	params[nparams].powern < 0.0 \|\| params[nparams].beta < 0.0 \|\|
	params[nparams].lam2 < 0.0 \|\| params[nparams].bigb < 0.0 \|\|
	params[nparams].cutoffR < 0.0 \|\|params[nparams].cutoffS < 0.0 \|\|
	params[nparams].cutoffR > params[nparams].cutoffS \|\|
	params[nparams].lam1 < 0.0 \|\| params[nparams].biga < 0.0
	) error->all(FLERR,"Illegal Tersoff parameter");

	// only tersoff_2 parametrization is implemented
	if (params[nparams].gamma != 1.0 \|\| params[nparams].lam3 != 0.0)
	error->all(FLERR,"Current tersoff/table pair_style implements only tersoff_2 parametrization");
	nparams++;
	}

	delete [] words;
	}

	/* ---------------------------------------------------------------------- */

	void PairTersoffTable::setup()
	{
	int i,j,k,m,n;

	// set elem2param for all triplet combinations
	// must be a single exact match to lines read from file
	// do not allow for ACB in place of ABC

	memory->destroy(elem2param);
	memory->create(elem2param,nelements,nelements,nelements,"pair:elem2param");

	for (i = 0; i < nelements; i++)
	for (j = 0; j < nelements; j++)
	for (k = 0; k < nelements; k++) {
	n = -1;
	for (m = 0; m < nparams; m++) {
	if (i == params[m].ielement && j == params[m].jelement &&
	k == params[m].kelement) {
	if (n >= 0) error->all(FLERR,"Potential file has duplicate entry");
	n = m;
	}
	}
	if (n < 0) error->all(FLERR,"Potential file is missing an entry");
	elem2param[i][j][k] = n;
	}

	// set cutoff square
	for (m = 0; m < nparams; m++) {
	params[m].cut = params[m].cutoffS;
	params[m].cutsq = params[m].cut*params[m].cut;
	}

	// set cutmax to max of all params
	cutmax = 0.0;
	for (m = 0; m < nparams; m++) {
	if (params[m].cut > cutmax) cutmax = params[m].cut;
	}
	}

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