// clang-format off /* ---------------------------------------------------------------------- LAMMPS - Large-scale Atomic/Molecular Massively Parallel Simulator https://www.lammps.org/, Sandia National Laboratories Steve Plimpton, sjplimp@sandia.gov This software is distributed under the GNU General Public License. See the README file in the top-level LAMMPS directory. ------------------------------------------------------------------------- */ /* ---------------------------------------------------------------------- Contributing author: Axel Kohlmeyer (Temple U) ------------------------------------------------------------------------- */ #include "pair_eam_omp.h" #include "atom.h" #include "comm.h" #include "force.h" #include "memory.h" #include "neigh_list.h" #include "suffix.h" #include #include "omp_compat.h" using namespace LAMMPS_NS; /* ---------------------------------------------------------------------- */ PairEAMOMP::PairEAMOMP(LAMMPS *lmp) : PairEAM(lmp), ThrOMP(lmp, THR_PAIR) { suffix_flag |= Suffix::OMP; respa_enable = 0; } /* ---------------------------------------------------------------------- */ void PairEAMOMP::compute(int eflag, int vflag) { ev_init(eflag,vflag); const int nall = atom->nlocal + atom->nghost; const int nthreads = comm->nthreads; const int inum = list->inum; // grow energy and fp arrays if necessary // need to be atom->nmax in length if (atom->nmax > nmax) { memory->destroy(rho); memory->destroy(fp); memory->destroy(numforce); nmax = atom->nmax; memory->create(rho,nthreads*nmax,"pair:rho"); memory->create(fp,nmax,"pair:fp"); memory->create(numforce,nmax,"pair:numforce"); } #if defined(_OPENMP) #pragma omp parallel LMP_DEFAULT_NONE LMP_SHARED(eflag,vflag) #endif { int ifrom, ito, tid; loop_setup_thr(ifrom, ito, tid, inum, nthreads); ThrData *thr = fix->get_thr(tid); thr->timer(Timer::START); ev_setup_thr(eflag, vflag, nall, eatom, vatom, nullptr, thr); if (force->newton_pair) thr->init_eam(nall, rho); else thr->init_eam(atom->nlocal, rho); if (evflag) { if (eflag) { if (force->newton_pair) eval<1,1,1>(ifrom, ito, thr); else eval<1,1,0>(ifrom, ito, thr); } else { if (force->newton_pair) eval<1,0,1>(ifrom, ito, thr); else eval<1,0,0>(ifrom, ito, thr); } } else { if (force->newton_pair) eval<0,0,1>(ifrom, ito, thr); else eval<0,0,0>(ifrom, ito, thr); } thr->timer(Timer::PAIR); reduce_thr(this, eflag, vflag, thr); } // end of omp parallel region } template void PairEAMOMP::eval(int iifrom, int iito, ThrData * const thr) { int i,j,ii,jj,m,jnum,itype,jtype; double xtmp,ytmp,ztmp,delx,dely,delz,evdwl,fpair; double rsq,r,p,rhoip,rhojp,z2,z2p,recip,phip,psip,phi; double *coeff; int *ilist,*jlist,*numneigh,**firstneigh; evdwl = 0.0; const auto * _noalias const x = (dbl3_t *) atom->x[0]; auto * _noalias const f = (dbl3_t *) thr->get_f()[0]; double * const rho_t = thr->get_rho(); const int tid = thr->get_tid(); const int nthreads = comm->nthreads; const int * _noalias const type = atom->type; const int nlocal = atom->nlocal; const int nall = nlocal + atom->nghost; double fxtmp,fytmp,fztmp; ilist = list->ilist; numneigh = list->numneigh; firstneigh = list->firstneigh; // rho = density at each atom // loop over neighbors of my atoms for (ii = iifrom; ii < iito; ii++) { i = ilist[ii]; xtmp = x[i].x; ytmp = x[i].y; ztmp = x[i].z; itype = type[i]; jlist = firstneigh[i]; jnum = numneigh[i]; for (jj = 0; jj < jnum; jj++) { j = jlist[jj]; j &= NEIGHMASK; delx = xtmp - x[j].x; dely = ytmp - x[j].y; delz = ztmp - x[j].z; rsq = delx*delx + dely*dely + delz*delz; if (rsq < cutforcesq) { jtype = type[j]; p = sqrt(rsq)*rdr + 1.0; m = static_cast (p); m = MIN(m,nr-1); p -= m; p = MIN(p,1.0); coeff = rhor_spline[type2rhor[jtype][itype]][m]; rho_t[i] += ((coeff[3]*p + coeff[4])*p + coeff[5])*p + coeff[6]; if (NEWTON_PAIR || j < nlocal) { coeff = rhor_spline[type2rhor[itype][jtype]][m]; rho_t[j] += ((coeff[3]*p + coeff[4])*p + coeff[5])*p + coeff[6]; } } } } // wait until all threads are done with computation sync_threads(); // communicate and sum densities if (NEWTON_PAIR) { // reduce per thread density thr->timer(Timer::PAIR); data_reduce_thr(rho, nall, nthreads, 1, tid); // wait until reduction is complete sync_threads(); #if defined(_OPENMP) #pragma omp master #endif { comm->reverse_comm(this); } // wait until master thread is done with communication sync_threads(); } else { thr->timer(Timer::PAIR); data_reduce_thr(rho, nlocal, nthreads, 1, tid); // wait until reduction is complete sync_threads(); } // fp = derivative of embedding energy at each atom // phi = embedding energy at each atom // if rho > rhomax (e.g. due to close approach of two atoms), // will exceed table, so add linear term to conserve energy for (ii = iifrom; ii < iito; ii++) { i = ilist[ii]; p = rho[i]*rdrho + 1.0; m = static_cast (p); m = MAX(1,MIN(m,nrho-1)); p -= m; p = MIN(p,1.0); coeff = frho_spline[type2frho[type[i]]][m]; fp[i] = (coeff[0]*p + coeff[1])*p + coeff[2]; if (EFLAG) { phi = ((coeff[3]*p + coeff[4])*p + coeff[5])*p + coeff[6]; if (rho[i] > rhomax) phi += fp[i] * (rho[i]-rhomax); e_tally_thr(this, i, i, nlocal, NEWTON_PAIR, scale[type[i]][type[i]]*phi, 0.0, thr); } } // wait until all theads are done with computation sync_threads(); // communicate derivative of embedding function // MPI communication only on master thread #if defined(_OPENMP) #pragma omp master #endif { comm->forward_comm(this); } // wait until master thread is done with communication sync_threads(); // compute forces on each atom // loop over neighbors of my atoms for (ii = iifrom; ii < iito; ii++) { i = ilist[ii]; xtmp = x[i].x; ytmp = x[i].y; ztmp = x[i].z; itype = type[i]; fxtmp = fytmp = fztmp = 0.0; const double * _noalias const scale_i = scale[itype]; jlist = firstneigh[i]; jnum = numneigh[i]; numforce[i] = 0; for (jj = 0; jj < jnum; jj++) { j = jlist[jj]; j &= NEIGHMASK; delx = xtmp - x[j].x; dely = ytmp - x[j].y; delz = ztmp - x[j].z; rsq = delx*delx + dely*dely + delz*delz; if (rsq < cutforcesq) { ++numforce[i]; jtype = type[j]; r = sqrt(rsq); p = r*rdr + 1.0; m = static_cast (p); m = MIN(m,nr-1); p -= m; p = MIN(p,1.0); // rhoip = derivative of (density at atom j due to atom i) // rhojp = derivative of (density at atom i due to atom j) // phi = pair potential energy // phip = phi' // z2 = phi * r // z2p = (phi * r)' = (phi' r) + phi // psip needs both fp[i] and fp[j] terms since r_ij appears in two // terms of embed eng: Fi(sum rho_ij) and Fj(sum rho_ji) // hence embed' = Fi(sum rho_ij) rhojp + Fj(sum rho_ji) rhoip coeff = rhor_spline[type2rhor[itype][jtype]][m]; rhoip = (coeff[0]*p + coeff[1])*p + coeff[2]; coeff = rhor_spline[type2rhor[jtype][itype]][m]; rhojp = (coeff[0]*p + coeff[1])*p + coeff[2]; coeff = z2r_spline[type2z2r[itype][jtype]][m]; z2p = (coeff[0]*p + coeff[1])*p + coeff[2]; z2 = ((coeff[3]*p + coeff[4])*p + coeff[5])*p + coeff[6]; recip = 1.0/r; phi = z2*recip; phip = z2p*recip - phi*recip; psip = fp[i]*rhojp + fp[j]*rhoip + phip; fpair = -scale_i[jtype]*psip*recip; fxtmp += delx*fpair; fytmp += dely*fpair; fztmp += delz*fpair; if (NEWTON_PAIR || j < nlocal) { f[j].x -= delx*fpair; f[j].y -= dely*fpair; f[j].z -= delz*fpair; } if (EFLAG) evdwl = scale_i[jtype]*phi; if (EVFLAG) ev_tally_thr(this, i,j,nlocal,NEWTON_PAIR, evdwl,0.0,fpair,delx,dely,delz,thr); } } f[i].x += fxtmp; f[i].y += fytmp; f[i].z += fztmp; } } /* ---------------------------------------------------------------------- */ double PairEAMOMP::memory_usage() { double bytes = memory_usage_thr(); bytes += PairEAM::memory_usage(); return bytes; }