/* * ======================================================================================= * * Author: Jan Eitzinger (je), jan.eitzinger@fau.de * Copyright (c) 2021 RRZE, University Erlangen-Nuremberg * * This file is part of MD-Bench. * * MD-Bench is free software: you can redistribute it and/or modify it * under the terms of the GNU Lesser General Public License as published * by the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * MD-Bench is distributed in the hope that it will be useful, but WITHOUT ANY * WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A * PARTICULAR PURPOSE. See the GNU Lesser General Public License for more * details. * * You should have received a copy of the GNU Lesser General Public License along * with MD-Bench. If not, see . * ======================================================================================= */ #include #include #include #include #include #include double computeForceLJFullNeigh(Parameter *param, Atom *atom, Neighbor *neighbor, Stats *stats) { int Nlocal = atom->Nlocal; int* neighs; MD_FLOAT* fx = atom->fx; MD_FLOAT* fy = atom->fy; MD_FLOAT* fz = atom->fz; #ifndef EXPLICIT_TYPES MD_FLOAT cutforcesq = param->cutforce * param->cutforce; MD_FLOAT sigma6 = param->sigma6; MD_FLOAT epsilon = param->epsilon; #endif for(int i = 0; i < Nlocal; i++) { fx[i] = 0.0; fy[i] = 0.0; fz[i] = 0.0; } double S = getTimeStamp(); LIKWID_MARKER_START("force"); #pragma omp parallel for for(int i = 0; i < Nlocal; i++) { neighs = &neighbor->neighbors[i * neighbor->maxneighs]; int numneighs = neighbor->numneigh[i]; MD_FLOAT xtmp = atom_x(i); MD_FLOAT ytmp = atom_y(i); MD_FLOAT ztmp = atom_z(i); MD_FLOAT fix = 0; MD_FLOAT fiy = 0; MD_FLOAT fiz = 0; #ifdef EXPLICIT_TYPES const int type_i = atom->type[i]; #endif for(int k = 0; k < numneighs; k++) { int j = neighs[k]; MD_FLOAT delx = xtmp - atom_x(j); MD_FLOAT dely = ytmp - atom_y(j); MD_FLOAT delz = ztmp - atom_z(j); MD_FLOAT rsq = delx * delx + dely * dely + delz * delz; #ifdef EXPLICIT_TYPES const int type_j = atom->type[j]; const int type_ij = type_i * atom->ntypes + type_j; const MD_FLOAT cutforcesq = atom->cutforcesq[type_ij]; const MD_FLOAT sigma6 = atom->sigma6[type_ij]; const MD_FLOAT epsilon = atom->epsilon[type_ij]; #endif if(rsq < cutforcesq) { MD_FLOAT sr2 = 1.0 / rsq; MD_FLOAT sr6 = sr2 * sr2 * sr2 * sigma6; MD_FLOAT force = 48.0 * sr6 * (sr6 - 0.5) * sr2 * epsilon; fix += delx * force; fiy += dely * force; fiz += delz * force; #ifdef USE_REFERENCE_VERSION addStat(stats->atoms_within_cutoff, 1); } else { addStat(stats->atoms_outside_cutoff, 1); #endif } } fx[i] += fix; fy[i] += fiy; fz[i] += fiz; addStat(stats->total_force_neighs, numneighs); addStat(stats->total_force_iters, (numneighs + VECTOR_WIDTH - 1) / VECTOR_WIDTH); } LIKWID_MARKER_STOP("force"); double E = getTimeStamp(); return E-S; } double computeForceLJHalfNeigh(Parameter *param, Atom *atom, Neighbor *neighbor, Stats *stats) { int Nlocal = atom->Nlocal; int* neighs; MD_FLOAT* fx = atom->fx; MD_FLOAT* fy = atom->fy; MD_FLOAT* fz = atom->fz; #ifndef EXPLICIT_TYPES MD_FLOAT cutforcesq = param->cutforce * param->cutforce; MD_FLOAT sigma6 = param->sigma6; MD_FLOAT epsilon = param->epsilon; #endif for(int i = 0; i < Nlocal; i++) { fx[i] = 0.0; fy[i] = 0.0; fz[i] = 0.0; } double S = getTimeStamp(); LIKWID_MARKER_START("forceLJ-halfneigh"); for(int i = 0; i < Nlocal; i++) { neighs = &neighbor->neighbors[i * neighbor->maxneighs]; int numneighs = neighbor->numneigh[i]; MD_FLOAT xtmp = atom_x(i); MD_FLOAT ytmp = atom_y(i); MD_FLOAT ztmp = atom_z(i); MD_FLOAT fix = 0; MD_FLOAT fiy = 0; MD_FLOAT fiz = 0; #ifdef EXPLICIT_TYPES const int type_i = atom->type[i]; #endif for(int k = 0; k < numneighs; k++) { int j = neighs[k]; MD_FLOAT delx = xtmp - atom_x(j); MD_FLOAT dely = ytmp - atom_y(j); MD_FLOAT delz = ztmp - atom_z(j); MD_FLOAT rsq = delx * delx + dely * dely + delz * delz; #ifdef EXPLICIT_TYPES const int type_j = atom->type[j]; const int type_ij = type_i * atom->ntypes + type_j; const MD_FLOAT cutforcesq = atom->cutforcesq[type_ij]; const MD_FLOAT sigma6 = atom->sigma6[type_ij]; const MD_FLOAT epsilon = atom->epsilon[type_ij]; #endif if(rsq < cutforcesq) { MD_FLOAT sr2 = 1.0 / rsq; MD_FLOAT sr6 = sr2 * sr2 * sr2 * sigma6; MD_FLOAT force = 48.0 * sr6 * (sr6 - 0.5) * sr2 * epsilon; fix += delx * force; fiy += dely * force; fiz += delz * force; fx[j] -= delx * force; fy[j] -= dely * force; fz[j] -= delz * force; } } fx[i] += fix; fy[i] += fiy; fz[i] += fiz; addStat(stats->total_force_neighs, numneighs); addStat(stats->total_force_iters, (numneighs + VECTOR_WIDTH - 1) / VECTOR_WIDTH); } LIKWID_MARKER_STOP("forceLJ-halfneigh"); double E = getTimeStamp(); return E-S; }