MD-Bench/lammps/force_dem.c

/*
 * =======================================================================================
 *
 *   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 <https://www.gnu.org/licenses/>.
 * =======================================================================================
 */
#include <math.h>
#include <likwid-marker.h>

#include <timing.h>
#include <neighbor.h>
#include <parameter.h>
#include <atom.h>
#include <stats.h>

// TODO: Joint common files for gromacs and lammps variants
#include "../gromacs/includes/simd.h"

double computeForceDEMFullNeigh_plain_c(Parameter *param, Atom *atom, Neighbor *neighbor, Stats *stats) {
    int Nlocal = atom->Nlocal;
    int* neighs;
    MD_FLOAT k_s = param->k_s;
    MD_FLOAT k_dn = param->k_dn;
#ifndef EXPLICIT_TYPES
    MD_FLOAT cutforcesq = param->cutforce * param->cutforce;
#endif

    for(int i = 0; i < Nlocal; i++) {
        atom_fx(i) = 0.0;
        atom_fy(i) = 0.0;
        atom_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 irad = atom->radius[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 jrad = atom->radius[j];
            MD_FLOAT xj = atom_x(j);
            MD_FLOAT yj = atom_y(j);
            MD_FLOAT zj = atom_z(j);
            MD_FLOAT delx = xtmp - xj;
            MD_FLOAT dely = ytmp - yj;
            MD_FLOAT delz = ztmp - zj;
            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];
#endif

            if(rsq < cutforcesq) {
                MD_FLOAT r = sqrt(rsq);
                // penetration depth
                MD_FLOAT p = irad + jrad - r;
                if(p >= 0) {
                    // contact position
                    //MD_FLOAT cterm = jrad / (irad + jrad);
                    //MD_FLOAT cx = xj + cterm * delx;
                    //MD_FLOAT cy = yj + cterm * dely;
                    //MD_FLOAT cz = zj + cterm * delz;

                    // delta contact and particle position
                    //MD_FLOAT delcx = cx - xtmp;
                    //MD_FLOAT delcy = cy - ytmp;
                    //MD_FLOAT delcz = cz - ztmp;

                    // contact velocity
                    //MD_FLOAT cvx = (atom_vx(i) + atom_avx(i) * delcx) - (atom_vx(j) + atom_avx(j) * (cx - xj));
                    //MD_FLOAT cvy = (atom_vy(i) + atom_avy(i) * delcy) - (atom_vy(j) + atom_avy(j) * (cy - yj));
                    //MD_FLOAT cvz = (atom_vz(i) + atom_avz(i) * delcz) - (atom_vz(j) + atom_avz(j) * (cz - zj));
                    MD_FLOAT delvx = atom_vx(i) - atom_vx(j);
                    MD_FLOAT delvy = atom_vy(i) - atom_vy(j);
                    MD_FLOAT delvz = atom_vz(i) - atom_vz(j);
                    MD_FLOAT vr = sqrt(delvx * delvx + delvy * delvy + delvz * delvz);

                    // normal distance
                    MD_FLOAT nx = delx / r;
                    MD_FLOAT ny = dely / r;
                    MD_FLOAT nz = delz / r;

                    // normal contact velocity
                    MD_FLOAT nvx = delvx / vr;
                    MD_FLOAT nvy = delvy / vr;
                    MD_FLOAT nvz = delvz / vr;

                    // forces
                    fix += k_s * p * nx - k_dn * nvx;
                    fiy += k_s * p * ny - k_dn * nvy;
                    fiz += k_s * p * nz - k_dn * nvz;

                    // tangential force
                    //fix += MIN(kdt * vtsq, kf * fnx) * tx;
                    //fiy += MIN(kdt * vtsq, kf * fny) * ty;
                    //fiz += MIN(kdt * vtsq, kf * fnz) * tz;
                    // torque
                    //MD_FLOAT taux = delcx * ftx;
                    //MD_FLOAT tauy = delcy * fty;
                    //MD_FLOAT tauz = delcz * ftz;
                }
#ifdef USE_REFERENCE_VERSION
                addStat(stats->atoms_within_cutoff, 1);
            } else {
                addStat(stats->atoms_outside_cutoff, 1);
#endif
            }
        }

        atom_fx(i) += fix;
        atom_fy(i) += fiy;
        atom_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 computeForceDEMHalfNeigh(Parameter *param, Atom *atom, Neighbor *neighbor, Stats *stats) {
    int Nlocal = atom->Nlocal;
    int* neighs;
#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++) {
        atom_fx(i) = 0.0;
        atom_fy(i) = 0.0;
        atom_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

        // Pragma required to vectorize the inner loop
#ifdef ENABLE_OMP_SIMD
        #pragma omp simd reduction(+: fix,fiy,fiz)
#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;

                // We do not need to update forces for ghost atoms
                if(j < Nlocal) {
                    atom_fx(j) -= delx * force;
                    atom_fy(j) -= dely * force;
                    atom_fz(j) -= delz * force;
                }
            }
        }

        atom_fx(i) += fix;
        atom_fy(i) += fiy;
        atom_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;
}
Add first version of DEM kernel Signed-off-by: Rafael Ravedutti <rafaelravedutti@gmail.com> 2022-07-05 15:33:31 +02:00			`/*`
			`* =======================================================================================`
			`*`
			`* 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 <https://www.gnu.org/licenses/>.`
			`* =======================================================================================`
			`*/`
Adjust code with DEM to be compilable Signed-off-by: Rafael Ravedutti <rafaelravedutti@gmail.com> 2022-07-06 01:07:39 +02:00			`#include <math.h>`
Add first version of DEM kernel Signed-off-by: Rafael Ravedutti <rafaelravedutti@gmail.com> 2022-07-05 15:33:31 +02:00			`#include <likwid-marker.h>`

			`#include <timing.h>`
			`#include <neighbor.h>`
			`#include <parameter.h>`
			`#include <atom.h>`
			`#include <stats.h>`

			`// TODO: Joint common files for gromacs and lammps variants`
			`#include "../gromacs/includes/simd.h"`

			`double computeForceDEMFullNeigh_plain_c(Parameter param, Atom atom, Neighbor neighbor, Stats stats) {`
			`int Nlocal = atom->Nlocal;`
			`int* neighs;`
Adjust code with DEM to be compilable Signed-off-by: Rafael Ravedutti <rafaelravedutti@gmail.com> 2022-07-06 01:07:39 +02:00			`MD_FLOAT k_s = param->k_s;`
			`MD_FLOAT k_dn = param->k_dn;`
Add first version of DEM kernel Signed-off-by: Rafael Ravedutti <rafaelravedutti@gmail.com> 2022-07-05 15:33:31 +02:00			`#ifndef EXPLICIT_TYPES`
			`MD_FLOAT cutforcesq = param->cutforce * param->cutforce;`
			`#endif`

			`for(int i = 0; i < Nlocal; i++) {`
			`atom_fx(i) = 0.0;`
			`atom_fy(i) = 0.0;`
			`atom_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 irad = atom->radius[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 jrad = atom->radius[j];`
			`MD_FLOAT xj = atom_x(j);`
			`MD_FLOAT yj = atom_y(j);`
			`MD_FLOAT zj = atom_z(j);`
			`MD_FLOAT delx = xtmp - xj;`
			`MD_FLOAT dely = ytmp - yj;`
			`MD_FLOAT delz = ztmp - zj;`
			`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];`
			`#endif`

			`if(rsq < cutforcesq) {`
Adjust code with DEM to be compilable Signed-off-by: Rafael Ravedutti <rafaelravedutti@gmail.com> 2022-07-06 01:07:39 +02:00			`MD_FLOAT r = sqrt(rsq);`
Add first version of DEM kernel Signed-off-by: Rafael Ravedutti <rafaelravedutti@gmail.com> 2022-07-05 15:33:31 +02:00			`// penetration depth`
Adjust code with DEM to be compilable Signed-off-by: Rafael Ravedutti <rafaelravedutti@gmail.com> 2022-07-06 01:07:39 +02:00			`MD_FLOAT p = irad + jrad - r;`
			`if(p >= 0) {`
			`// contact position`
			`//MD_FLOAT cterm = jrad / (irad + jrad);`
			`//MD_FLOAT cx = xj + cterm * delx;`
			`//MD_FLOAT cy = yj + cterm * dely;`
			`//MD_FLOAT cz = zj + cterm * delz;`

			`// delta contact and particle position`
			`//MD_FLOAT delcx = cx - xtmp;`
			`//MD_FLOAT delcy = cy - ytmp;`
			`//MD_FLOAT delcz = cz - ztmp;`

			`// contact velocity`
			`//MD_FLOAT cvx = (atom_vx(i) + atom_avx(i) * delcx) - (atom_vx(j) + atom_avx(j) * (cx - xj));`
			`//MD_FLOAT cvy = (atom_vy(i) + atom_avy(i) * delcy) - (atom_vy(j) + atom_avy(j) * (cy - yj));`
			`//MD_FLOAT cvz = (atom_vz(i) + atom_avz(i) * delcz) - (atom_vz(j) + atom_avz(j) * (cz - zj));`
			`MD_FLOAT delvx = atom_vx(i) - atom_vx(j);`
			`MD_FLOAT delvy = atom_vy(i) - atom_vy(j);`
			`MD_FLOAT delvz = atom_vz(i) - atom_vz(j);`
			`MD_FLOAT vr = sqrt(delvx * delvx + delvy * delvy + delvz * delvz);`

			`// normal distance`
			`MD_FLOAT nx = delx / r;`
			`MD_FLOAT ny = dely / r;`
			`MD_FLOAT nz = delz / r;`

			`// normal contact velocity`
			`MD_FLOAT nvx = delvx / vr;`
			`MD_FLOAT nvy = delvy / vr;`
			`MD_FLOAT nvz = delvz / vr;`

			`// forces`
			`fix += k_s * p * nx - k_dn * nvx;`
			`fiy += k_s * p * ny - k_dn * nvy;`
			`fiz += k_s * p * nz - k_dn * nvz;`

			`// tangential force`
			`//fix += MIN(kdt * vtsq, kf * fnx) * tx;`
			`//fiy += MIN(kdt * vtsq, kf * fny) * ty;`
			`//fiz += MIN(kdt * vtsq, kf * fnz) * tz;`
			`// torque`
			`//MD_FLOAT taux = delcx * ftx;`
			`//MD_FLOAT tauy = delcy * fty;`
			`//MD_FLOAT tauz = delcz * ftz;`
			`}`
Add first version of DEM kernel Signed-off-by: Rafael Ravedutti <rafaelravedutti@gmail.com> 2022-07-05 15:33:31 +02:00			`#ifdef USE_REFERENCE_VERSION`
			`addStat(stats->atoms_within_cutoff, 1);`
			`} else {`
			`addStat(stats->atoms_outside_cutoff, 1);`
			`#endif`
			`}`
			`}`

			`atom_fx(i) += fix;`
			`atom_fy(i) += fiy;`
			`atom_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 computeForceDEMHalfNeigh(Parameter param, Atom atom, Neighbor neighbor, Stats stats) {`
			`int Nlocal = atom->Nlocal;`
			`int* neighs;`
			`#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++) {`
			`atom_fx(i) = 0.0;`
			`atom_fy(i) = 0.0;`
			`atom_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`

			`// Pragma required to vectorize the inner loop`
			`#ifdef ENABLE_OMP_SIMD`
			`#pragma omp simd reduction(+: fix,fiy,fiz)`
			`#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;`

			`// We do not need to update forces for ghost atoms`
			`if(j < Nlocal) {`
			`atom_fx(j) -= delx * force;`
			`atom_fy(j) -= dely * force;`
			`atom_fz(j) -= delz * force;`
			`}`
			`}`
			`}`

			`atom_fx(i) += fix;`
			`atom_fy(i) += fiy;`
			`atom_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;`
			`}`