verlet_intel.cpp
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Created: Tue, Sep 3, 23:41

verlet_intel.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.
	------------------------------------------------------------------------- */

	#include <string.h>
	#include "verlet_intel.h"
	#include "neighbor.h"
	#include "domain.h"
	#include "comm.h"
	#include "atom.h"
	#include "atom_vec.h"
	#include "force.h"
	#include "pair.h"
	#include "bond.h"
	#include "angle.h"
	#include "dihedral.h"
	#include "improper.h"
	#include "kspace.h"
	#include "output.h"
	#include "update.h"
	#include "modify.h"
	#include "compute.h"
	#include "fix.h"
	#include "timer.h"
	#include "memory.h"
	#include "error.h"

	using namespace LAMMPS_NS;

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

	VerletIntel::VerletIntel(LAMMPS lmp, int narg, char *arg) :
	Integrate(lmp, narg, arg) {}

	/* ----------------------------------------------------------------------
	initialization before run
	------------------------------------------------------------------------- */

	void VerletIntel::init()
	{
	Integrate::init();

	// warn if no fixes

	if (modify->nfix == 0 && comm->me == 0)
	error->warning(FLERR,"No fixes defined, atoms won't move");

	// virial_style:
	// 1 if computed explicitly by pair->compute via sum over pair interactions
	// 2 if computed implicitly by pair->virial_fdotr_compute via sum over ghosts

	if (force->newton_pair) virial_style = 2;
	else virial_style = 1;

	// setup lists of computes for global and per-atom PE and pressure

	ev_setup();

	// detect if fix omp is present for clearing force arrays

	int ifix = modify->find_fix("package_omp");
	if (ifix >= 0) external_force_clear = 1;

	if (nvlist_atom)
	error->all(FLERR,
	"Cannot currently get per-atom virials with Intel package.");

	ifix = modify->find_fix("package_intel");
	if (ifix >= 0) fix_intel = static_cast<FixIntel *>(modify->fix[ifix]);
	else fix_intel = 0;

	// set flags for what arrays to clear in force_clear()
	// need to clear additionals arrays if they exist

	torqueflag = extraflag = 0;
	if (atom->torque_flag) torqueflag = 1;
	if (atom->avec->forceclearflag) extraflag = 1;

	// orthogonal vs triclinic simulation box

	triclinic = domain->triclinic;
	}

	/* ----------------------------------------------------------------------
	setup before run
	------------------------------------------------------------------------- */

	void VerletIntel::setup()
	{
	if (comm->me == 0 && screen) {
	fprintf(screen,"Setting up Verlet run ...\n");
	fprintf(screen," Unit style : %s\n", update->unit_style);
	fprintf(screen," Current step: " BIGINT_FORMAT "\n", update->ntimestep);
	fprintf(screen," Time step : %g\n", update->dt);
	timer->print_timeout(screen);
	}

	update->setupflag = 1;

	// setup domain, communication and neighboring
	// acquire ghosts
	// build neighbor lists

	atom->setup();
	modify->setup_pre_exchange();
	if (triclinic) domain->x2lamda(atom->nlocal);
	domain->pbc();
	domain->reset_box();
	comm->setup();
	if (neighbor->style) neighbor->setup_bins();
	comm->exchange();
	if (atom->sortfreq > 0) atom->sort();
	comm->borders();
	if (triclinic) domain->lamda2x(atom->nlocal+atom->nghost);
	domain->image_check();
	domain->box_too_small_check();
	modify->setup_pre_neighbor();
	neighbor->build();
	neighbor->ncalls = 0;

	// compute all forces

	ev_set(update->ntimestep);
	force_clear();
	modify->setup_pre_force(vflag);

	if (pair_compute_flag) force->pair->compute(eflag,vflag);
	else if (force->pair) force->pair->compute_dummy(eflag,vflag);

	if (atom->molecular) {
	if (force->bond) force->bond->compute(eflag,vflag);
	if (force->angle) force->angle->compute(eflag,vflag);
	if (force->dihedral) force->dihedral->compute(eflag,vflag);
	if (force->improper) force->improper->compute(eflag,vflag);
	}

	if (force->kspace) {
	force->kspace->setup();
	if (kspace_compute_flag) force->kspace->compute(eflag,vflag);
	else force->kspace->compute_dummy(eflag,vflag);
	}

	if (fix_intel) fix_intel->sync();

	#ifdef _LMP_INTEL_OFFLOAD
	sync_mode = 0;
	if (fix_intel) {
	if (fix_intel->offload_balance() != 0.0) {
	if (fix_intel->offload_noghost())
	sync_mode = 2;
	else
	sync_mode = 1;
	}
	}

	if (sync_mode == 1) fix_intel->sync_coprocessor();
	#endif

	if (force->newton) comm->reverse_comm();

	#ifdef _LMP_INTEL_OFFLOAD
	if (sync_mode == 2) fix_intel->sync_coprocessor();
	#endif

	modify->setup(vflag);
	output->setup();
	update->setupflag = 0;
	}

	/* ----------------------------------------------------------------------
	setup without output
	flag = 0 = just force calculation
	flag = 1 = reneighbor and force calculation
	------------------------------------------------------------------------- */

	void VerletIntel::setup_minimal(int flag)
	{
	update->setupflag = 1;

	// setup domain, communication and neighboring
	// acquire ghosts
	// build neighbor lists

	if (flag) {
	modify->setup_pre_exchange();
	if (triclinic) domain->x2lamda(atom->nlocal);
	domain->pbc();
	domain->reset_box();
	comm->setup();
	if (neighbor->style) neighbor->setup_bins();
	comm->exchange();
	comm->borders();
	if (triclinic) domain->lamda2x(atom->nlocal+atom->nghost);
	domain->image_check();
	domain->box_too_small_check();
	modify->setup_pre_neighbor();
	neighbor->build();
	neighbor->ncalls = 0;
	}

	// compute all forces

	ev_set(update->ntimestep);
	force_clear();
	modify->setup_pre_force(vflag);

	if (pair_compute_flag) force->pair->compute(eflag,vflag);
	else if (force->pair) force->pair->compute_dummy(eflag,vflag);

	if (atom->molecular) {
	if (force->bond) force->bond->compute(eflag,vflag);
	if (force->angle) force->angle->compute(eflag,vflag);
	if (force->dihedral) force->dihedral->compute(eflag,vflag);
	if (force->improper) force->improper->compute(eflag,vflag);
	}

	if (force->kspace) {
	force->kspace->setup();
	if (kspace_compute_flag) force->kspace->compute(eflag,vflag);
	else force->kspace->compute_dummy(eflag,vflag);
	}

	if (fix_intel) fix_intel->sync();

	#ifdef _LMP_INTEL_OFFLOAD
	sync_mode = 0;
	if (fix_intel) {
	if (fix_intel->offload_balance() != 0.0) {
	if (fix_intel->offload_noghost())
	sync_mode = 2;
	else
	sync_mode = 1;
	}
	}

	if (sync_mode == 1) fix_intel->sync_coprocessor();
	#endif

	if (force->newton) comm->reverse_comm();

	#ifdef _LMP_INTEL_OFFLOAD
	if (sync_mode == 2) fix_intel->sync_coprocessor();
	#endif

	modify->setup(vflag);
	update->setupflag = 0;
	}

	/* ----------------------------------------------------------------------
	run for N steps
	------------------------------------------------------------------------- */

	void VerletIntel::run(int n)
	{
	bigint ntimestep;
	int nflag,sortflag;

	int n_post_integrate = modify->n_post_integrate;
	int n_pre_exchange = modify->n_pre_exchange;
	int n_pre_neighbor = modify->n_pre_neighbor;
	int n_pre_force = modify->n_pre_force;
	int n_post_force = modify->n_post_force;
	int n_end_of_step = modify->n_end_of_step;

	if (atom->sortfreq > 0) sortflag = 1;
	else sortflag = 0;

	for (int i = 0; i < n; i++) {

	if (timer->check_timeout(i)) {
	update->nsteps = i;
	break;
	}

	ntimestep = ++update->ntimestep;
	ev_set(ntimestep);

	// initial time integration

	timer->stamp();
	modify->initial_integrate(vflag);
	if (n_post_integrate) modify->post_integrate();
	timer->stamp(Timer::MODIFY);

	// regular communication vs neighbor list rebuild

	nflag = neighbor->decide();

	if (nflag == 0) {
	timer->stamp();
	comm->forward_comm();
	timer->stamp(Timer::COMM);
	} else {
	if (n_pre_exchange) {
	timer->stamp();
	modify->pre_exchange();
	timer->stamp(Timer::MODIFY);
	}
	if (triclinic) domain->x2lamda(atom->nlocal);
	domain->pbc();
	if (domain->box_change) {
	domain->reset_box();
	comm->setup();
	if (neighbor->style) neighbor->setup_bins();
	}
	timer->stamp();
	comm->exchange();
	if (sortflag && ntimestep >= atom->nextsort) atom->sort();
	comm->borders();
	if (triclinic) domain->lamda2x(atom->nlocal+atom->nghost);
	timer->stamp(Timer::COMM);
	if (n_pre_neighbor) {
	modify->pre_neighbor();
	timer->stamp(Timer::MODIFY);
	}
	neighbor->build();
	timer->stamp(Timer::NEIGH);
	}

	// force computations
	// important for pair to come before bonded contributions
	// since some bonded potentials tally pairwise energy/virial
	// and Pair:ev_tally() needs to be called before any tallying

	force_clear();

	timer->stamp();

	if (n_pre_force) {
	modify->pre_force(vflag);
	timer->stamp(Timer::MODIFY);
	}

	if (pair_compute_flag) {
	force->pair->compute(eflag,vflag);
	timer->stamp(Timer::PAIR);
	}

	if (atom->molecular) {
	if (force->bond) force->bond->compute(eflag,vflag);
	if (force->angle) force->angle->compute(eflag,vflag);
	if (force->dihedral) force->dihedral->compute(eflag,vflag);
	if (force->improper) force->improper->compute(eflag,vflag);
	timer->stamp(Timer::BOND);
	}

	if (kspace_compute_flag) {
	force->kspace->compute(eflag,vflag);
	timer->stamp(Timer::KSPACE);
	}

	if (fix_intel) fix_intel->sync();

	#ifdef _LMP_INTEL_OFFLOAD
	if (sync_mode == 1) {
	fix_intel->sync_coprocessor();
	timer->stamp(Timer::PAIR);
	}
	#endif

	// reverse communication of forces

	if (force->newton) {
	comm->reverse_comm();
	timer->stamp(Timer::COMM);
	}

	#ifdef _LMP_INTEL_OFFLOAD
	if (sync_mode == 2) {
	fix_intel->sync_coprocessor();
	timer->stamp(Timer::PAIR);
	}
	#endif

	// force modifications, final time integration, diagnostics

	if (n_post_force) modify->post_force(vflag);
	modify->final_integrate();
	if (n_end_of_step) modify->end_of_step();
	timer->stamp(Timer::MODIFY);

	// all output

	if (ntimestep == output->next) {
	timer->stamp();
	output->write(ntimestep);
	timer->stamp(Timer::OUTPUT);
	}
	}
	}

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

	void VerletIntel::cleanup()
	{
	modify->post_run();
	domain->box_too_small_check();
	update->update_time();
	}

	/* ----------------------------------------------------------------------
	clear force on own & ghost atoms
	clear other arrays as needed
	------------------------------------------------------------------------- */

	void VerletIntel::force_clear()
	{
	size_t nbytes;

	if (external_force_clear) return;

	// clear force on all particles
	// if either newton flag is set, also include ghosts
	// when using threads always clear all forces.

	int nlocal = atom->nlocal;

	if (neighbor->includegroup == 0) {
	nbytes = sizeof(double) * nlocal;
	if (force->newton) nbytes += sizeof(double) * atom->nghost;

	if (nbytes) {
	memset(&atom->f[0][0],0,3*nbytes);
	if (torqueflag) memset(&atom->torque[0][0],0,3*nbytes);
	if (extraflag) atom->avec->force_clear(0,nbytes);
	}

	// neighbor includegroup flag is set
	// clear force only on initial nfirst particles
	// if either newton flag is set, also include ghosts

	} else {
	nbytes = sizeof(double) * atom->nfirst;

	if (nbytes) {
	memset(&atom->f[0][0],0,3*nbytes);
	if (torqueflag) memset(&atom->torque[0][0],0,3*nbytes);
	if (extraflag) atom->avec->force_clear(0,nbytes);
	}

	if (force->newton) {
	nbytes = sizeof(double) * atom->nghost;

	if (nbytes) {
	memset(&atom->f[nlocal][0],0,3*nbytes);
	if (torqueflag) memset(&atom->torque[nlocal][0],0,3*nbytes);
	if (extraflag) atom->avec->force_clear(nlocal,nbytes);
	}
	}
	}
	}

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