Exemplo n.º 1
0
/* return the list of exclusions from the file */
void GromacsTopFile::getExclusions(int* atomi, int* atomj) const {
    for(int i =0; i < exclusions_atom_i.size(); i++) {
	atomi[i] = exclusions_atom_i[i];
	atomj[i] = exclusions_atom_j[i];
    }
  return;
}
Exemplo n.º 2
0
void ComputeDPMEMaster::recvData(ComputeDPMEDataMsg *msg)
{ 
  DebugM(4,"ComputeDPMEMaster::recvData() " << msg->numParticles
	<< " particles from node " << msg->node << "\n");

  {
    homeNode.add(msg->node);
    Pme2Particle *data_ptr = localData + numLocalAtoms;
    for ( int j = 0; j < msg->numParticles; ++j, ++data_ptr ) {
      *data_ptr = msg->particles[j];
    }
    numLocalAtoms += msg->numParticles;
    endForNode.add(numLocalAtoms);
    delete msg;
  }

  if ( homeNode.size() < numWorkingPes ) return;  // messages outstanding

  DebugM(4,"ComputeDPMEMaster::recvData() running serial code.\n");

  // single processor version

  Lattice lattice = host->getFlags()->lattice;
  SimParameters * simParams = Node::Object()->simParameters;
  int i;

  AtomInfo atom_info;
  atom_info.numatoms = numLocalAtoms;
  atom_info.atompnt = 0;  // not used
  atom_info.freepnt = 0;  // not used
  atom_info.nlocal = numLocalAtoms;
  atom_info.nother = 0;

  if ( ! lattice.orthogonal() ) {
    NAMD_die("DPME only supports orthogonal PBC's.");
  }

  BoxInfo box_info;
  box_info.box.x = lattice.a().x;
  box_info.box.y = lattice.b().y;
  box_info.box.z = lattice.c().z;
  box_info.box.origin = 0.;  // why only one number?
  box_info.prd.x = box_info.box.x;
  box_info.prd.y = box_info.box.y;
  box_info.prd.z = box_info.box.z;
  box_info.prd2.x = 0.5 * box_info.box.x;
  box_info.prd2.y = 0.5 * box_info.box.y;
  box_info.prd2.z = 0.5 * box_info.box.z;
  box_info.cutoff = simParams->cutoff;
  box_info.rs = simParams->cutoff;
  box_info.mc2.x = 2. * ( box_info.prd.x - box_info.cutoff );
  box_info.mc2.y = 2. * ( box_info.prd.y - box_info.cutoff );
  box_info.mc2.z = 2. * ( box_info.prd.z - box_info.cutoff );
  box_info.ewaldcof = ComputeNonbondedUtil::ewaldcof;
  box_info.dtol = simParams->PMETolerance;
  for (i = 0; i <= 8; i++) {
    box_info.recip[i] = 0.; /* assume orthogonal box */
  }
  box_info.recip[0] = 1.0/box_info.box.x;
  box_info.recip[4] = 1.0/box_info.box.y;
  box_info.recip[8] = 1.0/box_info.box.z;

  GridInfo grid_info;
  grid_info.order = simParams->PMEInterpOrder;
  grid_info.nfftgrd.x = simParams->PMEGridSizeX;
  grid_info.nfftgrd.y = simParams->PMEGridSizeY;
  grid_info.nfftgrd.z = simParams->PMEGridSizeZ;
  grid_info.nfft = 0;
  grid_info.volume = lattice.volume();

  PeInfo pe_info;  // hopefully this isn't used for anything
  pe_info.myproc.node = 0;
  pe_info.myproc.nprocs = 1;
  pe_info.myproc.ncube = 0;
  pe_info.inst_node[0] = 0;
  pe_info.igrid = 0;

  PmeVector *localResults;
  double recip_vir[6];
  int time_count = 0;
  int tsteps = 1;
  double mytime = 0.;

  // perform calculations
  BigReal electEnergy = 0;

  // calculate self energy
  Pme2Particle *data_ptr = localData;
  for(i=0; i<numLocalAtoms; ++i)
  {
    electEnergy += data_ptr->cg * data_ptr->cg;
    ++data_ptr;
  }
  electEnergy *= -1. * box_info.ewaldcof / SQRT_PI;

  DebugM(4,"Ewald self energy: " << electEnergy << "\n");

  DebugM(4,"Calling dpme_eval_recip().\n");

  double pme_start_time = 0;
  if ( runcount == 1 ) pme_start_time = CmiTimer();

  electEnergy += dpme_eval_recip( atom_info, localData - 1, &localResults,
			recip_vir, grid_info, box_info, pe_info,
			time_count, tsteps, &mytime );

  if ( runcount == 1 ) {
    iout << iINFO << "PME reciprocal sum CPU time per evaluation: "
         << (CmiTimer() - pme_start_time) << "\n" << endi;
  }

  DebugM(4,"Returned from dpme_eval_recip().\n");

  // REVERSE SIGN OF VIRIAL RETURNED BY DPME
  for(i=0; i<6; ++i) recip_vir[i] *= -1.;

  // send out reductions
  DebugM(4,"Timestep : " << host->getFlags()->step << "\n");
  DebugM(4,"Reciprocal sum energy: " << electEnergy << "\n");
  DebugM(4,"Reciprocal sum virial: " << recip_vir[0] << " " <<
	recip_vir[1] << " " << recip_vir[2] << " " << recip_vir[3] << " " <<
	recip_vir[4] << " " << recip_vir[5] << "\n");
  reduction->item(REDUCTION_ELECT_ENERGY_SLOW) += electEnergy;
  reduction->item(REDUCTION_VIRIAL_SLOW_XX) += (BigReal)(recip_vir[0]);
  reduction->item(REDUCTION_VIRIAL_SLOW_XY) += (BigReal)(recip_vir[1]);
  reduction->item(REDUCTION_VIRIAL_SLOW_XZ) += (BigReal)(recip_vir[2]);
  reduction->item(REDUCTION_VIRIAL_SLOW_YX) += (BigReal)(recip_vir[1]);
  reduction->item(REDUCTION_VIRIAL_SLOW_YY) += (BigReal)(recip_vir[3]);
  reduction->item(REDUCTION_VIRIAL_SLOW_YZ) += (BigReal)(recip_vir[4]);
  reduction->item(REDUCTION_VIRIAL_SLOW_ZX) += (BigReal)(recip_vir[2]);
  reduction->item(REDUCTION_VIRIAL_SLOW_ZY) += (BigReal)(recip_vir[4]);
  reduction->item(REDUCTION_VIRIAL_SLOW_ZZ) += (BigReal)(recip_vir[5]);
  reduction->submit();

  PmeVector *results_ptr = localResults + 1;

  numLocalAtoms = 0;
  for ( i = 0; i < homeNode.size(); ++i ) {
    ComputeDPMEResultsMsg *msg = new ComputeDPMEResultsMsg;
    msg->node = homeNode[i];
    msg->numParticles = endForNode[i] - numLocalAtoms;
    msg->forces = new PmeVector[msg->numParticles];
    for ( int j = 0; j < msg->numParticles; ++j, ++results_ptr ) {
      msg->forces[j] = *results_ptr;
    }
    numLocalAtoms = endForNode[i];
    host->comm->sendComputeDPMEResults(msg,homeNode[i]);
  }

  // reset
  runcount += 1;
  numLocalAtoms = 0;
  homeNode.resize(0);
  endForNode.resize(0);

}