/* ---------------------------------------------------------------------- This is the ██╗ ██╗ ██████╗ ██████╗ ██████╗ ██╗ ██╗████████╗███████╗ ██║ ██║██╔════╝ ██╔════╝ ██╔════╝ ██║ ██║╚══██╔══╝██╔════╝ ██║ ██║██║ ███╗██║ ███╗██║ ███╗███████║ ██║ ███████╗ ██║ ██║██║ ██║██║ ██║██║ ██║██╔══██║ ██║ ╚════██║ ███████╗██║╚██████╔╝╚██████╔╝╚██████╔╝██║ ██║ ██║ ███████║ ╚══════╝╚═╝ ╚═════╝ ╚═════╝ ╚═════╝ ╚═╝ ╚═╝ ╚═╝ ╚══════╝® DEM simulation engine, released by DCS Computing Gmbh, Linz, Austria http://www.dcs-computing.com, office@dcs-computing.com LIGGGHTS® is part of CFDEM®project: http://www.liggghts.com | http://www.cfdem.com Core developer and main author: Christoph Kloss, christoph.kloss@dcs-computing.com LIGGGHTS® is open-source, distributed under the terms of the GNU Public License, version 2 or later. It 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. You should have received a copy of the GNU General Public License along with LIGGGHTS®. If not, see http://www.gnu.org/licenses . See also top-level README and LICENSE files. LIGGGHTS® and CFDEM® are registered trade marks of DCS Computing GmbH, the producer of the LIGGGHTS® software and the CFDEM®coupling software See http://www.cfdem.com/terms-trademark-policy for details. ------------------------------------------------------------------------- Contributing author and copyright for this file: This file is from LAMMPS 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. ------------------------------------------------------------------------- */ #include #include #include #include "atom_vec_tri.h" #include "math_extra.h" #include "atom.h" #include "comm.h" #include "domain.h" #include "modify.h" #include "force.h" #include "fix.h" #include "memory.h" #include "error.h" using namespace LAMMPS_NS; #define DELTA 10000 #define DELTA_BONUS 10000 #define EPSILON 0.001 /* ---------------------------------------------------------------------- */ AtomVecTri::AtomVecTri(LAMMPS *lmp) : AtomVec(lmp) { molecular = 0; comm_x_only = comm_f_only = 0; size_forward = 7; size_reverse = 6; size_border = 24; size_velocity = 6; size_data_atom = 8; size_data_vel = 7; size_data_bonus = 10; xcol_data = 6; atom->tri_flag = 1; atom->molecule_flag = atom->rmass_flag = 1; atom->angmom_flag = atom->torque_flag = 1; nlocal_bonus = nghost_bonus = nmax_bonus = 0; bonus = NULL; } /* ---------------------------------------------------------------------- */ AtomVecTri::~AtomVecTri() { memory->sfree(bonus); } /* ---------------------------------------------------------------------- */ void AtomVecTri::init() { AtomVec::init(); if (domain->dimension != 3) error->all(FLERR,"Atom_style tri can only be used in 3d simulations"); } /* ---------------------------------------------------------------------- grow atom arrays n = 0 grows arrays by DELTA n > 0 allocates arrays to size n ------------------------------------------------------------------------- */ void AtomVecTri::grow(int n) { if (n == 0) nmax += DELTA; else nmax = n; atom->nmax = nmax; if (nmax < 0 || nmax > MAXSMALLINT) error->one(FLERR,"Per-processor system is too big"); tag = memory->grow(atom->tag,nmax,"atom:tag"); type = memory->grow(atom->type,nmax,"atom:type"); mask = memory->grow(atom->mask,nmax,"atom:mask"); image = memory->grow(atom->image,nmax,"atom:image"); x = memory->grow(atom->x,nmax,3,"atom:x"); v = memory->grow(atom->v,nmax,3,"atom:v"); f = memory->grow(atom->f,nmax*comm->nthreads,3,"atom:f"); molecule = memory->grow(atom->molecule,nmax,"atom:molecule"); rmass = memory->grow(atom->rmass,nmax,"atom:rmass"); angmom = memory->grow(atom->angmom,nmax,3,"atom:angmom"); torque = memory->grow(atom->torque,nmax*comm->nthreads,3,"atom:torque"); tri = memory->grow(atom->tri,nmax,"atom:tri"); if (atom->nextra_grow) for (int iextra = 0; iextra < atom->nextra_grow; iextra++) modify->fix[atom->extra_grow[iextra]]->grow_arrays(nmax); } /* ---------------------------------------------------------------------- reset local array ptrs ------------------------------------------------------------------------- */ void AtomVecTri::grow_reset() { tag = atom->tag; type = atom->type; mask = atom->mask; image = atom->image; x = atom->x; v = atom->v; f = atom->f; molecule = atom->molecule; rmass = atom->rmass; angmom = atom->angmom; torque = atom->torque; tri = atom->tri; } /* ---------------------------------------------------------------------- grow bonus data structure ------------------------------------------------------------------------- */ void AtomVecTri::grow_bonus() { nmax_bonus += DELTA_BONUS; if (nmax_bonus < 0 || nmax_bonus > MAXSMALLINT) error->one(FLERR,"Per-processor system is too big"); bonus = (Bonus *) memory->srealloc(bonus,nmax_bonus*sizeof(Bonus), "atom:bonus"); } /* ---------------------------------------------------------------------- copy atom I info to atom J if delflag and atom J has bonus data, then delete it ------------------------------------------------------------------------- */ void AtomVecTri::copy(int i, int j, int delflag) { tag[j] = tag[i]; type[j] = type[i]; mask[j] = mask[i]; image[j] = image[i]; x[j][0] = x[i][0]; x[j][1] = x[i][1]; x[j][2] = x[i][2]; v[j][0] = v[i][0]; v[j][1] = v[i][1]; v[j][2] = v[i][2]; molecule[j] = molecule[i]; rmass[j] = rmass[i]; angmom[j][0] = angmom[i][0]; angmom[j][1] = angmom[i][1]; angmom[j][2] = angmom[i][2]; // if deleting atom J via delflag and J has bonus data, then delete it if (delflag && tri[j] >= 0) { copy_bonus(nlocal_bonus-1,tri[j]); nlocal_bonus--; } // if atom I has bonus data, reset I's bonus.ilocal to loc J // do NOT do this if self-copy (I=J) since I's bonus data is already deleted if (tri[i] >= 0 && i != j) bonus[tri[i]].ilocal = j; tri[j] = tri[i]; if (atom->nextra_grow) for (int iextra = 0; iextra < atom->nextra_grow; iextra++) modify->fix[atom->extra_grow[iextra]]->copy_arrays(i,j,delflag); } /* ---------------------------------------------------------------------- copy bonus data from I to J, effectively deleting the J entry also reset tri that points to I to now point to J ------------------------------------------------------------------------- */ void AtomVecTri::copy_bonus(int i, int j) { tri[bonus[i].ilocal] = j; memcpy(&bonus[j],&bonus[i],sizeof(Bonus)); } /* ---------------------------------------------------------------------- clear ghost info in bonus data called before ghosts are recommunicated in comm and irregular ------------------------------------------------------------------------- */ void AtomVecTri::clear_bonus() { nghost_bonus = 0; } /* ---------------------------------------------------------------------- set equilateral tri of size in bonus data for particle I oriented symmetrically in xy plane this may create or delete entry in bonus data ------------------------------------------------------------------------- */ void AtomVecTri::set_equilateral(int i, double size) { if (tri[i] < 0) { if (size == 0.0) return; if (nlocal_bonus == nmax_bonus) grow_bonus(); double *quat = bonus[nlocal_bonus].quat; double *c1 = bonus[nlocal_bonus].c1; double *c2 = bonus[nlocal_bonus].c2; double *c3 = bonus[nlocal_bonus].c3; double *inertia = bonus[nlocal_bonus].inertia; quat[0] = 1.0; quat[1] = 0.0; quat[2] = 0.0; quat[3] = 0.0; c1[0] = -size/2.0; c1[1] = -sqrt(3.0)/2.0 * size / 3.0; c1[2] = 0.0; c2[0] = size/2.0; c2[1] = -sqrt(3.0)/2.0 * size / 3.0; c2[2] = 0.0; c3[0] = 0.0; c3[1] = sqrt(3.0)/2.0 * size * 2.0/3.0; c3[2] = 0.0; inertia[0] = sqrt(3.0)/96.0 * size*size*size*size; inertia[1] = sqrt(3.0)/96.0 * size*size*size*size; inertia[2] = sqrt(3.0)/48.0 * size*size*size*size; bonus[nlocal_bonus].ilocal = i; tri[i] = nlocal_bonus++; } else if (size == 0.0) { copy_bonus(nlocal_bonus-1,tri[i]); nlocal_bonus--; tri[i] = -1; } else { double *c1 = bonus[tri[i]].c1; double *c2 = bonus[tri[i]].c2; double *c3 = bonus[tri[i]].c3; double *inertia = bonus[tri[i]].inertia; c1[0] = -size/2.0; c1[1] = -sqrt(3.0)/2.0 * size / 3.0; c1[2] = 0.0; c2[0] = size/2.0; c2[1] = -sqrt(3.0)/2.0 * size / 3.0; c2[2] = 0.0; c3[0] = 0.0; c3[1] = sqrt(3.0)/2.0 * size * 2.0/3.0; c3[2] = 0.0; inertia[0] = sqrt(3.0)/96.0 * size*size*size*size; inertia[1] = sqrt(3.0)/96.0 * size*size*size*size; inertia[2] = sqrt(3.0)/48.0 * size*size*size*size; } } /* ---------------------------------------------------------------------- */ int AtomVecTri::pack_comm(int n, int *list, double *buf, int pbc_flag, int *pbc) { int i,j,m; double dx,dy,dz; double *quat; m = 0; if (pbc_flag == 0) { for (i = 0; i < n; i++) { j = list[i]; buf[m++] = x[j][0]; buf[m++] = x[j][1]; buf[m++] = x[j][2]; if (tri[j] >= 0) { quat = bonus[tri[j]].quat; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; } } } else { if (domain->triclinic == 0) { dx = pbc[0]*domain->xprd; dy = pbc[1]*domain->yprd; dz = pbc[2]*domain->zprd; } else { dx = pbc[0]*domain->xprd + pbc[5]*domain->xy + pbc[4]*domain->xz; dy = pbc[1]*domain->yprd + pbc[3]*domain->yz; dz = pbc[2]*domain->zprd; } for (i = 0; i < n; i++) { j = list[i]; buf[m++] = x[j][0] + dx; buf[m++] = x[j][1] + dy; buf[m++] = x[j][2] + dz; if (tri[j] >= 0) { quat = bonus[tri[j]].quat; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; } } } return m; } /* ---------------------------------------------------------------------- */ int AtomVecTri::pack_comm_vel(int n, int *list, double *buf, int pbc_flag, int *pbc) { int i,j,m; double dx,dy,dz,dvx,dvy,dvz; double *quat; m = 0; if (pbc_flag == 0) { for (i = 0; i < n; i++) { j = list[i]; buf[m++] = x[j][0]; buf[m++] = x[j][1]; buf[m++] = x[j][2]; if (tri[j] >= 0) { quat = bonus[tri[j]].quat; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; } buf[m++] = v[j][0]; buf[m++] = v[j][1]; buf[m++] = v[j][2]; buf[m++] = angmom[j][0]; buf[m++] = angmom[j][1]; buf[m++] = angmom[j][2]; } } else { if (domain->triclinic == 0) { dx = pbc[0]*domain->xprd; dy = pbc[1]*domain->yprd; dz = pbc[2]*domain->zprd; } else { dx = pbc[0]*domain->xprd + pbc[5]*domain->xy + pbc[4]*domain->xz; dy = pbc[1]*domain->yprd + pbc[3]*domain->yz; dz = pbc[2]*domain->zprd; } if (!deform_vremap) { for (i = 0; i < n; i++) { j = list[i]; buf[m++] = x[j][0] + dx; buf[m++] = x[j][1] + dy; buf[m++] = x[j][2] + dz; if (tri[j] >= 0) { quat = bonus[tri[j]].quat; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; } buf[m++] = v[j][0]; buf[m++] = v[j][1]; buf[m++] = v[j][2]; buf[m++] = angmom[j][0]; buf[m++] = angmom[j][1]; buf[m++] = angmom[j][2]; } } else { dvx = pbc[0]*h_rate[0] + pbc[5]*h_rate[5] + pbc[4]*h_rate[4]; dvy = pbc[1]*h_rate[1] + pbc[3]*h_rate[3]; dvz = pbc[2]*h_rate[2]; for (i = 0; i < n; i++) { j = list[i]; buf[m++] = x[j][0] + dx; buf[m++] = x[j][1] + dy; buf[m++] = x[j][2] + dz; if (tri[j] >= 0) { quat = bonus[tri[j]].quat; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; } if (mask[i] & deform_groupbit) { buf[m++] = v[j][0] + dvx; buf[m++] = v[j][1] + dvy; buf[m++] = v[j][2] + dvz; } else { buf[m++] = v[j][0]; buf[m++] = v[j][1]; buf[m++] = v[j][2]; } buf[m++] = angmom[j][0]; buf[m++] = angmom[j][1]; buf[m++] = angmom[j][2]; } } } return m; } /* ---------------------------------------------------------------------- */ int AtomVecTri::pack_comm_hybrid(int n, int *list, double *buf) { int i,j,m; double *quat; m = 0; for (i = 0; i < n; i++) { j = list[i]; if (tri[j] >= 0) { quat = bonus[tri[j]].quat; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; } } return m; } /* ---------------------------------------------------------------------- */ void AtomVecTri::unpack_comm(int n, int first, double *buf) { int i,m,last; double *quat; m = 0; last = first + n; for (i = first; i < last; i++) { x[i][0] = buf[m++]; x[i][1] = buf[m++]; x[i][2] = buf[m++]; if (tri[i] >= 0) { quat = bonus[tri[i]].quat; quat[0] = buf[m++]; quat[1] = buf[m++]; quat[2] = buf[m++]; quat[3] = buf[m++]; } } } /* ---------------------------------------------------------------------- */ void AtomVecTri::unpack_comm_vel(int n, int first, double *buf) { int i,m,last; double *quat; m = 0; last = first + n; for (i = first; i < last; i++) { x[i][0] = buf[m++]; x[i][1] = buf[m++]; x[i][2] = buf[m++]; if (tri[i] >= 0) { quat = bonus[tri[i]].quat; quat[0] = buf[m++]; quat[1] = buf[m++]; quat[2] = buf[m++]; quat[3] = buf[m++]; } v[i][0] = buf[m++]; v[i][1] = buf[m++]; v[i][2] = buf[m++]; angmom[i][0] = buf[m++]; angmom[i][1] = buf[m++]; angmom[i][2] = buf[m++]; } } /* ---------------------------------------------------------------------- */ int AtomVecTri::unpack_comm_hybrid(int n, int first, double *buf) { int i,m,last; double *quat; m = 0; last = first + n; for (i = first; i < last; i++) if (tri[i] >= 0) { quat = bonus[tri[i]].quat; quat[0] = buf[m++]; quat[1] = buf[m++]; quat[2] = buf[m++]; quat[3] = buf[m++]; } return m; } /* ---------------------------------------------------------------------- */ int AtomVecTri::pack_reverse(int n, int first, double *buf) { int i,m,last; m = 0; last = first + n; for (i = first; i < last; i++) { buf[m++] = f[i][0]; buf[m++] = f[i][1]; buf[m++] = f[i][2]; buf[m++] = torque[i][0]; buf[m++] = torque[i][1]; buf[m++] = torque[i][2]; } return m; } /* ---------------------------------------------------------------------- */ int AtomVecTri::pack_reverse_hybrid(int n, int first, double *buf) { int i,m,last; m = 0; last = first + n; for (i = first; i < last; i++) { buf[m++] = torque[i][0]; buf[m++] = torque[i][1]; buf[m++] = torque[i][2]; } return m; } /* ---------------------------------------------------------------------- */ void AtomVecTri::unpack_reverse(int n, int *list, double *buf) { int i,j,m; m = 0; for (i = 0; i < n; i++) { j = list[i]; f[j][0] += buf[m++]; f[j][1] += buf[m++]; f[j][2] += buf[m++]; torque[j][0] += buf[m++]; torque[j][1] += buf[m++]; torque[j][2] += buf[m++]; } } /* ---------------------------------------------------------------------- */ int AtomVecTri::unpack_reverse_hybrid(int n, int *list, double *buf) { int i,j,m; m = 0; for (i = 0; i < n; i++) { j = list[i]; torque[j][0] += buf[m++]; torque[j][1] += buf[m++]; torque[j][2] += buf[m++]; } return m; } /* ---------------------------------------------------------------------- */ int AtomVecTri::pack_border(int n, int *list, double *buf, int pbc_flag, int *pbc) { int i,j,m; double dx,dy,dz; double *quat,*c1,*c2,*c3,*inertia; m = 0; if (pbc_flag == 0) { for (i = 0; i < n; i++) { j = list[i]; buf[m++] = x[j][0]; buf[m++] = x[j][1]; buf[m++] = x[j][2]; buf[m++] = ubuf(tag[j]).d; buf[m++] = ubuf(type[j]).d; buf[m++] = ubuf(mask[j]).d; buf[m++] = ubuf(molecule[j]).d; if (tri[j] < 0) buf[m++] = ubuf(0).d; else { buf[m++] = ubuf(1).d; quat = bonus[tri[j]].quat; c1 = bonus[tri[j]].c1; c2 = bonus[tri[j]].c2; c3 = bonus[tri[j]].c3; inertia = bonus[tri[j]].inertia; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; buf[m++] = c1[0]; buf[m++] = c1[1]; buf[m++] = c1[2]; buf[m++] = c2[0]; buf[m++] = c2[1]; buf[m++] = c2[2]; buf[m++] = c3[0]; buf[m++] = c3[1]; buf[m++] = c3[2]; buf[m++] = inertia[0]; buf[m++] = inertia[1]; buf[m++] = inertia[2]; } } } else { if (domain->triclinic == 0) { dx = pbc[0]*domain->xprd; dy = pbc[1]*domain->yprd; dz = pbc[2]*domain->zprd; } else { dx = pbc[0]; dy = pbc[1]; dz = pbc[2]; } for (i = 0; i < n; i++) { j = list[i]; buf[m++] = x[j][0] + dx; buf[m++] = x[j][1] + dy; buf[m++] = x[j][2] + dz; buf[m++] = ubuf(tag[j]).d; buf[m++] = ubuf(type[j]).d; buf[m++] = ubuf(mask[j]).d; buf[m++] = ubuf(molecule[j]).d; if (tri[j] < 0) buf[m++] = ubuf(0).d; else { buf[m++] = ubuf(1).d; quat = bonus[tri[j]].quat; c1 = bonus[tri[j]].c1; c2 = bonus[tri[j]].c2; c3 = bonus[tri[j]].c3; inertia = bonus[tri[j]].inertia; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; buf[m++] = c1[0]; buf[m++] = c1[1]; buf[m++] = c1[2]; buf[m++] = c2[0]; buf[m++] = c2[1]; buf[m++] = c2[2]; buf[m++] = c3[0]; buf[m++] = c3[1]; buf[m++] = c3[2]; buf[m++] = inertia[0]; buf[m++] = inertia[1]; buf[m++] = inertia[2]; } } } if (atom->nextra_border) for (int iextra = 0; iextra < atom->nextra_border; iextra++) m += modify->fix[atom->extra_border[iextra]]->pack_border(n,list,&buf[m]); return m; } /* ---------------------------------------------------------------------- */ int AtomVecTri::pack_border_vel(int n, int *list, double *buf, int pbc_flag, int *pbc) { int i,j,m; double dx,dy,dz,dvx,dvy,dvz; double *quat,*c1,*c2,*c3,*inertia; m = 0; if (pbc_flag == 0) { for (i = 0; i < n; i++) { j = list[i]; buf[m++] = x[j][0]; buf[m++] = x[j][1]; buf[m++] = x[j][2]; buf[m++] = ubuf(tag[j]).d; buf[m++] = ubuf(type[j]).d; buf[m++] = ubuf(mask[j]).d; buf[m++] = ubuf(molecule[j]).d; if (tri[j] < 0) buf[m++] = ubuf(0).d; else { buf[m++] = ubuf(1).d; quat = bonus[tri[j]].quat; c1 = bonus[tri[j]].c1; c2 = bonus[tri[j]].c2; c3 = bonus[tri[j]].c3; inertia = bonus[tri[j]].inertia; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; buf[m++] = c1[0]; buf[m++] = c1[1]; buf[m++] = c1[2]; buf[m++] = c2[0]; buf[m++] = c2[1]; buf[m++] = c2[2]; buf[m++] = c3[0]; buf[m++] = c3[1]; buf[m++] = c3[2]; buf[m++] = inertia[0]; buf[m++] = inertia[1]; buf[m++] = inertia[2]; } buf[m++] = v[j][0]; buf[m++] = v[j][1]; buf[m++] = v[j][2]; buf[m++] = angmom[j][0]; buf[m++] = angmom[j][1]; buf[m++] = angmom[j][2]; } } else { if (domain->triclinic == 0) { dx = pbc[0]*domain->xprd; dy = pbc[1]*domain->yprd; dz = pbc[2]*domain->zprd; } else { dx = pbc[0]; dy = pbc[1]; dz = pbc[2]; } if (!deform_vremap) { for (i = 0; i < n; i++) { j = list[i]; buf[m++] = x[j][0] + dx; buf[m++] = x[j][1] + dy; buf[m++] = x[j][2] + dz; buf[m++] = ubuf(tag[j]).d; buf[m++] = ubuf(type[j]).d; buf[m++] = ubuf(mask[j]).d; buf[m++] = ubuf(molecule[j]).d; if (tri[j] < 0) buf[m++] = ubuf(0).d; else { buf[m++] = ubuf(1).d; quat = bonus[tri[j]].quat; c1 = bonus[tri[j]].c1; c2 = bonus[tri[j]].c2; c3 = bonus[tri[j]].c3; inertia = bonus[tri[j]].inertia; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; buf[m++] = c1[0]; buf[m++] = c1[1]; buf[m++] = c1[2]; buf[m++] = c2[0]; buf[m++] = c2[1]; buf[m++] = c2[2]; buf[m++] = c3[0]; buf[m++] = c3[1]; buf[m++] = c3[2]; buf[m++] = inertia[0]; buf[m++] = inertia[1]; buf[m++] = inertia[2]; } buf[m++] = v[j][0]; buf[m++] = v[j][1]; buf[m++] = v[j][2]; buf[m++] = angmom[j][0]; buf[m++] = angmom[j][1]; buf[m++] = angmom[j][2]; } } else { dvx = pbc[0]*h_rate[0] + pbc[5]*h_rate[5] + pbc[4]*h_rate[4]; dvy = pbc[1]*h_rate[1] + pbc[3]*h_rate[3]; dvz = pbc[2]*h_rate[2]; for (i = 0; i < n; i++) { j = list[i]; buf[m++] = x[j][0] + dx; buf[m++] = x[j][1] + dy; buf[m++] = x[j][2] + dz; buf[m++] = ubuf(tag[j]).d; buf[m++] = ubuf(type[j]).d; buf[m++] = ubuf(mask[j]).d; buf[m++] = ubuf(molecule[j]).d; if (tri[j] < 0) buf[m++] = ubuf(0).d; else { buf[m++] = ubuf(1).d; quat = bonus[tri[j]].quat; c1 = bonus[tri[j]].c1; c2 = bonus[tri[j]].c2; c3 = bonus[tri[j]].c3; inertia = bonus[tri[j]].inertia; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; buf[m++] = c1[0]; buf[m++] = c1[1]; buf[m++] = c1[2]; buf[m++] = c2[0]; buf[m++] = c2[1]; buf[m++] = c2[2]; buf[m++] = c3[0]; buf[m++] = c3[1]; buf[m++] = c3[2]; buf[m++] = inertia[0]; buf[m++] = inertia[1]; buf[m++] = inertia[2]; } if (mask[i] & deform_groupbit) { buf[m++] = v[j][0] + dvx; buf[m++] = v[j][1] + dvy; buf[m++] = v[j][2] + dvz; } else { buf[m++] = v[j][0]; buf[m++] = v[j][1]; buf[m++] = v[j][2]; } buf[m++] = angmom[j][0]; buf[m++] = angmom[j][1]; buf[m++] = angmom[j][2]; } } } if (atom->nextra_border) for (int iextra = 0; iextra < atom->nextra_border; iextra++) m += modify->fix[atom->extra_border[iextra]]->pack_border(n,list,&buf[m]); return m; } /* ---------------------------------------------------------------------- */ int AtomVecTri::pack_border_hybrid(int n, int *list, double *buf) { int i,j,m; double *quat,*c1,*c2,*c3,*inertia; m = 0; for (i = 0; i < n; i++) { j = list[i]; buf[m++] = ubuf(molecule[j]).d; if (tri[j] < 0) buf[m++] = ubuf(0).d; else { buf[m++] = ubuf(1).d; quat = bonus[tri[j]].quat; c1 = bonus[tri[j]].c1; c2 = bonus[tri[j]].c2; c3 = bonus[tri[j]].c3; inertia = bonus[tri[j]].inertia; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; buf[m++] = c1[0]; buf[m++] = c1[1]; buf[m++] = c1[2]; buf[m++] = c2[0]; buf[m++] = c2[1]; buf[m++] = c2[2]; buf[m++] = c3[0]; buf[m++] = c3[1]; buf[m++] = c3[2]; buf[m++] = inertia[0]; buf[m++] = inertia[1]; buf[m++] = inertia[2]; } } return m; } /* ---------------------------------------------------------------------- */ void AtomVecTri::unpack_border(int n, int first, double *buf) { int i,j,m,last; double *quat,*c1,*c2,*c3,*inertia; m = 0; last = first + n; for (i = first; i < last; i++) { if (i == nmax) grow(0); x[i][0] = buf[m++]; x[i][1] = buf[m++]; x[i][2] = buf[m++]; tag[i] = (int) ubuf(buf[m++]).i; type[i] = (int) ubuf(buf[m++]).i; mask[i] = (int) ubuf(buf[m++]).i; molecule[i] = (int) ubuf(buf[m++]).i; tri[i] = (int) ubuf(buf[m++]).i; if (tri[i] == 0) tri[i] = -1; else { j = nlocal_bonus + nghost_bonus; if (j == nmax_bonus) grow_bonus(); quat = bonus[j].quat; c1 = bonus[j].c1; c2 = bonus[j].c2; c3 = bonus[j].c3; inertia = bonus[j].inertia; quat[0] = buf[m++]; quat[1] = buf[m++]; quat[2] = buf[m++]; quat[3] = buf[m++]; c1[0] = buf[m++]; c1[1] = buf[m++]; c1[2] = buf[m++]; c2[0] = buf[m++]; c2[1] = buf[m++]; c2[2] = buf[m++]; c3[0] = buf[m++]; c3[1] = buf[m++]; c3[2] = buf[m++]; inertia[0] = buf[m++]; inertia[1] = buf[m++]; inertia[2] = buf[m++]; bonus[j].ilocal = i; tri[i] = j; nghost_bonus++; } } if (atom->nextra_border) for (int iextra = 0; iextra < atom->nextra_border; iextra++) m += modify->fix[atom->extra_border[iextra]]-> unpack_border(n,first,&buf[m]); } /* ---------------------------------------------------------------------- */ void AtomVecTri::unpack_border_vel(int n, int first, double *buf) { int i,j,m,last; double *quat,*c1,*c2,*c3,*inertia; m = 0; last = first + n; for (i = first; i < last; i++) { if (i == nmax) grow(0); x[i][0] = buf[m++]; x[i][1] = buf[m++]; x[i][2] = buf[m++]; tag[i] = (int) ubuf(buf[m++]).i; type[i] = (int) ubuf(buf[m++]).i; mask[i] = (int) ubuf(buf[m++]).i; molecule[i] = (int) ubuf(buf[m++]).i; tri[i] = (int) ubuf(buf[m++]).i; if (tri[i] == 0) tri[i] = -1; else { j = nlocal_bonus + nghost_bonus; if (j == nmax_bonus) grow_bonus(); quat = bonus[j].quat; c1 = bonus[j].c1; c2 = bonus[j].c2; c3 = bonus[j].c3; inertia = bonus[j].inertia; quat[0] = buf[m++]; quat[1] = buf[m++]; quat[2] = buf[m++]; quat[3] = buf[m++]; c1[0] = buf[m++]; c1[1] = buf[m++]; c1[2] = buf[m++]; c2[0] = buf[m++]; c2[1] = buf[m++]; c2[2] = buf[m++]; c3[0] = buf[m++]; c3[1] = buf[m++]; c3[2] = buf[m++]; inertia[0] = buf[m++]; inertia[1] = buf[m++]; inertia[2] = buf[m++]; bonus[j].ilocal = i; tri[i] = j; nghost_bonus++; } v[i][0] = buf[m++]; v[i][1] = buf[m++]; v[i][2] = buf[m++]; angmom[i][0] = buf[m++]; angmom[i][1] = buf[m++]; angmom[i][2] = buf[m++]; } if (atom->nextra_border) for (int iextra = 0; iextra < atom->nextra_border; iextra++) m += modify->fix[atom->extra_border[iextra]]-> unpack_border(n,first,&buf[m]); } /* ---------------------------------------------------------------------- */ int AtomVecTri::unpack_border_hybrid(int n, int first, double *buf) { int i,j,m,last; double *quat,*c1,*c2,*c3,*inertia; m = 0; last = first + n; for (i = first; i < last; i++) { molecule[i] = (int) ubuf(buf[m++]).i; tri[i] = (int) ubuf(buf[m++]).i; if (tri[i] == 0) tri[i] = -1; else { j = nlocal_bonus + nghost_bonus; if (j == nmax_bonus) grow_bonus(); quat = bonus[j].quat; c1 = bonus[j].c1; c2 = bonus[j].c2; c3 = bonus[j].c3; inertia = bonus[j].inertia; quat[0] = buf[m++]; quat[1] = buf[m++]; quat[2] = buf[m++]; quat[3] = buf[m++]; c1[0] = buf[m++]; c1[1] = buf[m++]; c1[2] = buf[m++]; c2[0] = buf[m++]; c2[1] = buf[m++]; c2[2] = buf[m++]; c3[0] = buf[m++]; c3[1] = buf[m++]; c3[2] = buf[m++]; inertia[0] = buf[m++]; inertia[1] = buf[m++]; inertia[2] = buf[m++]; bonus[j].ilocal = i; tri[i] = j; nghost_bonus++; } } return m; } /* ---------------------------------------------------------------------- pack data for atom I for sending to another proc xyz must be 1st 3 values, so comm::exchange() can test on them ------------------------------------------------------------------------- */ int AtomVecTri::pack_exchange(int i, double *buf) { int m = 1; buf[m++] = x[i][0]; buf[m++] = x[i][1]; buf[m++] = x[i][2]; buf[m++] = v[i][0]; buf[m++] = v[i][1]; buf[m++] = v[i][2]; buf[m++] = ubuf(tag[i]).d; buf[m++] = ubuf(type[i]).d; buf[m++] = ubuf(mask[i]).d; buf[m++] = ubuf(image[i]).d; buf[m++] = ubuf(molecule[i]).d; buf[m++] = rmass[i]; buf[m++] = angmom[i][0]; buf[m++] = angmom[i][1]; buf[m++] = angmom[i][2]; if (tri[i] < 0) buf[m++] = ubuf(0).d; else { buf[m++] = ubuf(1).d; int j = tri[i]; double *quat = bonus[j].quat; double *c1 = bonus[j].c1; double *c2 = bonus[j].c2; double *c3 = bonus[j].c3; double *inertia = bonus[j].inertia; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; buf[m++] = c1[0]; buf[m++] = c1[1]; buf[m++] = c1[2]; buf[m++] = c2[0]; buf[m++] = c2[1]; buf[m++] = c2[2]; buf[m++] = c3[0]; buf[m++] = c3[1]; buf[m++] = c3[2]; buf[m++] = inertia[0]; buf[m++] = inertia[1]; buf[m++] = inertia[2]; } if (atom->nextra_grow) for (int iextra = 0; iextra < atom->nextra_grow; iextra++) m += modify->fix[atom->extra_grow[iextra]]->pack_exchange(i,&buf[m]); buf[0] = m; return m; } /* ---------------------------------------------------------------------- */ int AtomVecTri::unpack_exchange(double *buf) { int nlocal = atom->nlocal; if (nlocal == nmax) grow(0); int m = 1; x[nlocal][0] = buf[m++]; x[nlocal][1] = buf[m++]; x[nlocal][2] = buf[m++]; v[nlocal][0] = buf[m++]; v[nlocal][1] = buf[m++]; v[nlocal][2] = buf[m++]; tag[nlocal] = (int) ubuf(buf[m++]).i; type[nlocal] = (int) ubuf(buf[m++]).i; mask[nlocal] = (int) ubuf(buf[m++]).i; image[nlocal] = (tagint) ubuf(buf[m++]).i; molecule[nlocal] = (int) ubuf(buf[m++]).i; rmass[nlocal] = buf[m++]; angmom[nlocal][0] = buf[m++]; angmom[nlocal][1] = buf[m++]; angmom[nlocal][2] = buf[m++]; tri[nlocal] = (int) ubuf(buf[m++]).i; if (tri[nlocal] == 0) tri[nlocal] = -1; else { if (nlocal_bonus == nmax_bonus) grow_bonus(); double *quat = bonus[nlocal_bonus].quat; double *c1 = bonus[nlocal_bonus].c1; double *c2 = bonus[nlocal_bonus].c2; double *c3 = bonus[nlocal_bonus].c3; double *inertia = bonus[nlocal_bonus].inertia; quat[0] = buf[m++]; quat[1] = buf[m++]; quat[2] = buf[m++]; quat[3] = buf[m++]; c1[0] = buf[m++]; c1[1] = buf[m++]; c1[2] = buf[m++]; c2[0] = buf[m++]; c2[1] = buf[m++]; c2[2] = buf[m++]; c3[0] = buf[m++]; c3[1] = buf[m++]; c3[2] = buf[m++]; inertia[0] = buf[m++]; inertia[1] = buf[m++]; inertia[2] = buf[m++]; bonus[nlocal_bonus].ilocal = nlocal; tri[nlocal] = nlocal_bonus++; } if (atom->nextra_grow) for (int iextra = 0; iextra < atom->nextra_grow; iextra++) m += modify->fix[atom->extra_grow[iextra]]-> unpack_exchange(nlocal,&buf[m]); atom->nlocal++; return m; } /* ---------------------------------------------------------------------- size of restart data for all atoms owned by this proc include extra data stored by fixes ------------------------------------------------------------------------- */ int AtomVecTri::size_restart() { int i; int n = 0; int nlocal = atom->nlocal; for (i = 0; i < nlocal; i++) if (tri[i] >= 0) n += 33; else n += 17; if (atom->nextra_restart) for (int iextra = 0; iextra < atom->nextra_restart; iextra++) for (i = 0; i < nlocal; i++) n += modify->fix[atom->extra_restart[iextra]]->size_restart(i); return n; } /* ---------------------------------------------------------------------- pack atom I's data for restart file including extra quantities xyz must be 1st 3 values, so that read_restart can test on them molecular types may be negative, but write as positive ------------------------------------------------------------------------- */ int AtomVecTri::pack_restart(int i, double *buf) { int m = 1; buf[m++] = x[i][0]; buf[m++] = x[i][1]; buf[m++] = x[i][2]; buf[m++] = ubuf(tag[i]).d; buf[m++] = ubuf(type[i]).d; buf[m++] = ubuf(mask[i]).d; buf[m++] = ubuf(image[i]).d; buf[m++] = v[i][0]; buf[m++] = v[i][1]; buf[m++] = v[i][2]; buf[m++] = ubuf(molecule[i]).d; buf[m++] = rmass[i]; buf[m++] = angmom[i][0]; buf[m++] = angmom[i][1]; buf[m++] = angmom[i][2]; if (tri[i] < 0) buf[m++] = ubuf(0).d; else { buf[m++] = ubuf(1).d; int j = tri[i]; double *quat = bonus[j].quat; double *c1 = bonus[j].c1; double *c2 = bonus[j].c2; double *c3 = bonus[j].c3; double *inertia = bonus[j].inertia; buf[m++] = quat[0]; buf[m++] = quat[1]; buf[m++] = quat[2]; buf[m++] = quat[3]; buf[m++] = c1[0]; buf[m++] = c1[1]; buf[m++] = c1[2]; buf[m++] = c2[0]; buf[m++] = c2[1]; buf[m++] = c2[2]; buf[m++] = c3[0]; buf[m++] = c3[1]; buf[m++] = c3[2]; buf[m++] = inertia[0]; buf[m++] = inertia[1]; buf[m++] = inertia[2]; } if (atom->nextra_restart) for (int iextra = 0; iextra < atom->nextra_restart; iextra++) m += modify->fix[atom->extra_restart[iextra]]->pack_restart(i,&buf[m]); buf[0] = m; return m; } /* ---------------------------------------------------------------------- unpack data for one atom from restart file including extra quantities ------------------------------------------------------------------------- */ int AtomVecTri::unpack_restart(double *buf) { int nlocal = atom->nlocal; if (nlocal == nmax) { grow(0); if (atom->nextra_store) memory->grow(atom->extra,nmax,atom->nextra_store,"atom:extra"); } int m = 1; x[nlocal][0] = buf[m++]; x[nlocal][1] = buf[m++]; x[nlocal][2] = buf[m++]; tag[nlocal] = (int) ubuf(buf[m++]).i; type[nlocal] = (int) ubuf(buf[m++]).i; mask[nlocal] = (int) ubuf(buf[m++]).i; image[nlocal] = (tagint) ubuf(buf[m++]).i; v[nlocal][0] = buf[m++]; v[nlocal][1] = buf[m++]; v[nlocal][2] = buf[m++]; molecule[nlocal] = (int) ubuf(buf[m++]).i; rmass[nlocal] = buf[m++]; angmom[nlocal][0] = buf[m++]; angmom[nlocal][1] = buf[m++]; angmom[nlocal][2] = buf[m++]; tri[nlocal] = (int) ubuf(buf[m++]).i; if (tri[nlocal] == 0) tri[nlocal] = -1; else { if (nlocal_bonus == nmax_bonus) grow_bonus(); double *quat = bonus[nlocal_bonus].quat; double *c1 = bonus[nlocal_bonus].c1; double *c2 = bonus[nlocal_bonus].c2; double *c3 = bonus[nlocal_bonus].c3; double *inertia = bonus[nlocal_bonus].inertia; quat[0] = buf[m++]; quat[1] = buf[m++]; quat[2] = buf[m++]; quat[3] = buf[m++]; c1[0] = buf[m++]; c1[1] = buf[m++]; c1[2] = buf[m++]; c2[0] = buf[m++]; c2[1] = buf[m++]; c2[2] = buf[m++]; c3[0] = buf[m++]; c3[1] = buf[m++]; c3[2] = buf[m++]; inertia[0] = buf[m++]; inertia[1] = buf[m++]; inertia[2] = buf[m++]; bonus[nlocal_bonus].ilocal = nlocal; tri[nlocal] = nlocal_bonus++; } double **extra = atom->extra; if (atom->nextra_store) { int size = static_cast (buf[0]) - m; for (int i = 0; i < size; i++) extra[nlocal][i] = buf[m++]; } atom->nlocal++; return m; } /* ---------------------------------------------------------------------- create one atom of itype at coord set other values to defaults ------------------------------------------------------------------------- */ void AtomVecTri::create_atom(int itype, double *coord) { int nlocal = atom->nlocal; if (nlocal == nmax) grow(0); tag[nlocal] = 0; type[nlocal] = itype; x[nlocal][0] = coord[0]; x[nlocal][1] = coord[1]; x[nlocal][2] = coord[2]; mask[nlocal] = 1; image[nlocal] = ((tagint) IMGMAX << IMG2BITS) | ((tagint) IMGMAX << IMGBITS) | IMGMAX; v[nlocal][0] = 0.0; v[nlocal][1] = 0.0; v[nlocal][2] = 0.0; molecule[nlocal] = 0; rmass[nlocal] = 1.0; angmom[nlocal][0] = 0.0; angmom[nlocal][1] = 0.0; angmom[nlocal][2] = 0.0; tri[nlocal] = -1; atom->nlocal++; } /* ---------------------------------------------------------------------- unpack one line from Atoms section of data file initialize other atom quantities ------------------------------------------------------------------------- */ void AtomVecTri::data_atom(double *coord, tagint imagetmp, char **values) { int nlocal = atom->nlocal; if (nlocal == nmax) grow(0); tag[nlocal] = atoi(values[0]); if (tag[nlocal] <= 0) error->one(FLERR,"Invalid atom ID in Atoms section of data file"); molecule[nlocal] = atoi(values[1]); type[nlocal] = atoi(values[2]); if (type[nlocal] <= 0 || type[nlocal] > atom->ntypes) error->one(FLERR,"Invalid atom type in Atoms section of data file"); tri[nlocal] = atoi(values[3]); if (tri[nlocal] == 0) tri[nlocal] = -1; else if (tri[nlocal] == 1) tri[nlocal] = 0; else error->one(FLERR,"Invalid atom type in Atoms section of data file"); rmass[nlocal] = atof(values[4]); if (rmass[nlocal] <= 0.0) error->one(FLERR,"Invalid density in Atoms section of data file"); x[nlocal][0] = coord[0]; x[nlocal][1] = coord[1]; x[nlocal][2] = coord[2]; image[nlocal] = imagetmp; mask[nlocal] = 1; v[nlocal][0] = 0.0; v[nlocal][1] = 0.0; v[nlocal][2] = 0.0; angmom[nlocal][0] = 0.0; angmom[nlocal][1] = 0.0; angmom[nlocal][2] = 0.0; atom->nlocal++; } /* ---------------------------------------------------------------------- unpack hybrid quantities from one tri in Atoms section of data file initialize other atom quantities for this sub-style ------------------------------------------------------------------------- */ int AtomVecTri::data_atom_hybrid(int nlocal, char **values) { molecule[nlocal] = atoi(values[0]); tri[nlocal] = atoi(values[1]); if (tri[nlocal] == 0) tri[nlocal] = -1; else if (tri[nlocal] == 1) tri[nlocal] = 0; else error->one(FLERR,"Invalid atom type in Atoms section of data file"); rmass[nlocal] = atof(values[2]); if (rmass[nlocal] <= 0.0) error->one(FLERR,"Invalid density in Atoms section of data file"); return 3; } /* ---------------------------------------------------------------------- unpack one line from Tris section of data file ------------------------------------------------------------------------- */ void AtomVecTri::data_atom_bonus(int m, char **values) { if (tri[m]) error->one(FLERR,"Assigning tri parameters to non-tri atom"); if (nlocal_bonus == nmax_bonus) grow_bonus(); double c1[3],c2[3],c3[3]; c1[0] = atof(values[0]); c1[1] = atof(values[1]); c1[2] = atof(values[2]); c2[0] = atof(values[3]); c2[1] = atof(values[4]); c2[2] = atof(values[5]); c3[0] = atof(values[6]); c3[1] = atof(values[7]); c3[2] = atof(values[8]); // check for duplicate points if (c1[0] == c2[0] && c1[1] == c2[1] && c1[2] == c2[2]) error->one(FLERR,"Invalid shape in Triangles section of data file"); if (c1[0] == c3[0] && c1[1] == c3[1] && c1[2] == c3[2]) error->one(FLERR,"Invalid shape in Triangles section of data file"); if (c2[0] == c3[0] && c2[1] == c3[1] && c2[2] == c3[2]) error->one(FLERR,"Invalid shape in Triangles section of data file"); // size = length of one edge double c2mc1[2],c3mc1[3]; MathExtra::sub3(c2,c1,c2mc1); MathExtra::sub3(c3,c1,c3mc1); double size = MAX(MathExtra::len3(c2mc1),MathExtra::len3(c3mc1)); // centroid = 1/3 of sum of vertices double centroid[3]; centroid[0] = (c1[0]+c2[0]+c3[0]) / 3.0; centroid[1] = (c1[1]+c2[1]+c3[1]) / 3.0; centroid[2] = (c1[2]+c2[2]+c3[2]) / 3.0; double dx = centroid[0] - x[m][0]; double dy = centroid[1] - x[m][1]; double dz = centroid[2] - x[m][2]; double delta = sqrt(dx*dx + dy*dy + dz*dz); if (delta/size > EPSILON) error->one(FLERR,"Inconsistent triangle in data file"); x[m][0] = centroid[0]; x[m][1] = centroid[1]; x[m][2] = centroid[2]; // reset tri mass // previously stored density in rmass // tri area = 0.5 len(U x V), where U,V are edge vectors from one vertex double norm[3]; MathExtra::cross3(c2mc1,c3mc1,norm); double area = 0.5 * MathExtra::len3(norm); rmass[m] *= area; // inertia = inertia tensor of triangle as 6-vector in Voigt notation double inertia[6]; MathExtra::inertia_triangle(c1,c2,c3,rmass[m],inertia); // diagonalize inertia tensor via Jacobi rotations // bonus[].inertia = 3 eigenvalues = principal moments of inertia // evectors and exzy_space = 3 evectors = principal axes of triangle double tensor[3][3],evectors[3][3]; tensor[0][0] = inertia[0]; tensor[1][1] = inertia[1]; tensor[2][2] = inertia[2]; tensor[1][2] = tensor[2][1] = inertia[3]; tensor[0][2] = tensor[2][0] = inertia[4]; tensor[0][1] = tensor[1][0] = inertia[5]; int ierror = MathExtra::jacobi(tensor,bonus[nlocal_bonus].inertia,evectors); if (ierror) error->one(FLERR,"Insufficient Jacobi rotations for triangle"); double ex_space[3],ey_space[3],ez_space[3]; ex_space[0] = evectors[0][0]; ex_space[1] = evectors[1][0]; ex_space[2] = evectors[2][0]; ey_space[0] = evectors[0][1]; ey_space[1] = evectors[1][1]; ey_space[2] = evectors[2][1]; ez_space[0] = evectors[0][2]; ez_space[1] = evectors[1][2]; ez_space[2] = evectors[2][2]; // enforce 3 orthogonal vectors as a right-handed coordinate system // flip 3rd vector if needed MathExtra::cross3(ex_space,ey_space,norm); if (MathExtra::dot3(norm,ez_space) < 0.0) MathExtra::negate3(ez_space); // create initial quaternion MathExtra::exyz_to_q(ex_space,ey_space,ez_space,bonus[nlocal_bonus].quat); // bonus c1,c2,c3 = displacement of c1,c2,c3 from centroid // in basis of principal axes double disp[3]; MathExtra::sub3(c1,centroid,disp); MathExtra::transpose_matvec(ex_space,ey_space,ez_space, disp,bonus[nlocal_bonus].c1); MathExtra::sub3(c2,centroid,disp); MathExtra::transpose_matvec(ex_space,ey_space,ez_space, disp,bonus[nlocal_bonus].c2); MathExtra::sub3(c3,centroid,disp); MathExtra::transpose_matvec(ex_space,ey_space,ez_space, disp,bonus[nlocal_bonus].c3); bonus[nlocal_bonus].ilocal = m; tri[m] = nlocal_bonus++; } /* ---------------------------------------------------------------------- unpack one line from Velocities section of data file ------------------------------------------------------------------------- */ void AtomVecTri::data_vel(int m, char **values) { v[m][0] = atof(values[0]); v[m][1] = atof(values[1]); v[m][2] = atof(values[2]); angmom[m][0] = atof(values[3]); angmom[m][1] = atof(values[4]); angmom[m][2] = atof(values[5]); } /* ---------------------------------------------------------------------- unpack hybrid quantities from one tri in Velocities section of data file ------------------------------------------------------------------------- */ int AtomVecTri::data_vel_hybrid(int m, char **values) { angmom[m][0] = atof(values[0]); angmom[m][1] = atof(values[1]); angmom[m][2] = atof(values[2]); return 3; } /* ---------------------------------------------------------------------- pack atom info for data file including 3 image flags ------------------------------------------------------------------------- */ void AtomVecTri::pack_data(double **buf) { double c2mc1[2],c3mc1[3],norm[3]; double area; int nlocal = atom->nlocal; for (int i = 0; i < nlocal; i++) { buf[i][0] = ubuf(tag[i]).d; buf[i][1] = ubuf(molecule[i]).d; buf[i][2] = ubuf(type[i]).d; if (tri[i] < 0) buf[i][3] = ubuf(0).d; else buf[i][3] = ubuf(1).d; if (tri[i] < 0) buf[i][4] = rmass[i]; else { MathExtra::sub3(bonus[tri[i]].c2,bonus[tri[i]].c1,c2mc1); MathExtra::sub3(bonus[tri[i]].c3,bonus[tri[i]].c1,c3mc1); MathExtra::cross3(c2mc1,c3mc1,norm); area = 0.5 * MathExtra::len3(norm); buf[i][4] = rmass[i]/area; } buf[i][5] = x[i][0]; buf[i][6] = x[i][1]; buf[i][7] = x[i][2]; buf[i][8] = ubuf((image[i] & IMGMASK) - IMGMAX).d; buf[i][9] = ubuf((image[i] >> IMGBITS & IMGMASK) - IMGMAX).d; buf[i][10] = ubuf((image[i] >> IMG2BITS) - IMGMAX).d; } } /* ---------------------------------------------------------------------- pack hybrid atom info for data file ------------------------------------------------------------------------- */ int AtomVecTri::pack_data_hybrid(int i, double *buf) { buf[0] = ubuf(molecule[i]).d; if (tri[i] < 0) buf[1] = ubuf(0).d; else buf[1] = ubuf(1).d; if (tri[i] < 0) buf[2] = rmass[i]; else { double c2mc1[2],c3mc1[3],norm[3]; MathExtra::sub3(bonus[tri[i]].c2,bonus[tri[i]].c1,c2mc1); MathExtra::sub3(bonus[tri[i]].c3,bonus[tri[i]].c1,c3mc1); MathExtra::cross3(c2mc1,c3mc1,norm); double area = 0.5 * MathExtra::len3(norm); buf[2] = rmass[i]/area; } return 3; } /* ---------------------------------------------------------------------- write atom info to data file including 3 image flags ------------------------------------------------------------------------- */ void AtomVecTri::write_data(FILE *fp, int n, double **buf) { for (int i = 0; i < n; i++) fprintf(fp,"%d %d %d %d %-1.16e %-1.16e %-1.16e %-1.16e %d %d %d\n", (int) ubuf(buf[i][0]).i,(int) ubuf(buf[i][1]).i, (int) ubuf(buf[i][2]).i,(int) ubuf(buf[i][3]).i, buf[i][4],buf[i][5],buf[i][6],buf[i][7], (int) ubuf(buf[i][8]).i,(int) ubuf(buf[i][9]).i, (int) ubuf(buf[i][10]).i); } /* ---------------------------------------------------------------------- write hybrid atom info to data file ------------------------------------------------------------------------- */ int AtomVecTri::write_data_hybrid(FILE *fp, double *buf) { fprintf(fp," %d %d %-1.16e",(int) ubuf(buf[0]).i,(int) ubuf(buf[1]).i,buf[2]); return 3; } /* ---------------------------------------------------------------------- pack velocity info for data file ------------------------------------------------------------------------- */ void AtomVecTri::pack_vel(double **buf) { int nlocal = atom->nlocal; for (int i = 0; i < nlocal; i++) { buf[i][0] = ubuf(tag[i]).d; buf[i][1] = v[i][0]; buf[i][2] = v[i][1]; buf[i][3] = v[i][2]; buf[i][4] = angmom[i][0]; buf[i][5] = angmom[i][1]; buf[i][6] = angmom[i][2]; } } /* ---------------------------------------------------------------------- pack hybrid velocity info for data file ------------------------------------------------------------------------- */ int AtomVecTri::pack_vel_hybrid(int i, double *buf) { buf[0] = angmom[i][0]; buf[1] = angmom[i][1]; buf[2] = angmom[i][2]; return 3; } /* ---------------------------------------------------------------------- write velocity info to data file ------------------------------------------------------------------------- */ void AtomVecTri::write_vel(FILE *fp, int n, double **buf) { for (int i = 0; i < n; i++) fprintf(fp,"%d %-1.16e %-1.16e %-1.16e %-1.16e %-1.16e %-1.16e\n", (int) ubuf(buf[i][0]).i,buf[i][1],buf[i][2],buf[i][3], buf[i][4],buf[i][5],buf[i][6]); } /* ---------------------------------------------------------------------- write hybrid velocity info to data file ------------------------------------------------------------------------- */ int AtomVecTri::write_vel_hybrid(FILE *fp, double *buf) { fprintf(fp," %-1.16e %-1.16e %-1.16e",buf[0],buf[1],buf[2]); return 3; } /* ---------------------------------------------------------------------- return # of bytes of allocated memory ------------------------------------------------------------------------- */ bigint AtomVecTri::memory_usage() { bigint bytes = 0; if (atom->memcheck("tag")) bytes += memory->usage(tag,nmax); if (atom->memcheck("type")) bytes += memory->usage(type,nmax); if (atom->memcheck("mask")) bytes += memory->usage(mask,nmax); if (atom->memcheck("image")) bytes += memory->usage(image,nmax); if (atom->memcheck("x")) bytes += memory->usage(x,nmax,3); if (atom->memcheck("v")) bytes += memory->usage(v,nmax,3); if (atom->memcheck("f")) bytes += memory->usage(f,nmax*comm->nthreads,3); if (atom->memcheck("molecule")) bytes += memory->usage(molecule,nmax); if (atom->memcheck("rmass")) bytes += memory->usage(rmass,nmax); if (atom->memcheck("angmom")) bytes += memory->usage(angmom,nmax,3); if (atom->memcheck("torque")) bytes += memory->usage(torque,nmax*comm->nthreads,3); if (atom->memcheck("tri")) bytes += memory->usage(tri,nmax); bytes += nmax_bonus*sizeof(Bonus); return bytes; }