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Kurt A. O'Hearn authoredKurt A. O'Hearn authored
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init_md.c 29.03 KiB
/*----------------------------------------------------------------------
SerialReax - Reax Force Field Simulator
Copyright (2010) Purdue University
Hasan Metin Aktulga, haktulga@cs.purdue.edu
Joseph Fogarty, jcfogart@mail.usf.edu
Sagar Pandit, pandit@usf.edu
Ananth Y Grama, ayg@cs.purdue.edu
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License as
published by the Free Software Foundation; either version 2 of
the License, or (at your option) any later version.
This program 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 General Public License for more details:
<http://www.gnu.org/licenses/>.
----------------------------------------------------------------------*/
#include "init_md.h"
#include "allocate.h"
#include "box.h"
#include "forces.h"
#include "grid.h"
#include "integrate.h"
#include "lin_alg.h"
#include "neighbors.h"
#include "list.h"
#include "lookup.h"
#include "print_utils.h"
#include "reset_utils.h"
#include "system_props.h"
#include "traj.h"
#include "vector.h"
void Generate_Initial_Velocities( reax_system *system, real T )
{
int i;
real scale, norm;
if ( T <= 0.1 )
{
for (i = 0; i < system->N; i++)
rvec_MakeZero( system->atoms[i].v );
#if defined(DEBUG)
fprintf( stderr, "no random velocities...\n" );
#endif
}
else
{
for ( i = 0; i < system->N; i++ )
{
rvec_Random( system->atoms[i].v );
norm = rvec_Norm_Sqr( system->atoms[i].v );
scale = SQRT( system->reaxprm.sbp[ system->atoms[i].type ].mass *
norm / (3.0 * K_B * T) );
rvec_Scale( system->atoms[i].v, 1.0 / scale, system->atoms[i].v );
/*fprintf( stderr, "v = %f %f %f\n",
system->atoms[i].v[0],system->atoms[i].v[1],system->atoms[i].v[2]);
fprintf( stderr, "scale = %f\n", scale );
fprintf( stderr, "v = %f %f %f\n",
system->atoms[i].v[0],system->atoms[i].v[1],system->atoms[i].v[2]);*/
} }
}
void Init_System( reax_system *system, control_params *control,
simulation_data *data )
{
int i;
rvec dx;
if ( !control->restart )
Reset_Atoms( system );
Compute_Total_Mass( system, data );
Compute_Center_of_Mass( system, data, stderr );
/* reposition atoms */
// just fit the atoms to the periodic box
if ( control->reposition_atoms == 0 )
{
rvec_MakeZero( dx );
}
// put the center of mass to the center of the box
else if ( control->reposition_atoms == 1 )
{
rvec_Scale( dx, 0.5, system->box.box_norms );
rvec_ScaledAdd( dx, -1., data->xcm );
}
// put the center of mass to the origin
else if ( control->reposition_atoms == 2 )
{
rvec_Scale( dx, -1., data->xcm );
}
else
{
fprintf( stderr, "UNKNOWN OPTION: reposition_atoms. Terminating...\n" );
exit( UNKNOWN_OPTION );
}
for ( i = 0; i < system->N; ++i )
{
Inc_on_T3( system->atoms[i].x, dx, &(system->box) );
/*fprintf( stderr, "%6d%2d%8.3f%8.3f%8.3f\n",
i, system->atoms[i].type,
system->atoms[i].x[0], system->atoms[i].x[1], system->atoms[i].x[2] );*/
}
/* Initialize velocities so that desired init T can be attained */
if ( !control->restart || (control->restart && control->random_vel) )
Generate_Initial_Velocities( system, control->T_init );
Setup_Grid( system );
}
void Init_Simulation_Data( reax_system *system, control_params *control,
simulation_data *data, output_controls *out_control,
evolve_function *Evolve )
{
Reset_Simulation_Data( data );
if ( !control->restart )
data->step = data->prev_steps = 0;
switch ( control->ensemble )
{
case NVE:
data->N_f = 3 * system->N;
*Evolve = Velocity_Verlet_NVE; break;
case NVT:
data->N_f = 3 * system->N + 1;
//control->Tau_T = 100 * data->N_f * K_B * control->T_final;
if ( !control->restart || (control->restart && control->random_vel) )
{
data->therm.G_xi = control->Tau_T * (2.0 * data->E_Kin -
data->N_f * K_B * control->T );
data->therm.v_xi = data->therm.G_xi * control->dt;
data->therm.v_xi_old = 0;
data->therm.xi = 0;
#if defined(DEBUG_FOCUS)
fprintf( stderr, "init_md: G_xi=%f Tau_T=%f E_kin=%f N_f=%f v_xi=%f\n",
data->therm.G_xi, control->Tau_T, data->E_Kin,
data->N_f, data->therm.v_xi );
#endif
}
*Evolve = Velocity_Verlet_Nose_Hoover_NVT_Klein;
break;
case NPT: // Anisotropic NPT
fprintf( stderr, "THIS OPTION IS NOT YET IMPLEMENTED! TERMINATING...\n" );
exit( UNKNOWN_OPTION );
data->N_f = 3 * system->N + 9;
if ( !control->restart )
{
data->therm.G_xi = control->Tau_T * (2.0 * data->E_Kin -
data->N_f * K_B * control->T );
data->therm.v_xi = data->therm.G_xi * control->dt;
data->iso_bar.eps = 0.33333 * log(system->box.volume);
//data->inv_W = 1. / (data->N_f*K_B*control->T*SQR(control->Tau_P));
//Compute_Pressure( system, data, workspace );
}
*Evolve = Velocity_Verlet_Berendsen_Isotropic_NPT;
break;
case sNPT: // Semi-Isotropic NPT
data->N_f = 3 * system->N + 4;
*Evolve = Velocity_Verlet_Berendsen_SemiIsotropic_NPT;
break;
case iNPT: // Isotropic NPT
data->N_f = 3 * system->N + 2;
*Evolve = Velocity_Verlet_Berendsen_Isotropic_NPT;
break;
case bNVT:
data->N_f = 3 * system->N + 1;
*Evolve = Velocity_Verlet_Berendsen_NVT;
fprintf (stderr, " Initializing Velocity_Verlet_Berendsen_NVT .... \n");
break;
default:
break;
}
Compute_Kinetic_Energy( system, data );
/* init timing info */
data->timing.start = Get_Time( );
data->timing.total = data->timing.start;
data->timing.nbrs = 0;
data->timing.init_forces = 0;
data->timing.bonded = 0; data->timing.nonb = 0;
data->timing.cm = ZERO;
data->timing.cm_sort_mat_rows = ZERO;
data->timing.cm_solver_pre_comp = ZERO;
data->timing.cm_solver_pre_app = ZERO;
data->timing.cm_solver_iters = 0;
data->timing.cm_solver_spmv = ZERO;
data->timing.cm_solver_vector_ops = ZERO;
data->timing.cm_solver_orthog = ZERO;
data->timing.cm_solver_tri_solve = ZERO;
}
/* Initialize Taper params */
void Init_Taper( control_params *control )
{
real d1, d7;
real swa, swa2, swa3;
real swb, swb2, swb3;
swa = control->r_low;
swb = control->r_cut;
if ( FABS( swa ) > 0.01 )
{
fprintf( stderr, "Warning: non-zero value for lower Taper-radius cutoff\n" );
}
if ( swb < 0.0 )
{
fprintf( stderr, "Negative value for upper Taper-radius cutoff\n" );
exit( INVALID_INPUT );
}
else if ( swb < 5.0 )
{
fprintf( stderr, "Warning: low value for upper Taper-radius cutoff:%f\n", swb );
}
d1 = swb - swa;
d7 = POW( d1, 7.0 );
swa2 = SQR( swa );
swa3 = CUBE( swa );
swb2 = SQR( swb );
swb3 = CUBE( swb );
control->Tap7 = 20.0 / d7;
control->Tap6 = -70.0 * (swa + swb) / d7;
control->Tap5 = 84.0 * (swa2 + 3.0 * swa * swb + swb2) / d7;
control->Tap4 = -35.0 * (swa3 + 9.0 * swa2 * swb + 9.0 * swa * swb2 + swb3 ) / d7;
control->Tap3 = 140.0 * (swa3 * swb + 3.0 * swa2 * swb2 + swa * swb3 ) / d7;
control->Tap2 = -210.0 * (swa3 * swb2 + swa2 * swb3) / d7;
control->Tap1 = 140.0 * swa3 * swb3 / d7;
control->Tap0 = (-35.0 * swa3 * swb2 * swb2 + 21.0 * swa2 * swb3 * swb2 +
7.0 * swa * swb3 * swb3 + swb3 * swb3 * swb ) / d7;
}
void Init_Workspace( reax_system *system, control_params *control,
static_storage *workspace )
{
int i;
/* Allocate space for hydrogen bond list */
workspace->hbond_index = (int *) malloc( system->N * sizeof( int ) );
/* bond order related storage */
workspace->total_bond_order = (real *) malloc( system->N * sizeof( real ) );
workspace->Deltap = (real *) malloc( system->N * sizeof( real ) );
workspace->Deltap_boc = (real *) malloc( system->N * sizeof( real ) );
workspace->dDeltap_self = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->Delta = (real *) malloc( system->N * sizeof( real ) );
workspace->Delta_lp = (real *) malloc( system->N * sizeof( real ) );
workspace->Delta_lp_temp = (real *) malloc( system->N * sizeof( real ) );
workspace->dDelta_lp = (real *) malloc( system->N * sizeof( real ) );
workspace->dDelta_lp_temp = (real *) malloc( system->N * sizeof( real ) );
workspace->Delta_e = (real *) malloc( system->N * sizeof( real ) );
workspace->Delta_boc = (real *) malloc( system->N * sizeof( real ) );
workspace->nlp = (real *) malloc( system->N * sizeof( real ) );
workspace->nlp_temp = (real *) malloc( system->N * sizeof( real ) );
workspace->Clp = (real *) malloc( system->N * sizeof( real ) );
workspace->CdDelta = (real *) malloc( system->N * sizeof( real ) );
workspace->vlpex = (real *) malloc( system->N * sizeof( real ) );
/* charge method storage */
switch ( control->charge_method )
{
case QEQ_CM:
system->N_cm = system->N;
break;
case EEM_CM:
system->N_cm = system->N + 1;
break;
case ACKS2_CM:
system->N_cm = 2 * system->N + 2;
break;
default:
fprintf( stderr, "Unknown charge method type. Terminating...\n" );
exit( INVALID_INPUT );
break;
}
workspace->H = NULL;
workspace->H_sp = NULL;
workspace->L = NULL;
workspace->U = NULL;
workspace->H_EEM = NULL;
workspace->L_EEM = NULL;
workspace->U_EEM = NULL;
workspace->H_ACKS2_1 = NULL;
workspace->H_ACKS2_2 = NULL;
workspace->L_ACKS2_1 = NULL;
workspace->L_ACKS2_2 = NULL;
workspace->U_ACKS2_1 = NULL;
workspace->U_ACKS2_2 = NULL;
workspace->Hdia_inv = NULL;
if ( control->cm_solver_pre_comp_type == ICHOLT_PC ||
control->cm_solver_pre_comp_type == ILUT_PAR_PC )
{
workspace->droptol = (real *) calloc( system->N_cm, sizeof( real ) );
}
//TODO: check if unused
//workspace->w = (real *) calloc( cm_lin_sys_size, sizeof( real ) );
//TODO: check if unused
workspace->b = (real *) calloc( system->N_cm * 2, sizeof( real ) );
workspace->b_s = (real *) calloc( system->N_cm, sizeof( real ) );
workspace->b_t = (real *) calloc( system->N_cm, sizeof( real ) );
workspace->b_prc = (real *) calloc( system->N_cm * 2, sizeof( real ) );
workspace->b_prm = (real *) calloc( system->N_cm * 2, sizeof( real ) );
//TODO: check if unused
//workspace->s_t = (real *) calloc( cm_lin_sys_size * 2, sizeof( real ) );
workspace->s = (real**) calloc( 5, sizeof( real* ) );
workspace->t = (real**) calloc( 5, sizeof( real* ) );
for ( i = 0; i < 5; ++i )
{
workspace->s[i] = (real *) calloc( system->N_cm, sizeof( real ) );
workspace->t[i] = (real *) calloc( system->N_cm, sizeof( real ) );
}
switch ( control->charge_method ) {
case QEQ_CM:
for ( i = 0; i < system->N; ++i )
{
workspace->b_s[i] = -system->reaxprm.sbp[ system->atoms[i].type ].chi;
workspace->b_t[i] = -1.0;
//TODO: check if unused (redundant)
workspace->b[i] = -system->reaxprm.sbp[ system->atoms[i].type ].chi;
workspace->b[i + system->N] = -1.0;
}
break;
case EEM_CM:
for ( i = 0; i < system->N; ++i )
{
workspace->b_s[i] = -system->reaxprm.sbp[ system->atoms[i].type ].chi;
//TODO: check if unused (redundant)
workspace->b[i] = -system->reaxprm.sbp[ system->atoms[i].type ].chi;
}
workspace->b_s[system->N] = control->cm_q_net;
workspace->b[system->N] = control->cm_q_net;
break;
case ACKS2_CM:
//TODO
break;
default:
fprintf( stderr, "Unknown charge method type. Terminating...\n" );
exit( INVALID_INPUT );
break;
}
switch ( control->cm_solver_type )
{
/* GMRES storage */
case GMRES_S:
case GMRES_H_S:
workspace->y = (real *) calloc( RESTART + 1, sizeof( real ) );
workspace->z = (real *) calloc( RESTART + 1, sizeof( real ) );
workspace->g = (real *) calloc( RESTART + 1, sizeof( real ) );
workspace->h = (real **) calloc( RESTART + 1, sizeof( real*) );
workspace->hs = (real *) calloc( RESTART + 1, sizeof( real ) );
workspace->hc = (real *) calloc( RESTART + 1, sizeof( real ) );
workspace->rn = (real **) calloc( RESTART + 1, sizeof( real*) );
workspace->v = (real **) calloc( RESTART + 1, sizeof( real*) );
for ( i = 0; i < RESTART + 1; ++i )
{
workspace->h[i] = (real *) calloc( RESTART + 1, sizeof( real ) );
workspace->rn[i] = (real *) calloc( system->N_cm * 2, sizeof( real ) );
workspace->v[i] = (real *) calloc( system->N_cm, sizeof( real ) );
}
workspace->r = (real *) calloc( system->N_cm, sizeof( real ) );
workspace->d = (real *) calloc( system->N_cm, sizeof( real ) );
workspace->q = (real *) calloc( system->N_cm, sizeof( real ) );
workspace->p = (real *) calloc( system->N_cm, sizeof( real ) );
break;
/* CG storage */
case CG_S:
workspace->r = (real *) calloc( system->N_cm, sizeof( real ) );
workspace->d = (real *) calloc( system->N_cm, sizeof( real ) );
workspace->q = (real *) calloc( system->N_cm, sizeof( real ) );
workspace->p = (real *) calloc( system->N_cm, sizeof( real ) );
break;
case SDM_S:
//TODO
break;
default:
fprintf( stderr, "Unknown charge method linear solver type. Terminating...\n" );
exit( INVALID_INPUT );
break;
}
/* integrator storage */
workspace->a = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_old = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->v_const = (rvec *) malloc( system->N * sizeof( rvec ) );
/* storage for analysis */
if ( control->molec_anal || control->diffusion_coef )
{
workspace->mark = (int *) calloc( system->N, sizeof(int) );
workspace->old_mark = (int *) calloc( system->N, sizeof(int) );
}
else
{
workspace->mark = workspace->old_mark = NULL;
}
if ( control->diffusion_coef )
{
workspace->x_old = (rvec *) calloc( system->N, sizeof( rvec ) );
}
else
{
workspace->x_old = NULL;
}
#ifdef TEST_FORCES
workspace->dDelta = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_ele = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_vdw = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_bo = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_be = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_lp = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_ov = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_un = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_ang = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_coa = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_pen = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_hb = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_tor = (rvec *) malloc( system->N * sizeof( rvec ) );
workspace->f_con = (rvec *) malloc( system->N * sizeof( rvec ) );
#endif
workspace->realloc.num_far = -1;
workspace->realloc.Htop = -1;
workspace->realloc.hbonds = -1;
workspace->realloc.bonds = -1;
workspace->realloc.num_3body = -1;
workspace->realloc.gcell_atoms = -1;
Reset_Workspace( system, workspace );
/* Initialize Taper function */
Init_Taper( control );
}
void Init_Lists( reax_system *system, control_params *control,
simulation_data *data, static_storage *workspace,
list **lists, output_controls *out_control ){
int i, num_nbrs, num_hbonds, num_bonds, num_3body, Htop;
int *hb_top, *bond_top;
num_nbrs = Estimate_NumNeighbors( system, control, workspace, lists );
if ( !Make_List(system->N, num_nbrs, TYP_FAR_NEIGHBOR, (*lists) + FAR_NBRS) )
{
fprintf(stderr, "Problem in initializing far nbrs list. Terminating!\n");
exit( CANNOT_INITIALIZE );
}
#if defined(DEBUG_FOCUS)
fprintf( stderr, "memory allocated: far_nbrs = %ldMB\n",
num_nbrs * sizeof(far_neighbor_data) / (1024 * 1024) );
#endif
Generate_Neighbor_Lists(system, control, data, workspace, lists, out_control);
Htop = 0;
hb_top = (int*) calloc( system->N, sizeof(int) );
bond_top = (int*) calloc( system->N, sizeof(int) );
num_3body = 0;
Estimate_Storage_Sizes( system, control, lists, &Htop,
hb_top, bond_top, &num_3body );
if ( Allocate_Matrix( &(workspace->H), system->N_cm, Htop ) == FAILURE )
{
fprintf( stderr, "Not enough space for init matrices. Terminating...\n" );
exit( INSUFFICIENT_MEMORY );
}
/* TODO: better estimate for H_sp?
* If so, need to refactor Estimate_Storage_Sizes
* to use various cut-off distances as parameters
* (non-bonded, hydrogen, 3body, etc.) */
if ( Allocate_Matrix( &(workspace->H_sp), system->N_cm, Htop ) == FAILURE )
{
fprintf( stderr, "Not enough space for init matrices. Terminating...\n" );
exit( INSUFFICIENT_MEMORY );
}
#if defined(DEBUG_FOCUS)
fprintf( stderr, "estimated storage - Htop: %d\n", Htop );
fprintf( stderr, "memory allocated: H = %ldMB\n",
Htop * sizeof(sparse_matrix_entry) / (1024 * 1024) );
#endif
workspace->num_H = 0;
if ( control->hb_cut > 0 )
{
/* init H indexes */
for ( i = 0; i < system->N; ++i )
{
// H atom
if ( system->reaxprm.sbp[ system->atoms[i].type ].p_hbond == 1 )
{
workspace->hbond_index[i] = workspace->num_H++;
}
else
{
workspace->hbond_index[i] = -1;
}
}
Allocate_HBond_List( system->N, workspace->num_H, workspace->hbond_index,
hb_top, (*lists) + HBONDS );
num_hbonds = hb_top[system->N - 1];
#if defined(DEBUG_FOCUS)
fprintf( stderr, "estimated storage - num_hbonds: %d\n", num_hbonds );
fprintf( stderr, "memory allocated: hbonds = %ldMB\n", num_hbonds * sizeof(hbond_data) / (1024 * 1024) );
#endif
}
/* bonds list */
Allocate_Bond_List( system->N, bond_top, (*lists) + BONDS );
num_bonds = bond_top[system->N - 1];
#if defined(DEBUG_FOCUS)
fprintf( stderr, "estimated storage - num_bonds: %d\n", num_bonds );
fprintf( stderr, "memory allocated: bonds = %ldMB\n",
num_bonds * sizeof(bond_data) / (1024 * 1024) );
#endif
//fprintf (stderr, " **** sizeof 3 body : %d \n", sizeof (three_body_interaction_data));
//fprintf (stderr, " **** num_3body : %d \n", num_3body);
//fprintf (stderr, " **** num_bonds : %d \n", num_bonds);
/* 3bodies list */
if (!Make_List(num_bonds, num_3body, TYP_THREE_BODY, (*lists) + THREE_BODIES))
{
fprintf( stderr, "Problem in initializing angles list. Terminating!\n" );
exit( CANNOT_INITIALIZE );
}
#if defined(DEBUG_FOCUS)
fprintf( stderr, "estimated storage - num_3body: %d\n", num_3body );
fprintf( stderr, "memory allocated: 3-body = %ldMB\n",
num_3body * sizeof(three_body_interaction_data) / (1024 * 1024) );
#endif
#ifdef TEST_FORCES
if (!Make_List( system->N, num_bonds * 8, TYP_DDELTA, (*lists) + DDELTA ))
{
fprintf( stderr, "Problem in initializing dDelta list. Terminating!\n" );
exit( CANNOT_INITIALIZE );
}
if ( !Make_List( num_bonds, num_bonds * MAX_BONDS * 3, TYP_DBO, (*lists) + DBO ) )
{
fprintf( stderr, "Problem in initializing dBO list. Terminating!\n" );
exit( CANNOT_INITIALIZE );
}
#endif
free( hb_top );
free( bond_top );
}
void Init_Out_Controls(reax_system *system, control_params *control,
static_storage *workspace, output_controls *out_control)
{
char temp[1000];
/* Init trajectory file */
if ( out_control->write_steps > 0 )
{
strcpy( temp, control->sim_name );
strcat( temp, ".trj" );
out_control->trj = fopen( temp, "w" );
out_control->write_header( system, control, workspace, out_control );
}
if ( out_control->energy_update_freq > 0 )
{
/* Init out file */
strcpy( temp, control->sim_name );
strcat( temp, ".out" );
out_control->out = fopen( temp, "w" ); fprintf( out_control->out, "%-6s%16s%16s%16s%11s%11s%13s%13s%13s\n",
"step", "total energy", "poten. energy", "kin. energy",
"temp.", "target", "volume", "press.", "target" );
fflush( out_control->out );
/* Init potentials file */
strcpy( temp, control->sim_name );
strcat( temp, ".pot" );
out_control->pot = fopen( temp, "w" );
fprintf( out_control->pot,
"%-6s%13s%13s%13s%13s%13s%13s%13s%13s%13s%13s%13s\n",
"step", "ebond", "eatom", "elp", "eang", "ecoa", "ehb",
"etor", "econj", "evdw", "ecoul", "epol" );
fflush( out_control->pot );
/* Init log file */
strcpy( temp, control->sim_name );
strcat( temp, ".log" );
out_control->log = fopen( temp, "w" );
fprintf( out_control->log, "%-6s %10s %10s %10s %10s %10s %10s %10s %10s %10s %10s %10s %10s %10s %10s\n",
"step", "total", "neighbors", "init", "bonded",
"nonbonded", "CM", "CM Sort", "S iters", "Pre Comp", "Pre App",
"S spmv", "S vec ops", "S orthog", "S tsolve" );
}
/* Init pressure file */
if ( control->ensemble == NPT ||
control->ensemble == iNPT ||
control->ensemble == sNPT )
{
strcpy( temp, control->sim_name );
strcat( temp, ".prs" );
out_control->prs = fopen( temp, "w" );
fprintf( out_control->prs, "%-6s%13s%13s%13s%13s%13s%13s%13s%13s\n",
"step", "norm_x", "norm_y", "norm_z",
"press_x", "press_y", "press_z", "target_p", "volume" );
fflush( out_control->prs );
}
/* Init molecular analysis file */
if ( control->molec_anal )
{
sprintf( temp, "%s.mol", control->sim_name );
out_control->mol = fopen( temp, "w" );
if ( control->num_ignored )
{
sprintf( temp, "%s.ign", control->sim_name );
out_control->ign = fopen( temp, "w" );
}
}
/* Init electric dipole moment analysis file */
if ( control->dipole_anal )
{
strcpy( temp, control->sim_name );
strcat( temp, ".dpl" );
out_control->dpl = fopen( temp, "w" );
fprintf( out_control->dpl,
"Step Molecule Count Avg. Dipole Moment Norm\n" );
fflush( out_control->dpl );
}
/* Init diffusion coef analysis file */
if ( control->diffusion_coef )
{
strcpy( temp, control->sim_name );
strcat( temp, ".drft" );
out_control->drft = fopen( temp, "w" );
fprintf( out_control->drft, "Step Type Count Avg Squared Disp\n" );
fflush( out_control->drft ); }
#ifdef TEST_ENERGY
/* open bond energy file */
strcpy( temp, control->sim_name );
strcat( temp, ".ebond" );
out_control->ebond = fopen( temp, "w" );
/* open lone-pair energy file */
strcpy( temp, control->sim_name );
strcat( temp, ".elp" );
out_control->elp = fopen( temp, "w" );
/* open overcoordination energy file */
strcpy( temp, control->sim_name );
strcat( temp, ".eov" );
out_control->eov = fopen( temp, "w" );
/* open undercoordination energy file */
strcpy( temp, control->sim_name );
strcat( temp, ".eun" );
out_control->eun = fopen( temp, "w" );
/* open angle energy file */
strcpy( temp, control->sim_name );
strcat( temp, ".eval" );
out_control->eval = fopen( temp, "w" );
/* open penalty energy file */
strcpy( temp, control->sim_name );
strcat( temp, ".epen" );
out_control->epen = fopen( temp, "w" );
/* open coalition energy file */
strcpy( temp, control->sim_name );
strcat( temp, ".ecoa" );
out_control->ecoa = fopen( temp, "w" );
/* open hydrogen bond energy file */
strcpy( temp, control->sim_name );
strcat( temp, ".ehb" );
out_control->ehb = fopen( temp, "w" );
/* open torsion energy file */
strcpy( temp, control->sim_name );
strcat( temp, ".etor" );
out_control->etor = fopen( temp, "w" );
/* open conjugation energy file */
strcpy( temp, control->sim_name );
strcat( temp, ".econ" );
out_control->econ = fopen( temp, "w" );
/* open vdWaals energy file */
strcpy( temp, control->sim_name );
strcat( temp, ".evdw" );
out_control->evdw = fopen( temp, "w" );
/* open coulomb energy file */
strcpy( temp, control->sim_name );
strcat( temp, ".ecou" );
out_control->ecou = fopen( temp, "w" );
#endif
#ifdef TEST_FORCES
/* open bond orders file */
strcpy( temp, control->sim_name );
strcat( temp, ".fbo" ); out_control->fbo = fopen( temp, "w" );
/* open bond orders derivatives file */
strcpy( temp, control->sim_name );
strcat( temp, ".fdbo" );
out_control->fdbo = fopen( temp, "w" );
/* open bond forces file */
strcpy( temp, control->sim_name );
strcat( temp, ".fbond" );
out_control->fbond = fopen( temp, "w" );
/* open lone-pair forces file */
strcpy( temp, control->sim_name );
strcat( temp, ".flp" );
out_control->flp = fopen( temp, "w" );
/* open overcoordination forces file */
strcpy( temp, control->sim_name );
strcat( temp, ".fatom" );
out_control->fatom = fopen( temp, "w" );
/* open angle forces file */
strcpy( temp, control->sim_name );
strcat( temp, ".f3body" );
out_control->f3body = fopen( temp, "w" );
/* open hydrogen bond forces file */
strcpy( temp, control->sim_name );
strcat( temp, ".fhb" );
out_control->fhb = fopen( temp, "w" );
/* open torsion forces file */
strcpy( temp, control->sim_name );
strcat( temp, ".f4body" );
out_control->f4body = fopen( temp, "w" );
/* open nonbonded forces file */
strcpy( temp, control->sim_name );
strcat( temp, ".fnonb" );
out_control->fnonb = fopen( temp, "w" );
/* open total force file */
strcpy( temp, control->sim_name );
strcat( temp, ".ftot" );
out_control->ftot = fopen( temp, "w" );
/* open coulomb forces file */
strcpy( temp, control->sim_name );
strcat( temp, ".ftot2" );
out_control->ftot2 = fopen( temp, "w" );
#endif
/* Error handling */
/* if ( out_control->out == NULL || out_control->pot == NULL ||
out_control->log == NULL || out_control->mol == NULL ||
out_control->dpl == NULL || out_control->drft == NULL ||
out_control->pdb == NULL )
{
fprintf( stderr, "FILE OPEN ERROR. TERMINATING..." );
exit( CANNOT_OPEN_FILE );
}*/
}
void Initialize(reax_system *system, control_params *control,
simulation_data *data, static_storage *workspace, list **lists,
output_controls *out_control, evolve_function *Evolve)
{ real start, end;
Randomize();
Init_System( system, control, data );
Init_Simulation_Data( system, control, data, out_control, Evolve );
Init_Workspace( system, control, workspace );
Init_Lists( system, control, data, workspace, lists, out_control );
Init_Out_Controls( system, control, workspace, out_control );
/* These are done in forces.c, only forces.c can see all those functions */
Init_Bonded_Force_Functions( control );
#ifdef TEST_FORCES
Init_Force_Test_Functions( );
#endif
if ( control->tabulate )
{
start = Get_Time ();
Make_LR_Lookup_Table( system, control );
end = Get_Timing_Info (start);
//fprintf (stderr, "Time for LR Lookup Table calculation is %f \n", end );
}
#if defined(DEBUG_FOCUS)
fprintf( stderr, "data structures have been initialized...\n" );
#endif
}