src/brains/SimInfo.cpp

#include <stdlib.h>
#include <string.h>
#include <math.h>

#include <iostream>
using namespace std;

#include "brains/SimInfo.hpp"
#define __C
#include "brains/fSimulation.h"
#include "utils/simError.h"
#include "UseTheForce/DarkSide/simulation_interface.h"
#include "UseTheForce/notifyCutoffs_interface.h"

//#include "UseTheForce/fortranWrappers.hpp"

#include "math/MatVec3.h"

#ifdef IS_MPI
#include "brains/mpiSimulation.hpp"
#endif

inline double roundMe( double x ){
  return ( x >= 0 ) ? floor( x + 0.5 ) : ceil( x - 0.5 );
}
          
inline double min( double a, double b ){
  return (a < b ) ? a : b;
}

SimInfo* currentInfo;

SimInfo::SimInfo(){

  n_constraints = 0;
  nZconstraints = 0;
  n_oriented = 0;
  n_dipoles = 0;
  ndf = 0;
  ndfRaw = 0;
  nZconstraints = 0;
  the_integrator = NULL;
  setTemp = 0;
  thermalTime = 0.0;
  currentTime = 0.0;
  rCut = 0.0;
  rSw = 0.0;

  haveRcut = 0;
  haveRsw = 0;
  boxIsInit = 0;
  
  resetTime = 1e99;

  orthoRhombic = 0;
  orthoTolerance = 1E-6;
  useInitXSstate = true;

  usePBC = 0;
  useLJ = 0; 
  useSticky = 0;
  useCharges = 0;
  useDipoles = 0;
  useReactionField = 0;
  useGB = 0;
  useEAM = 0;
  useSolidThermInt = 0;
  useLiquidThermInt = 0;

  haveCutoffGroups = false;

  excludes = Exclude::Instance();

  myConfiguration = new SimState();

  has_minimizer = false;
  the_minimizer =NULL;

  ngroup = 0;

}


SimInfo::~SimInfo(){

  delete myConfiguration;

  map<string, GenericData*>::iterator i;
  
  for(i = properties.begin(); i != properties.end(); i++)
    delete (*i).second;

}

void SimInfo::setBox(double newBox[3]) {
  
  int i, j;
  double tempMat[3][3];

  for(i=0; i<3; i++) 
    for (j=0; j<3; j++) tempMat[i][j] = 0.0;;

  tempMat[0][0] = newBox[0];
  tempMat[1][1] = newBox[1];
  tempMat[2][2] = newBox[2];

  setBoxM( tempMat );

}

void SimInfo::setBoxM( double theBox[3][3] ){
  
  int i, j;
  double FortranHmat[9]; // to preserve compatibility with Fortran the
                         // ordering in the array is as follows:
                         // [ 0 3 6 ]
                         // [ 1 4 7 ]
                         // [ 2 5 8 ]
  double FortranHmatInv[9]; // the inverted Hmat (for Fortran);

  if( !boxIsInit ) boxIsInit = 1;

  for(i=0; i < 3; i++) 
    for (j=0; j < 3; j++) Hmat[i][j] = theBox[i][j];
  
  calcBoxL();
  calcHmatInv();

  for(i=0; i < 3; i++) {
    for (j=0; j < 3; j++) {
      FortranHmat[3*j + i] = Hmat[i][j];
      FortranHmatInv[3*j + i] = HmatInv[i][j];
    }
  }

  setFortranBox(FortranHmat, FortranHmatInv, &orthoRhombic);
 
}
 

void SimInfo::getBoxM (double theBox[3][3]) {

  int i, j;
  for(i=0; i<3; i++) 
    for (j=0; j<3; j++) theBox[i][j] = Hmat[i][j];
}


void SimInfo::scaleBox(double scale) {
  double theBox[3][3];
  int i, j;

  // cerr << "Scaling box by " << scale << "\n";

  for(i=0; i<3; i++) 
    for (j=0; j<3; j++) theBox[i][j] = Hmat[i][j]*scale;

  setBoxM(theBox);

}

void SimInfo::calcHmatInv( void ) {
  
  int oldOrtho;
  int i,j;
  double smallDiag;
  double tol;
  double sanity[3][3];

  invertMat3( Hmat, HmatInv );

  // check to see if Hmat is orthorhombic
  
  oldOrtho = orthoRhombic;

  smallDiag = fabs(Hmat[0][0]);
  if(smallDiag > fabs(Hmat[1][1])) smallDiag = fabs(Hmat[1][1]);
  if(smallDiag > fabs(Hmat[2][2])) smallDiag = fabs(Hmat[2][2]);
  tol = smallDiag * orthoTolerance;

  orthoRhombic = 1;
  
  for (i = 0; i < 3; i++ ) {
    for (j = 0 ; j < 3; j++) {
      if (i != j) {
        if (orthoRhombic) {
          if ( fabs(Hmat[i][j]) >= tol) orthoRhombic = 0;
        }        
      }
    }
  }

  if( oldOrtho != orthoRhombic ){
    
    if( orthoRhombic ) {
      sprintf( painCave.errMsg,
               "OOPSE is switching from the default Non-Orthorhombic\n"
               "\tto the faster Orthorhombic periodic boundary computations.\n"
               "\tThis is usually a good thing, but if you wan't the\n"
               "\tNon-Orthorhombic computations, make the orthoBoxTolerance\n"
               "\tvariable ( currently set to %G ) smaller.\n",
               orthoTolerance);
      painCave.severity = OOPSE_INFO;
      simError();
    }
    else {
      sprintf( painCave.errMsg,
               "OOPSE is switching from the faster Orthorhombic to the more\n"
               "\tflexible Non-Orthorhombic periodic boundary computations.\n"
               "\tThis is usually because the box has deformed under\n"
               "\tNPTf integration. If you wan't to live on the edge with\n"
               "\tthe Orthorhombic computations, make the orthoBoxTolerance\n"
               "\tvariable ( currently set to %G ) larger.\n",
               orthoTolerance);
      painCave.severity = OOPSE_WARNING;
      simError();
    }
  }
}

void SimInfo::calcBoxL( void ){

  double dx, dy, dz, dsq;

  // boxVol = Determinant of Hmat

  boxVol = matDet3( Hmat );

  // boxLx
  
  dx = Hmat[0][0]; dy = Hmat[1][0]; dz = Hmat[2][0];
  dsq = dx*dx + dy*dy + dz*dz;
  boxL[0] = sqrt( dsq );
  //maxCutoff = 0.5 * boxL[0];

  // boxLy
  
  dx = Hmat[0][1]; dy = Hmat[1][1]; dz = Hmat[2][1];
  dsq = dx*dx + dy*dy + dz*dz;
  boxL[1] = sqrt( dsq );
  //if( (0.5 * boxL[1]) < maxCutoff ) maxCutoff = 0.5 * boxL[1];


  // boxLz
  
  dx = Hmat[0][2]; dy = Hmat[1][2]; dz = Hmat[2][2];
  dsq = dx*dx + dy*dy + dz*dz;
  boxL[2] = sqrt( dsq );
  //if( (0.5 * boxL[2]) < maxCutoff ) maxCutoff = 0.5 * boxL[2];

  //calculate the max cutoff
  maxCutoff =  calcMaxCutOff(); 
  
  checkCutOffs();

}


double SimInfo::calcMaxCutOff(){

  double ri[3], rj[3], rk[3];
  double rij[3], rjk[3], rki[3];
  double minDist;

  ri[0] = Hmat[0][0];
  ri[1] = Hmat[1][0];
  ri[2] = Hmat[2][0];

  rj[0] = Hmat[0][1];
  rj[1] = Hmat[1][1];
  rj[2] = Hmat[2][1];

  rk[0] = Hmat[0][2];
  rk[1] = Hmat[1][2];
  rk[2] = Hmat[2][2];
    
  crossProduct3(ri, rj, rij);
  distXY = dotProduct3(rk,rij) / norm3(rij);

  crossProduct3(rj,rk, rjk);
  distYZ = dotProduct3(ri,rjk) / norm3(rjk);

  crossProduct3(rk,ri, rki);
  distZX = dotProduct3(rj,rki) / norm3(rki);

  minDist = min(min(distXY, distYZ), distZX);
  return minDist/2;
  
}

void SimInfo::wrapVector( double thePos[3] ){

  int i;
  double scaled[3];

  if( !orthoRhombic ){
    // calc the scaled coordinates.
  

    matVecMul3(HmatInv, thePos, scaled);
    
    for(i=0; i<3; i++)
      scaled[i] -= roundMe(scaled[i]);
    
    // calc the wrapped real coordinates from the wrapped scaled coordinates
    
    matVecMul3(Hmat, scaled, thePos);

  }
  else{
    // calc the scaled coordinates.
    
    for(i=0; i<3; i++)
      scaled[i] = thePos[i]*HmatInv[i][i];
    
    // wrap the scaled coordinates
    
    for(i=0; i<3; i++)
      scaled[i] -= roundMe(scaled[i]);
    
    // calc the wrapped real coordinates from the wrapped scaled coordinates
    
    for(i=0; i<3; i++)
      thePos[i] = scaled[i]*Hmat[i][i];
  }
    
}


int SimInfo::getNDF(){
  int ndf_local;

  ndf_local = 0;
  
  for(int i = 0; i < integrableObjects.size(); i++){
    ndf_local += 3;
    if (integrableObjects[i]->isDirectional()) {
      if (integrableObjects[i]->isLinear())
        ndf_local += 2;
      else
        ndf_local += 3;
    }
  }

  // n_constraints is local, so subtract them on each processor:

  ndf_local -= n_constraints;

#ifdef IS_MPI
  MPI_Allreduce(&ndf_local,&ndf,1,MPI_INT,MPI_SUM, MPI_COMM_WORLD);
#else
  ndf = ndf_local;
#endif

  // nZconstraints is global, as are the 3 COM translations for the 
  // entire system:

  ndf = ndf - 3 - nZconstraints;

  return ndf;
}

int SimInfo::getNDFraw() {
  int ndfRaw_local;

  // Raw degrees of freedom that we have to set
  ndfRaw_local = 0;

  for(int i = 0; i < integrableObjects.size(); i++){
    ndfRaw_local += 3;
    if (integrableObjects[i]->isDirectional()) {
       if (integrableObjects[i]->isLinear())
        ndfRaw_local += 2;
      else
        ndfRaw_local += 3;
    }
  }
    
#ifdef IS_MPI
  MPI_Allreduce(&ndfRaw_local,&ndfRaw,1,MPI_INT,MPI_SUM, MPI_COMM_WORLD);
#else
  ndfRaw = ndfRaw_local;
#endif

  return ndfRaw;
}

int SimInfo::getNDFtranslational() {
  int ndfTrans_local;

  ndfTrans_local = 3 * integrableObjects.size() - n_constraints;


#ifdef IS_MPI
  MPI_Allreduce(&ndfTrans_local,&ndfTrans,1,MPI_INT,MPI_SUM, MPI_COMM_WORLD);
#else
  ndfTrans = ndfTrans_local;
#endif

  ndfTrans = ndfTrans - 3 - nZconstraints;

  return ndfTrans;
}

int SimInfo::getTotIntegrableObjects() {
  int nObjs_local;
  int nObjs;

  nObjs_local =  integrableObjects.size();


#ifdef IS_MPI
  MPI_Allreduce(&nObjs_local,&nObjs,1,MPI_INT,MPI_SUM, MPI_COMM_WORLD);
#else
  nObjs = nObjs_local;
#endif


  return nObjs;
}

void SimInfo::refreshSim(){

  simtype fInfo;
  int isError;
  int n_global;
  int* excl;

  fInfo.dielect = 0.0;

  if( useDipoles ){
    if( useReactionField )fInfo.dielect = dielectric;
  }

  fInfo.SIM_uses_PBC = usePBC;
  //fInfo.SIM_uses_LJ = 0;
  fInfo.SIM_uses_LJ = useLJ;
  fInfo.SIM_uses_sticky = useSticky;
  //fInfo.SIM_uses_sticky = 0;
  fInfo.SIM_uses_charges = useCharges;
  fInfo.SIM_uses_dipoles = useDipoles;
  //fInfo.SIM_uses_dipoles = 0;
  fInfo.SIM_uses_RF = useReactionField;
  //fInfo.SIM_uses_RF = 0;
  fInfo.SIM_uses_GB = useGB;
  fInfo.SIM_uses_EAM = useEAM;

  n_exclude = excludes->getSize();
  excl = excludes->getFortranArray();
  
#ifdef IS_MPI
  n_global = mpiSim->getNAtomsGlobal();
#else
  n_global = n_atoms;
#endif
  
  isError = 0;
  
  getFortranGroupArrays(this, FglobalGroupMembership, mfact);
  //it may not be a good idea to pass the address of first element in vector
  //since c++ standard does not require vector to be stored continuously in meomory
  //Most of the compilers will organize the memory of vector continuously
  setFortranSim( &fInfo, &n_global, &n_atoms, identArray, &n_exclude, excl, 
                  &nGlobalExcludes, globalExcludes, molMembershipArray, 
                  &mfact[0], &ngroup, &FglobalGroupMembership[0], &isError); 

  if( isError ){
    
    sprintf( painCave.errMsg,
             "There was an error setting the simulation information in fortran.\n" );
    painCave.isFatal = 1;
    painCave.severity = OOPSE_ERROR;
    simError();
  }
  
#ifdef IS_MPI
  sprintf( checkPointMsg,
           "succesfully sent the simulation information to fortran.\n");
  MPIcheckPoint();
#endif // is_mpi
  
  this->ndf = this->getNDF();
  this->ndfRaw = this->getNDFraw();
  this->ndfTrans = this->getNDFtranslational();
}

void SimInfo::setDefaultRcut( double theRcut ){
  
  haveRcut = 1;
  rCut = theRcut;
  rList = rCut + 1.0; 
  
  notifyFortranCutoffs( &rCut, &rSw, &rList );
}

void SimInfo::setDefaultRcut( double theRcut, double theRsw ){

  rSw = theRsw;
  setDefaultRcut( theRcut );
}


void SimInfo::checkCutOffs( void ){
  
  if( boxIsInit ){
    
    //we need to check cutOffs against the box
    
    if( rCut > maxCutoff ){
      sprintf( painCave.errMsg,
               "cutoffRadius is too large for the current periodic box.\n"
               "\tCurrent Value of cutoffRadius = %G at time %G\n "
               "\tThis is larger than half of at least one of the\n"
               "\tperiodic box vectors.  Right now, the Box matrix is:\n"
               "\n"
               "\t[ %G %G %G ]\n"
               "\t[ %G %G %G ]\n"
               "\t[ %G %G %G ]\n",
               rCut, currentTime,
               Hmat[0][0], Hmat[0][1], Hmat[0][2],
               Hmat[1][0], Hmat[1][1], Hmat[1][2],
               Hmat[2][0], Hmat[2][1], Hmat[2][2]);
      painCave.severity = OOPSE_ERROR;
      painCave.isFatal = 1;
      simError();
    }    
  } else {
    // initialize this stuff before using it, OK?
    sprintf( painCave.errMsg,
             "Trying to check cutoffs without a box.\n"
             "\tOOPSE should have better programmers than that.\n" );
    painCave.severity = OOPSE_ERROR;
    painCave.isFatal = 1;
    simError();      
  }
  
}

void SimInfo::addProperty(GenericData* prop){

  map<string, GenericData*>::iterator result;
  result = properties.find(prop->getID());
  
  //we can't simply use  properties[prop->getID()] = prop,
  //it will cause memory leak if we already contain a propery which has the same name of prop
  
  if(result != properties.end()){
    
    delete (*result).second;
    (*result).second = prop;
      
  }
  else{

    properties[prop->getID()] = prop;

  }
    
}

GenericData* SimInfo::getProperty(const string& propName){
 
  map<string, GenericData*>::iterator result;
  
  //string lowerCaseName = ();
  
  result = properties.find(propName);
  
  if(result != properties.end()) 
    return (*result).second;  
  else   
    return NULL;  
}


void SimInfo::getFortranGroupArrays(SimInfo* info, 
                                    vector<int>& FglobalGroupMembership,
                                    vector<double>& mfact){
  
  Molecule* myMols;
  Atom** myAtoms;
  int numAtom;
  double mtot;
  int numMol;
  int numCutoffGroups;
  CutoffGroup* myCutoffGroup;
  vector<CutoffGroup*>::iterator iterCutoff;
  Atom* cutoffAtom;
  vector<Atom*>::iterator iterAtom;
  int atomIndex;
  double totalMass;
  
  mfact.clear();
  FglobalGroupMembership.clear();
  

  // Fix the silly fortran indexing problem
#ifdef IS_MPI
  numAtom = mpiSim->getNAtomsGlobal();
#else
  numAtom = n_atoms;
#endif
  for (int i = 0; i < numAtom; i++) 
    FglobalGroupMembership.push_back(globalGroupMembership[i] + 1);
  

  myMols = info->molecules;
  numMol = info->n_mol;
  for(int i  = 0; i < numMol; i++){
    numCutoffGroups = myMols[i].getNCutoffGroups();
    for(myCutoffGroup =myMols[i].beginCutoffGroup(iterCutoff); 
        myCutoffGroup != NULL; 
        myCutoffGroup =myMols[i].nextCutoffGroup(iterCutoff)){

      totalMass = myCutoffGroup->getMass();
      
      for(cutoffAtom = myCutoffGroup->beginAtom(iterAtom); 
          cutoffAtom != NULL; 
          cutoffAtom = myCutoffGroup->nextAtom(iterAtom)){
        mfact.push_back(cutoffAtom->getMass()/totalMass);
      }  
    }
  }

}
Revision:	124
Committed:	Wed Oct 20 20:46:20 2004 UTC (21 years ago) by chuckv
Original Path:	*trunk/src/brains/SimInfo.cpp*
File size:	13839 byte(s)
Log Message:	Fortran/C++ interface de-obfuscation project (It is a very long story)
#	Content
1	#include <stdlib.h>
2	#include <string.h>
3	#include <math.h>
4
5	#include <iostream>
6	using namespace std;
7
8	#include "brains/SimInfo.hpp"
9	#define __C
10	#include "brains/fSimulation.h"
11	#include "utils/simError.h"
12	#include "UseTheForce/DarkSide/simulation_interface.h"
13	#include "UseTheForce/notifyCutoffs_interface.h"
14
15	//#include "UseTheForce/fortranWrappers.hpp"
16
17	#include "math/MatVec3.h"
18
19	#ifdef IS_MPI
20	#include "brains/mpiSimulation.hpp"
21	#endif
22
23	inline double roundMe( double x ){
24	return ( x >= 0 ) ? floor( x + 0.5 ) : ceil( x - 0.5 );
25	}
26
27	inline double min( double a, double b ){
28	return (a < b ) ? a : b;
29	}
30
31	SimInfo* currentInfo;
32
33	SimInfo::SimInfo(){
34
35	n_constraints = 0;
36	nZconstraints = 0;
37	n_oriented = 0;
38	n_dipoles = 0;
39	ndf = 0;
40	ndfRaw = 0;
41	nZconstraints = 0;
42	the_integrator = NULL;
43	setTemp = 0;
44	thermalTime = 0.0;
45	currentTime = 0.0;
46	rCut = 0.0;
47	rSw = 0.0;
48
49	haveRcut = 0;
50	haveRsw = 0;
51	boxIsInit = 0;
52
53	resetTime = 1e99;
54
55	orthoRhombic = 0;
56	orthoTolerance = 1E-6;
57	useInitXSstate = true;
58
59	usePBC = 0;
60	useLJ = 0;
61	useSticky = 0;
62	useCharges = 0;
63	useDipoles = 0;
64	useReactionField = 0;
65	useGB = 0;
66	useEAM = 0;
67	useSolidThermInt = 0;
68	useLiquidThermInt = 0;
69
70	haveCutoffGroups = false;
71
72	excludes = Exclude::Instance();
73
74	myConfiguration = new SimState();
75
76	has_minimizer = false;
77	the_minimizer =NULL;
78
79	ngroup = 0;
80
81	}
82
83
84	SimInfo::~SimInfo(){
85
86	delete myConfiguration;
87
88	map<string, GenericData*>::iterator i;
89
90	for(i = properties.begin(); i != properties.end(); i++)
91	delete (*i).second;
92
93	}
94
95	void SimInfo::setBox(double newBox[3]) {
96
97	int i, j;
98	double tempMat[3][3];
99
100	for(i=0; i<3; i++)
101	for (j=0; j<3; j++) tempMat[i][j] = 0.0;;
102
103	tempMat[0][0] = newBox[0];
104	tempMat[1][1] = newBox[1];
105	tempMat[2][2] = newBox[2];
106
107	setBoxM( tempMat );
108
109	}
110
111	void SimInfo::setBoxM( double theBox[3][3] ){
112
113	int i, j;
114	double FortranHmat[9]; // to preserve compatibility with Fortran the
115	// ordering in the array is as follows:
116	// [ 0 3 6 ]
117	// [ 1 4 7 ]
118	// [ 2 5 8 ]
119	double FortranHmatInv[9]; // the inverted Hmat (for Fortran);
120
121	if( !boxIsInit ) boxIsInit = 1;
122
123	for(i=0; i < 3; i++)
124	for (j=0; j < 3; j++) Hmat[i][j] = theBox[i][j];
125
126	calcBoxL();
127	calcHmatInv();
128
129	for(i=0; i < 3; i++) {
130	for (j=0; j < 3; j++) {
131	FortranHmat[3*j + i] = Hmat[i][j];
132	FortranHmatInv[3*j + i] = HmatInv[i][j];
133	}
134	}
135
136	setFortranBox(FortranHmat, FortranHmatInv, &orthoRhombic);
137
138	}
139
140
141	void SimInfo::getBoxM (double theBox[3][3]) {
142
143	int i, j;
144	for(i=0; i<3; i++)
145	for (j=0; j<3; j++) theBox[i][j] = Hmat[i][j];
146	}
147
148
149	void SimInfo::scaleBox(double scale) {
150	double theBox[3][3];
151	int i, j;
152
153	// cerr << "Scaling box by " << scale << "\n";
154
155	for(i=0; i<3; i++)
156	for (j=0; j<3; j++) theBox[i][j] = Hmat[i][j]*scale;
157
158	setBoxM(theBox);
159
160	}
161
162	void SimInfo::calcHmatInv( void ) {
163
164	int oldOrtho;
165	int i,j;
166	double smallDiag;
167	double tol;
168	double sanity[3][3];
169
170	invertMat3( Hmat, HmatInv );
171
172	// check to see if Hmat is orthorhombic
173
174	oldOrtho = orthoRhombic;
175
176	smallDiag = fabs(Hmat[0][0]);
177	if(smallDiag > fabs(Hmat[1][1])) smallDiag = fabs(Hmat[1][1]);
178	if(smallDiag > fabs(Hmat[2][2])) smallDiag = fabs(Hmat[2][2]);
179	tol = smallDiag * orthoTolerance;
180
181	orthoRhombic = 1;
182
183	for (i = 0; i < 3; i++ ) {
184	for (j = 0 ; j < 3; j++) {
185	if (i != j) {
186	if (orthoRhombic) {
187	if ( fabs(Hmat[i][j]) >= tol) orthoRhombic = 0;
188	}
189	}
190	}
191	}
192
193	if( oldOrtho != orthoRhombic ){
194
195	if( orthoRhombic ) {
196	sprintf( painCave.errMsg,
197	"OOPSE is switching from the default Non-Orthorhombic\n"
198	"\tto the faster Orthorhombic periodic boundary computations.\n"
199	"\tThis is usually a good thing, but if you wan't the\n"
200	"\tNon-Orthorhombic computations, make the orthoBoxTolerance\n"
201	"\tvariable ( currently set to %G ) smaller.\n",
202	orthoTolerance);
203	painCave.severity = OOPSE_INFO;
204	simError();
205	}
206	else {
207	sprintf( painCave.errMsg,
208	"OOPSE is switching from the faster Orthorhombic to the more\n"
209	"\tflexible Non-Orthorhombic periodic boundary computations.\n"
210	"\tThis is usually because the box has deformed under\n"
211	"\tNPTf integration. If you wan't to live on the edge with\n"
212	"\tthe Orthorhombic computations, make the orthoBoxTolerance\n"
213	"\tvariable ( currently set to %G ) larger.\n",
214	orthoTolerance);
215	painCave.severity = OOPSE_WARNING;
216	simError();
217	}
218	}
219	}
220
221	void SimInfo::calcBoxL( void ){
222
223	double dx, dy, dz, dsq;
224
225	// boxVol = Determinant of Hmat
226
227	boxVol = matDet3( Hmat );
228
229	// boxLx
230
231	dx = Hmat[0][0]; dy = Hmat[1][0]; dz = Hmat[2][0];
232	dsq = dxdx + dydy + dz*dz;
233	boxL[0] = sqrt( dsq );
234	//maxCutoff = 0.5 * boxL[0];
235
236	// boxLy
237
238	dx = Hmat[0][1]; dy = Hmat[1][1]; dz = Hmat[2][1];
239	dsq = dxdx + dydy + dz*dz;
240	boxL[1] = sqrt( dsq );
241	//if( (0.5 * boxL[1]) < maxCutoff ) maxCutoff = 0.5 * boxL[1];
242
243
244	// boxLz
245
246	dx = Hmat[0][2]; dy = Hmat[1][2]; dz = Hmat[2][2];
247	dsq = dxdx + dydy + dz*dz;
248	boxL[2] = sqrt( dsq );
249	//if( (0.5 * boxL[2]) < maxCutoff ) maxCutoff = 0.5 * boxL[2];
250
251	//calculate the max cutoff
252	maxCutoff = calcMaxCutOff();
253
254	checkCutOffs();
255
256	}
257
258
259	double SimInfo::calcMaxCutOff(){
260
261	double ri[3], rj[3], rk[3];
262	double rij[3], rjk[3], rki[3];
263	double minDist;
264
265	ri[0] = Hmat[0][0];
266	ri[1] = Hmat[1][0];
267	ri[2] = Hmat[2][0];
268
269	rj[0] = Hmat[0][1];
270	rj[1] = Hmat[1][1];
271	rj[2] = Hmat[2][1];
272
273	rk[0] = Hmat[0][2];
274	rk[1] = Hmat[1][2];
275	rk[2] = Hmat[2][2];
276
277	crossProduct3(ri, rj, rij);
278	distXY = dotProduct3(rk,rij) / norm3(rij);
279
280	crossProduct3(rj,rk, rjk);
281	distYZ = dotProduct3(ri,rjk) / norm3(rjk);
282
283	crossProduct3(rk,ri, rki);
284	distZX = dotProduct3(rj,rki) / norm3(rki);
285
286	minDist = min(min(distXY, distYZ), distZX);
287	return minDist/2;
288
289	}
290
291	void SimInfo::wrapVector( double thePos[3] ){
292
293	int i;
294	double scaled[3];
295
296	if( !orthoRhombic ){
297	// calc the scaled coordinates.
298
299
300	matVecMul3(HmatInv, thePos, scaled);
301
302	for(i=0; i<3; i++)
303	scaled[i] -= roundMe(scaled[i]);
304
305	// calc the wrapped real coordinates from the wrapped scaled coordinates
306
307	matVecMul3(Hmat, scaled, thePos);
308
309	}
310	else{
311	// calc the scaled coordinates.
312
313	for(i=0; i<3; i++)
314	scaled[i] = thePos[i]*HmatInv[i][i];
315
316	// wrap the scaled coordinates
317
318	for(i=0; i<3; i++)
319	scaled[i] -= roundMe(scaled[i]);
320
321	// calc the wrapped real coordinates from the wrapped scaled coordinates
322
323	for(i=0; i<3; i++)
324	thePos[i] = scaled[i]*Hmat[i][i];
325	}
326
327	}
328
329
330	int SimInfo::getNDF(){
331	int ndf_local;
332
333	ndf_local = 0;
334
335	for(int i = 0; i < integrableObjects.size(); i++){
336	ndf_local += 3;
337	if (integrableObjects[i]->isDirectional()) {
338	if (integrableObjects[i]->isLinear())
339	ndf_local += 2;
340	else
341	ndf_local += 3;
342	}
343	}
344
345	// n_constraints is local, so subtract them on each processor:
346
347	ndf_local -= n_constraints;
348
349	#ifdef IS_MPI
350	MPI_Allreduce(&ndf_local,&ndf,1,MPI_INT,MPI_SUM, MPI_COMM_WORLD);
351	#else
352	ndf = ndf_local;
353	#endif
354
355	// nZconstraints is global, as are the 3 COM translations for the
356	// entire system:
357
358	ndf = ndf - 3 - nZconstraints;
359
360	return ndf;
361	}
362
363	int SimInfo::getNDFraw() {
364	int ndfRaw_local;
365
366	// Raw degrees of freedom that we have to set
367	ndfRaw_local = 0;
368
369	for(int i = 0; i < integrableObjects.size(); i++){
370	ndfRaw_local += 3;
371	if (integrableObjects[i]->isDirectional()) {
372	if (integrableObjects[i]->isLinear())
373	ndfRaw_local += 2;
374	else
375	ndfRaw_local += 3;
376	}
377	}
378
379	#ifdef IS_MPI
380	MPI_Allreduce(&ndfRaw_local,&ndfRaw,1,MPI_INT,MPI_SUM, MPI_COMM_WORLD);
381	#else
382	ndfRaw = ndfRaw_local;
383	#endif
384
385	return ndfRaw;
386	}
387
388	int SimInfo::getNDFtranslational() {
389	int ndfTrans_local;
390
391	ndfTrans_local = 3 * integrableObjects.size() - n_constraints;
392
393
394	#ifdef IS_MPI
395	MPI_Allreduce(&ndfTrans_local,&ndfTrans,1,MPI_INT,MPI_SUM, MPI_COMM_WORLD);
396	#else
397	ndfTrans = ndfTrans_local;
398	#endif
399
400	ndfTrans = ndfTrans - 3 - nZconstraints;
401
402	return ndfTrans;
403	}
404
405	int SimInfo::getTotIntegrableObjects() {
406	int nObjs_local;
407	int nObjs;
408
409	nObjs_local = integrableObjects.size();
410
411
412	#ifdef IS_MPI
413	MPI_Allreduce(&nObjs_local,&nObjs,1,MPI_INT,MPI_SUM, MPI_COMM_WORLD);
414	#else
415	nObjs = nObjs_local;
416	#endif
417
418
419	return nObjs;
420	}
421
422	void SimInfo::refreshSim(){
423
424	simtype fInfo;
425	int isError;
426	int n_global;
427	int* excl;
428
429	fInfo.dielect = 0.0;
430
431	if( useDipoles ){
432	if( useReactionField )fInfo.dielect = dielectric;
433	}
434
435	fInfo.SIM_uses_PBC = usePBC;
436	//fInfo.SIM_uses_LJ = 0;
437	fInfo.SIM_uses_LJ = useLJ;
438	fInfo.SIM_uses_sticky = useSticky;
439	//fInfo.SIM_uses_sticky = 0;
440	fInfo.SIM_uses_charges = useCharges;
441	fInfo.SIM_uses_dipoles = useDipoles;
442	//fInfo.SIM_uses_dipoles = 0;
443	fInfo.SIM_uses_RF = useReactionField;
444	//fInfo.SIM_uses_RF = 0;
445	fInfo.SIM_uses_GB = useGB;
446	fInfo.SIM_uses_EAM = useEAM;
447
448	n_exclude = excludes->getSize();
449	excl = excludes->getFortranArray();
450
451	#ifdef IS_MPI
452	n_global = mpiSim->getNAtomsGlobal();
453	#else
454	n_global = n_atoms;
455	#endif
456
457	isError = 0;
458
459	getFortranGroupArrays(this, FglobalGroupMembership, mfact);
460	//it may not be a good idea to pass the address of first element in vector
461	//since c++ standard does not require vector to be stored continuously in meomory
462	//Most of the compilers will organize the memory of vector continuously
463	setFortranSim( &fInfo, &n_global, &n_atoms, identArray, &n_exclude, excl,
464	&nGlobalExcludes, globalExcludes, molMembershipArray,
465	&mfact[0], &ngroup, &FglobalGroupMembership[0], &isError);
466
467	if( isError ){
468
469	sprintf( painCave.errMsg,
470	"There was an error setting the simulation information in fortran.\n" );
471	painCave.isFatal = 1;
472	painCave.severity = OOPSE_ERROR;
473	simError();
474	}
475
476	#ifdef IS_MPI
477	sprintf( checkPointMsg,
478	"succesfully sent the simulation information to fortran.\n");
479	MPIcheckPoint();
480	#endif // is_mpi
481
482	this->ndf = this->getNDF();
483	this->ndfRaw = this->getNDFraw();
484	this->ndfTrans = this->getNDFtranslational();
485	}
486
487	void SimInfo::setDefaultRcut( double theRcut ){
488
489	haveRcut = 1;
490	rCut = theRcut;
491	rList = rCut + 1.0;
492
493	notifyFortranCutoffs( &rCut, &rSw, &rList );
494	}
495
496	void SimInfo::setDefaultRcut( double theRcut, double theRsw ){
497
498	rSw = theRsw;
499	setDefaultRcut( theRcut );
500	}
501
502
503	void SimInfo::checkCutOffs( void ){
504
505	if( boxIsInit ){
506
507	//we need to check cutOffs against the box
508
509	if( rCut > maxCutoff ){
510	sprintf( painCave.errMsg,
511	"cutoffRadius is too large for the current periodic box.\n"
512	"\tCurrent Value of cutoffRadius = %G at time %G\n "
513	"\tThis is larger than half of at least one of the\n"
514	"\tperiodic box vectors. Right now, the Box matrix is:\n"
515	"\n"
516	"\t[ %G %G %G ]\n"
517	"\t[ %G %G %G ]\n"
518	"\t[ %G %G %G ]\n",
519	rCut, currentTime,
520	Hmat[0][0], Hmat[0][1], Hmat[0][2],
521	Hmat[1][0], Hmat[1][1], Hmat[1][2],
522	Hmat[2][0], Hmat[2][1], Hmat[2][2]);
523	painCave.severity = OOPSE_ERROR;
524	painCave.isFatal = 1;
525	simError();
526	}
527	} else {
528	// initialize this stuff before using it, OK?
529	sprintf( painCave.errMsg,
530	"Trying to check cutoffs without a box.\n"
531	"\tOOPSE should have better programmers than that.\n" );
532	painCave.severity = OOPSE_ERROR;
533	painCave.isFatal = 1;
534	simError();
535	}
536
537	}
538
539	void SimInfo::addProperty(GenericData* prop){
540
541	map<string, GenericData*>::iterator result;
542	result = properties.find(prop->getID());
543
544	//we can't simply use properties[prop->getID()] = prop,
545	//it will cause memory leak if we already contain a propery which has the same name of prop
546
547	if(result != properties.end()){
548
549	delete (*result).second;
550	(*result).second = prop;
551
552	}
553	else{
554
555	properties[prop->getID()] = prop;
556
557	}
558
559	}
560
561	GenericData* SimInfo::getProperty(const string& propName){
562
563	map<string, GenericData*>::iterator result;
564
565	//string lowerCaseName = ();
566
567	result = properties.find(propName);
568
569	if(result != properties.end())
570	return (*result).second;
571	else
572	return NULL;
573	}
574
575
576	void SimInfo::getFortranGroupArrays(SimInfo* info,
577	vector<int>& FglobalGroupMembership,
578	vector<double>& mfact){
579
580	Molecule* myMols;
581	Atom** myAtoms;
582	int numAtom;
583	double mtot;
584	int numMol;
585	int numCutoffGroups;
586	CutoffGroup* myCutoffGroup;
587	vector<CutoffGroup*>::iterator iterCutoff;
588	Atom* cutoffAtom;
589	vector<Atom*>::iterator iterAtom;
590	int atomIndex;
591	double totalMass;
592
593	mfact.clear();
594	FglobalGroupMembership.clear();
595
596
597	// Fix the silly fortran indexing problem
598	#ifdef IS_MPI
599	numAtom = mpiSim->getNAtomsGlobal();
600	#else
601	numAtom = n_atoms;
602	#endif
603	for (int i = 0; i < numAtom; i++)
604	FglobalGroupMembership.push_back(globalGroupMembership[i] + 1);
605
606
607	myMols = info->molecules;
608	numMol = info->n_mol;
609	for(int i = 0; i < numMol; i++){
610	numCutoffGroups = myMols[i].getNCutoffGroups();
611	for(myCutoffGroup =myMols[i].beginCutoffGroup(iterCutoff);
612	myCutoffGroup != NULL;
613	myCutoffGroup =myMols[i].nextCutoffGroup(iterCutoff)){
614
615	totalMass = myCutoffGroup->getMass();
616
617	for(cutoffAtom = myCutoffGroup->beginAtom(iterAtom);
618	cutoffAtom != NULL;
619	cutoffAtom = myCutoffGroup->nextAtom(iterAtom)){
620	mfact.push_back(cutoffAtom->getMass()/totalMass);
621	}
622	}
623	}
624
625	}