OOPSE/libmdtools/Integrator.cpp

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

#ifdef IS_MPI
#include "mpiSimulation.hpp"
#include <unistd.h>
#endif //is_mpi

#ifdef PROFILE
#include "mdProfile.hpp"
#endif // profile

#include "Integrator.hpp"
#include "simError.h"


template<typename T> Integrator<T>::Integrator(SimInfo* theInfo,
                                               ForceFields* the_ff){
  info = theInfo;
  myFF = the_ff;
  isFirst = 1;

  molecules = info->molecules;
  nMols = info->n_mol;

  // give a little love back to the SimInfo object

  if (info->the_integrator != NULL){
    delete info->the_integrator;
  }

  nAtoms = info->n_atoms;
  integrableObjects = info->integrableObjects;
 
  // check for constraints

  constrainedA = NULL;
  constrainedB = NULL;
  constrainedDsqr = NULL;
  moving = NULL;
  moved = NULL;
  oldPos = NULL;

  nConstrained = 0;

  checkConstraints();

}

template<typename T> Integrator<T>::~Integrator(){
  if (nConstrained){
    delete[] constrainedA;
    delete[] constrainedB;
    delete[] constrainedDsqr;
    delete[] moving;
    delete[] moved;
    delete[] oldPos;
  }
}

template<typename T> void Integrator<T>::checkConstraints(void){
  isConstrained = 0;

  Constraint* temp_con;
  Constraint* dummy_plug;
  temp_con = new Constraint[info->n_SRI];
  nConstrained = 0;
  int constrained = 0;

  SRI** theArray;
  for (int i = 0; i < nMols; i++){

          theArray = (SRI * *) molecules[i].getMyBonds();
    for (int j = 0; j < molecules[i].getNBonds(); j++){
      constrained = theArray[j]->is_constrained();

      if (constrained){
        dummy_plug = theArray[j]->get_constraint();
        temp_con[nConstrained].set_a(dummy_plug->get_a());
        temp_con[nConstrained].set_b(dummy_plug->get_b());
        temp_con[nConstrained].set_dsqr(dummy_plug->get_dsqr());

        nConstrained++;
        constrained = 0;
      }
    }

    theArray = (SRI * *) molecules[i].getMyBends();
    for (int j = 0; j < molecules[i].getNBends(); j++){
      constrained = theArray[j]->is_constrained();

      if (constrained){
        dummy_plug = theArray[j]->get_constraint();
        temp_con[nConstrained].set_a(dummy_plug->get_a());
        temp_con[nConstrained].set_b(dummy_plug->get_b());
        temp_con[nConstrained].set_dsqr(dummy_plug->get_dsqr());

        nConstrained++;
        constrained = 0;
      }
    }

    theArray = (SRI * *) molecules[i].getMyTorsions();
    for (int j = 0; j < molecules[i].getNTorsions(); j++){
      constrained = theArray[j]->is_constrained();

      if (constrained){
        dummy_plug = theArray[j]->get_constraint();
        temp_con[nConstrained].set_a(dummy_plug->get_a());
        temp_con[nConstrained].set_b(dummy_plug->get_b());
        temp_con[nConstrained].set_dsqr(dummy_plug->get_dsqr());

        nConstrained++;
        constrained = 0;
      }
    }
  }


  if (nConstrained > 0){
    isConstrained = 1;

    if (constrainedA != NULL)
      delete[] constrainedA;
    if (constrainedB != NULL)
      delete[] constrainedB;
    if (constrainedDsqr != NULL)
      delete[] constrainedDsqr;

    constrainedA = new int[nConstrained];
    constrainedB = new int[nConstrained];
    constrainedDsqr = new double[nConstrained];

    for (int i = 0; i < nConstrained; i++){
      constrainedA[i] = temp_con[i].get_a();
      constrainedB[i] = temp_con[i].get_b();
      constrainedDsqr[i] = temp_con[i].get_dsqr();
    }


    // save oldAtoms to check for lode balancing later on.

    oldAtoms = nAtoms;

    moving = new int[nAtoms];
    moved = new int[nAtoms];

    oldPos = new double[nAtoms * 3];
  }

  delete[] temp_con;
}


template<typename T> void Integrator<T>::integrate(void){

  double runTime = info->run_time;
  double sampleTime = info->sampleTime;
  double statusTime = info->statusTime;
  double thermalTime = info->thermalTime;
  double resetTime = info->resetTime;

  double difference;
  double currSample;
  double currThermal;
  double currStatus;
  double currReset;

  int calcPot, calcStress;

  tStats = new Thermo(info);
  statOut = new StatWriter(info);
  dumpOut = new DumpWriter(info);

  atoms = info->atoms;

  dt = info->dt;
  dt2 = 0.5 * dt;

  readyCheck();

  // remove center of mass drift velocity (in case we passed in a configuration
  // that was drifting
  tStats->removeCOMdrift();

  // initialize the retraints if necessary
  if (info->useSolidThermInt && !info->useLiquidThermInt) {
    myFF->initRestraints();
  }

  // initialize the forces before the first step

  calcForce(1, 1);
  
  if (nConstrained){
    preMove();
    constrainA();
    calcForce(1, 1);
    constrainB();
  }
  
  if (info->setTemp){
    thermalize();
  }

  calcPot     = 0;
  calcStress  = 0;
  currSample  = sampleTime + info->getTime();
  currThermal = thermalTime+ info->getTime();
  currStatus  = statusTime + info->getTime();
  currReset   = resetTime  + info->getTime();

  dumpOut->writeDump(info->getTime());
  statOut->writeStat(info->getTime());


#ifdef IS_MPI
  strcpy(checkPointMsg, "The integrator is ready to go.");
  MPIcheckPoint();
#endif // is_mpi

  while (info->getTime() < runTime && !stopIntegrator()){
    difference = info->getTime() + dt - currStatus;
    if (difference > 0 || fabs(difference) < 1e-4 ){
      calcPot = 1;
      calcStress = 1;
    }

#ifdef PROFILE
    startProfile( pro1 );
#endif
    
    integrateStep(calcPot, calcStress);

#ifdef PROFILE
    endProfile( pro1 );

    startProfile( pro2 );
#endif // profile

    info->incrTime(dt);

    if (info->setTemp){
      if (info->getTime() >= currThermal){
        thermalize();
        currThermal += thermalTime;
      }
    }

    if (info->getTime() >= currSample){
      dumpOut->writeDump(info->getTime());
      currSample += sampleTime;
    }

    if (info->getTime() >= currStatus){
      statOut->writeStat(info->getTime());
      if (info->useSolidThermInt || info->useLiquidThermInt)
        statOut->writeRaw(info->getTime());
      calcPot = 0;
      calcStress = 0;
      currStatus += statusTime;
    }

    if (info->resetIntegrator){
      if (info->getTime() >= currReset){
        this->resetIntegrator();
        currReset += resetTime;
      }
    }
    
#ifdef PROFILE
    endProfile( pro2 );
#endif //profile

#ifdef IS_MPI
    strcpy(checkPointMsg, "successfully took a time step.");
    MPIcheckPoint();
#endif // is_mpi
  }

  // dump out a file containing the omega values for the final configuration
  if (info->useSolidThermInt && !info->useLiquidThermInt)
    myFF->dumpzAngle();
  

  delete dumpOut;
  delete statOut;
}

template<typename T> void Integrator<T>::integrateStep(int calcPot,
                                                       int calcStress){
  // Position full step, and velocity half step

#ifdef PROFILE
  startProfile(pro3);
#endif //profile

  preMove();

#ifdef PROFILE
  endProfile(pro3);

  startProfile(pro4);
#endif // profile

  moveA();

#ifdef PROFILE
  endProfile(pro4);
  
  startProfile(pro5);
#endif//profile


#ifdef IS_MPI
  strcpy(checkPointMsg, "Succesful moveA\n");
  MPIcheckPoint();
#endif // is_mpi

  // calc forces
  calcForce(calcPot, calcStress);

#ifdef IS_MPI
  strcpy(checkPointMsg, "Succesful doForces\n");
  MPIcheckPoint();
#endif // is_mpi

#ifdef PROFILE
  endProfile( pro5 );

  startProfile( pro6 );
#endif //profile

  // finish the velocity  half step

  moveB();

#ifdef PROFILE
  endProfile(pro6);
#endif // profile

#ifdef IS_MPI
  strcpy(checkPointMsg, "Succesful moveB\n");
  MPIcheckPoint();
#endif // is_mpi
}


template<typename T> void Integrator<T>::moveA(void){
  size_t i, j;
  DirectionalAtom* dAtom;
  double Tb[3], ji[3];
  double vel[3], pos[3], frc[3];
  double mass;
  double omega;
 
  for (i = 0; i < integrableObjects.size() ; i++){
    integrableObjects[i]->getVel(vel);
    integrableObjects[i]->getPos(pos);
    integrableObjects[i]->getFrc(frc);
    
    mass = integrableObjects[i]->getMass();

    for (j = 0; j < 3; j++){
      // velocity half step
      vel[j] += (dt2 * frc[j] / mass) * eConvert;
      // position whole step
      pos[j] += dt * vel[j];
    }

    integrableObjects[i]->setVel(vel);
    integrableObjects[i]->setPos(pos);

    if (integrableObjects[i]->isDirectional()){

      // get and convert the torque to body frame

      integrableObjects[i]->getTrq(Tb);
      integrableObjects[i]->lab2Body(Tb);

      // get the angular momentum, and propagate a half step

      integrableObjects[i]->getJ(ji);

      for (j = 0; j < 3; j++)
        ji[j] += (dt2 * Tb[j]) * eConvert;

      this->rotationPropagation( integrableObjects[i], ji );

      integrableObjects[i]->setJ(ji);
    }
  }

  if (nConstrained){
    constrainA();
  }
}


template<typename T> void Integrator<T>::moveB(void){
  int i, j;
  double Tb[3], ji[3];
  double vel[3], frc[3];
  double mass;

  for (i = 0; i < integrableObjects.size(); i++){
    integrableObjects[i]->getVel(vel);
    integrableObjects[i]->getFrc(frc);

    mass = integrableObjects[i]->getMass();

    // velocity half step
    for (j = 0; j < 3; j++)
      vel[j] += (dt2 * frc[j] / mass) * eConvert;

    integrableObjects[i]->setVel(vel);

    if (integrableObjects[i]->isDirectional()){

      // get and convert the torque to body frame

      integrableObjects[i]->getTrq(Tb);
      integrableObjects[i]->lab2Body(Tb);

      // get the angular momentum, and propagate a half step

      integrableObjects[i]->getJ(ji);

      for (j = 0; j < 3; j++)
        ji[j] += (dt2 * Tb[j]) * eConvert;


      integrableObjects[i]->setJ(ji);
    }
  }

  if (nConstrained){
    constrainB();
  }
}

template<typename T> void Integrator<T>::preMove(void){
  int i, j;
  double pos[3];

  if (nConstrained){
    for (i = 0; i < nAtoms; i++){
      atoms[i]->getPos(pos);

      for (j = 0; j < 3; j++){
        oldPos[3 * i + j] = pos[j];
      }
    }
  }
}

template<typename T> void Integrator<T>::constrainA(){
  int i, j;
  int done;
  double posA[3], posB[3];
  double velA[3], velB[3];
  double pab[3];
  double rab[3];
  int a, b, ax, ay, az, bx, by, bz;
  double rma, rmb;
  double dx, dy, dz;
  double rpab;
  double rabsq, pabsq, rpabsq;
  double diffsq;
  double gab;
  int iteration;

  for (i = 0; i < nAtoms; i++){
    moving[i] = 0;
    moved[i] = 1;
  }

  iteration = 0;
  done = 0;
  while (!done && (iteration < maxIteration)){
    done = 1;
    for (i = 0; i < nConstrained; i++){
      a = constrainedA[i];
      b = constrainedB[i];

      ax = (a * 3) + 0;
      ay = (a * 3) + 1;
      az = (a * 3) + 2;

      bx = (b * 3) + 0;
      by = (b * 3) + 1;
      bz = (b * 3) + 2;

      if (moved[a] || moved[b]){
        atoms[a]->getPos(posA);
        atoms[b]->getPos(posB);

        for (j = 0; j < 3; j++)
          pab[j] = posA[j] - posB[j];

        //periodic boundary condition

        info->wrapVector(pab);

        pabsq = pab[0] * pab[0] + pab[1] * pab[1] + pab[2] * pab[2];

        rabsq = constrainedDsqr[i];
        diffsq = rabsq - pabsq;

        // the original rattle code from alan tidesley
        if (fabs(diffsq) > (tol * rabsq * 2)){
          rab[0] = oldPos[ax] - oldPos[bx];
          rab[1] = oldPos[ay] - oldPos[by];
          rab[2] = oldPos[az] - oldPos[bz];

          info->wrapVector(rab);

          rpab = rab[0] * pab[0] + rab[1] * pab[1] + rab[2] * pab[2];

          rpabsq = rpab * rpab;


          if (rpabsq < (rabsq * -diffsq)){
#ifdef IS_MPI
            a = atoms[a]->getGlobalIndex();
            b = atoms[b]->getGlobalIndex();
#endif //is_mpi
            sprintf(painCave.errMsg,
                    "Constraint failure in constrainA at atom %d and %d.\n", a,
                    b);
            painCave.isFatal = 1;
            simError();
          }

          rma = 1.0 / atoms[a]->getMass();
          rmb = 1.0 / atoms[b]->getMass();

          gab = diffsq / (2.0 * (rma + rmb) * rpab);

          dx = rab[0] * gab;
          dy = rab[1] * gab;
          dz = rab[2] * gab;

          posA[0] += rma * dx;
          posA[1] += rma * dy;
          posA[2] += rma * dz;

          atoms[a]->setPos(posA);

          posB[0] -= rmb * dx;
          posB[1] -= rmb * dy;
          posB[2] -= rmb * dz;

          atoms[b]->setPos(posB);

          dx = dx / dt;
          dy = dy / dt;
          dz = dz / dt;

          atoms[a]->getVel(velA);

          velA[0] += rma * dx;
          velA[1] += rma * dy;
          velA[2] += rma * dz;

          atoms[a]->setVel(velA);

          atoms[b]->getVel(velB);

          velB[0] -= rmb * dx;
          velB[1] -= rmb * dy;
          velB[2] -= rmb * dz;

          atoms[b]->setVel(velB);

          moving[a] = 1;
          moving[b] = 1;
          done = 0;
        }
      }
    }

    for (i = 0; i < nAtoms; i++){
      moved[i] = moving[i];
      moving[i] = 0;
    }

    iteration++;
  }

  if (!done){
    sprintf(painCave.errMsg,
            "Constraint failure in constrainA, too many iterations: %d\n",
            iteration);
    painCave.isFatal = 1;
    simError();
  }

}

template<typename T> void Integrator<T>::constrainB(void){
  int i, j;
  int done;
  double posA[3], posB[3];
  double velA[3], velB[3];
  double vxab, vyab, vzab;
  double rab[3];
  int a, b, ax, ay, az, bx, by, bz;
  double rma, rmb;
  double dx, dy, dz;
  double rvab;
  double gab;
  int iteration;

  for (i = 0; i < nAtoms; i++){
    moving[i] = 0;
    moved[i] = 1;
  }

  done = 0;
  iteration = 0;
  while (!done && (iteration < maxIteration)){
    done = 1;

    for (i = 0; i < nConstrained; i++){
      a = constrainedA[i];
      b = constrainedB[i];

      ax = (a * 3) + 0;
      ay = (a * 3) + 1;
      az = (a * 3) + 2;

      bx = (b * 3) + 0;
      by = (b * 3) + 1;
      bz = (b * 3) + 2;

      if (moved[a] || moved[b]){
        atoms[a]->getVel(velA);
        atoms[b]->getVel(velB);

        vxab = velA[0] - velB[0];
        vyab = velA[1] - velB[1];
        vzab = velA[2] - velB[2];

        atoms[a]->getPos(posA);
        atoms[b]->getPos(posB);

        for (j = 0; j < 3; j++)
          rab[j] = posA[j] - posB[j];

        info->wrapVector(rab);

        rma = 1.0 / atoms[a]->getMass();
        rmb = 1.0 / atoms[b]->getMass();

        rvab = rab[0] * vxab + rab[1] * vyab + rab[2] * vzab;

        gab = -rvab / ((rma + rmb) * constrainedDsqr[i]);

        if (fabs(gab) > tol){
          dx = rab[0] * gab;
          dy = rab[1] * gab;
          dz = rab[2] * gab;

          velA[0] += rma * dx;
          velA[1] += rma * dy;
          velA[2] += rma * dz;

          atoms[a]->setVel(velA);

          velB[0] -= rmb * dx;
          velB[1] -= rmb * dy;
          velB[2] -= rmb * dz;

          atoms[b]->setVel(velB);

          moving[a] = 1;
          moving[b] = 1;
          done = 0;
        }
      }
    }

    for (i = 0; i < nAtoms; i++){
      moved[i] = moving[i];
      moving[i] = 0;
    }

    iteration++;
  }

  if (!done){
    sprintf(painCave.errMsg,
            "Constraint failure in constrainB, too many iterations: %d\n",
            iteration);
    painCave.isFatal = 1;
    simError();
  }
}

template<typename T> void Integrator<T>::rotationPropagation
( StuntDouble* sd, double ji[3] ){

  double angle;
  double A[3][3], I[3][3];
  int i, j, k;

  // use the angular velocities to propagate the rotation matrix a
  // full time step

  sd->getA(A);
  sd->getI(I);

  if (sd->isLinear()) {
    i = sd->linearAxis();
    j = (i+1)%3;
    k = (i+2)%3;
    
    angle = dt2 * ji[j] / I[j][j];
    this->rotate( k, i, angle, ji, A );

    angle = dt * ji[k] / I[k][k];
    this->rotate( i, j, angle, ji, A);

    angle = dt2 * ji[j] / I[j][j];
    this->rotate( k, i, angle, ji, A );

  } else {
    // rotate about the x-axis
    angle = dt2 * ji[0] / I[0][0];
    this->rotate( 1, 2, angle, ji, A );
    
    // rotate about the y-axis
    angle = dt2 * ji[1] / I[1][1];
    this->rotate( 2, 0, angle, ji, A );
    
    // rotate about the z-axis
    angle = dt * ji[2] / I[2][2];
    sd->addZangle(angle);
    this->rotate( 0, 1, angle, ji, A);
    
    // rotate about the y-axis
    angle = dt2 * ji[1] / I[1][1];
    this->rotate( 2, 0, angle, ji, A );
    
    // rotate about the x-axis
    angle = dt2 * ji[0] / I[0][0];
    this->rotate( 1, 2, angle, ji, A );
    
  }
  sd->setA( A  );
}

template<typename T> void Integrator<T>::rotate(int axes1, int axes2,
                                                double angle, double ji[3],
                                                double A[3][3]){
  int i, j, k;
  double sinAngle;
  double cosAngle;
  double angleSqr;
  double angleSqrOver4;
  double top, bottom;
  double rot[3][3];
  double tempA[3][3];
  double tempJ[3];

  // initialize the tempA

  for (i = 0; i < 3; i++){
    for (j = 0; j < 3; j++){
      tempA[j][i] = A[i][j];
    }
  }

  // initialize the tempJ

  for (i = 0; i < 3; i++)
    tempJ[i] = ji[i];

  // initalize rot as a unit matrix

  rot[0][0] = 1.0;
  rot[0][1] = 0.0;
  rot[0][2] = 0.0;

  rot[1][0] = 0.0;
  rot[1][1] = 1.0;
  rot[1][2] = 0.0;

  rot[2][0] = 0.0;
  rot[2][1] = 0.0;
  rot[2][2] = 1.0;

  // use a small angle aproximation for sin and cosine

  angleSqr = angle * angle;
  angleSqrOver4 = angleSqr / 4.0;
  top = 1.0 - angleSqrOver4;
  bottom = 1.0 + angleSqrOver4;

  cosAngle = top / bottom;
  sinAngle = angle / bottom;

  rot[axes1][axes1] = cosAngle;
  rot[axes2][axes2] = cosAngle;

  rot[axes1][axes2] = sinAngle;
  rot[axes2][axes1] = -sinAngle;

  // rotate the momentum acoording to: ji[] = rot[][] * ji[]

  for (i = 0; i < 3; i++){
    ji[i] = 0.0;
    for (k = 0; k < 3; k++){
      ji[i] += rot[i][k] * tempJ[k];
    }
  }

  // rotate the Rotation matrix acording to:
  //            A[][] = A[][] * transpose(rot[][])


  // NOte for as yet unknown reason, we are performing the
  // calculation as:
  //                transpose(A[][]) = transpose(A[][]) * transpose(rot[][])

  for (i = 0; i < 3; i++){
    for (j = 0; j < 3; j++){
      A[j][i] = 0.0;
      for (k = 0; k < 3; k++){
        A[j][i] += tempA[i][k] * rot[j][k];
      }
    }
  }
}

template<typename T> void Integrator<T>::calcForce(int calcPot, int calcStress){
  myFF->doForces(calcPot, calcStress);
}

template<typename T> void Integrator<T>::thermalize(){
  tStats->velocitize();
}

template<typename T> double Integrator<T>::getConservedQuantity(void){
  return tStats->getTotalE();
}
template<typename T> string Integrator<T>::getAdditionalParameters(void){
  //By default, return a null string
  //The reason we use string instead of char* is that if we use char*, we will
  //return a pointer point to local variable which might cause problem
  return string();
}
Revision:	1212
Committed:	Tue Jun 1 17:15:43 2004 UTC (21 years, 5 months ago) by chrisfen
File size:	18634 byte(s)
Log Message:	Implemented a separate solid and liquid thermodynamic integration routines
#	Content
1	#include <iostream>
2	#include <stdlib.h>
3	#include <math.h>
4
5	#ifdef IS_MPI
6	#include "mpiSimulation.hpp"
7	#include <unistd.h>
8	#endif //is_mpi
9
10	#ifdef PROFILE
11	#include "mdProfile.hpp"
12	#endif // profile
13
14	#include "Integrator.hpp"
15	#include "simError.h"
16
17
18	template<typename T> Integrator<T>::Integrator(SimInfo* theInfo,
19	ForceFields* the_ff){
20	info = theInfo;
21	myFF = the_ff;
22	isFirst = 1;
23
24	molecules = info->molecules;
25	nMols = info->n_mol;
26
27	// give a little love back to the SimInfo object
28
29	if (info->the_integrator != NULL){
30	delete info->the_integrator;
31	}
32
33	nAtoms = info->n_atoms;
34	integrableObjects = info->integrableObjects;
35
36	// check for constraints
37
38	constrainedA = NULL;
39	constrainedB = NULL;
40	constrainedDsqr = NULL;
41	moving = NULL;
42	moved = NULL;
43	oldPos = NULL;
44
45	nConstrained = 0;
46
47	checkConstraints();
48
49	}
50
51	template<typename T> Integrator<T>::~Integrator(){
52	if (nConstrained){
53	delete[] constrainedA;
54	delete[] constrainedB;
55	delete[] constrainedDsqr;
56	delete[] moving;
57	delete[] moved;
58	delete[] oldPos;
59	}
60	}
61
62	template<typename T> void Integrator<T>::checkConstraints(void){
63	isConstrained = 0;
64
65	Constraint* temp_con;
66	Constraint* dummy_plug;
67	temp_con = new Constraint[info->n_SRI];
68	nConstrained = 0;
69	int constrained = 0;
70
71	SRI** theArray;
72	for (int i = 0; i < nMols; i++){
73
74	theArray = (SRI * *) molecules[i].getMyBonds();
75	for (int j = 0; j < molecules[i].getNBonds(); j++){
76	constrained = theArray[j]->is_constrained();
77
78	if (constrained){
79	dummy_plug = theArray[j]->get_constraint();
80	temp_con[nConstrained].set_a(dummy_plug->get_a());
81	temp_con[nConstrained].set_b(dummy_plug->get_b());
82	temp_con[nConstrained].set_dsqr(dummy_plug->get_dsqr());
83
84	nConstrained++;
85	constrained = 0;
86	}
87	}
88
89	theArray = (SRI * *) molecules[i].getMyBends();
90	for (int j = 0; j < molecules[i].getNBends(); j++){
91	constrained = theArray[j]->is_constrained();
92
93	if (constrained){
94	dummy_plug = theArray[j]->get_constraint();
95	temp_con[nConstrained].set_a(dummy_plug->get_a());
96	temp_con[nConstrained].set_b(dummy_plug->get_b());
97	temp_con[nConstrained].set_dsqr(dummy_plug->get_dsqr());
98
99	nConstrained++;
100	constrained = 0;
101	}
102	}
103
104	theArray = (SRI * *) molecules[i].getMyTorsions();
105	for (int j = 0; j < molecules[i].getNTorsions(); j++){
106	constrained = theArray[j]->is_constrained();
107
108	if (constrained){
109	dummy_plug = theArray[j]->get_constraint();
110	temp_con[nConstrained].set_a(dummy_plug->get_a());
111	temp_con[nConstrained].set_b(dummy_plug->get_b());
112	temp_con[nConstrained].set_dsqr(dummy_plug->get_dsqr());
113
114	nConstrained++;
115	constrained = 0;
116	}
117	}
118	}
119
120
121	if (nConstrained > 0){
122	isConstrained = 1;
123
124	if (constrainedA != NULL)
125	delete[] constrainedA;
126	if (constrainedB != NULL)
127	delete[] constrainedB;
128	if (constrainedDsqr != NULL)
129	delete[] constrainedDsqr;
130
131	constrainedA = new int[nConstrained];
132	constrainedB = new int[nConstrained];
133	constrainedDsqr = new double[nConstrained];
134
135	for (int i = 0; i < nConstrained; i++){
136	constrainedA[i] = temp_con[i].get_a();
137	constrainedB[i] = temp_con[i].get_b();
138	constrainedDsqr[i] = temp_con[i].get_dsqr();
139	}
140
141
142	// save oldAtoms to check for lode balancing later on.
143
144	oldAtoms = nAtoms;
145
146	moving = new int[nAtoms];
147	moved = new int[nAtoms];
148
149	oldPos = new double[nAtoms * 3];
150	}
151
152	delete[] temp_con;
153	}
154
155
156	template<typename T> void Integrator<T>::integrate(void){
157
158	double runTime = info->run_time;
159	double sampleTime = info->sampleTime;
160	double statusTime = info->statusTime;
161	double thermalTime = info->thermalTime;
162	double resetTime = info->resetTime;
163
164	double difference;
165	double currSample;
166	double currThermal;
167	double currStatus;
168	double currReset;
169
170	int calcPot, calcStress;
171
172	tStats = new Thermo(info);
173	statOut = new StatWriter(info);
174	dumpOut = new DumpWriter(info);
175
176	atoms = info->atoms;
177
178	dt = info->dt;
179	dt2 = 0.5 * dt;
180
181	readyCheck();
182
183	// remove center of mass drift velocity (in case we passed in a configuration
184	// that was drifting
185	tStats->removeCOMdrift();
186
187	// initialize the retraints if necessary
188	if (info->useSolidThermInt && !info->useLiquidThermInt) {
189	myFF->initRestraints();
190	}
191
192	// initialize the forces before the first step
193
194	calcForce(1, 1);
195
196	if (nConstrained){
197	preMove();
198	constrainA();
199	calcForce(1, 1);
200	constrainB();
201	}
202
203	if (info->setTemp){
204	thermalize();
205	}
206
207	calcPot = 0;
208	calcStress = 0;
209	currSample = sampleTime + info->getTime();
210	currThermal = thermalTime+ info->getTime();
211	currStatus = statusTime + info->getTime();
212	currReset = resetTime + info->getTime();
213
214	dumpOut->writeDump(info->getTime());
215	statOut->writeStat(info->getTime());
216
217
218	#ifdef IS_MPI
219	strcpy(checkPointMsg, "The integrator is ready to go.");
220	MPIcheckPoint();
221	#endif // is_mpi
222
223	while (info->getTime() < runTime && !stopIntegrator()){
224	difference = info->getTime() + dt - currStatus;
225	if (difference > 0 \|\| fabs(difference) < 1e-4 ){
226	calcPot = 1;
227	calcStress = 1;
228	}
229
230	#ifdef PROFILE
231	startProfile( pro1 );
232	#endif
233
234	integrateStep(calcPot, calcStress);
235
236	#ifdef PROFILE
237	endProfile( pro1 );
238
239	startProfile( pro2 );
240	#endif // profile
241
242	info->incrTime(dt);
243
244	if (info->setTemp){
245	if (info->getTime() >= currThermal){
246	thermalize();
247	currThermal += thermalTime;
248	}
249	}
250
251	if (info->getTime() >= currSample){
252	dumpOut->writeDump(info->getTime());
253	currSample += sampleTime;
254	}
255
256	if (info->getTime() >= currStatus){
257	statOut->writeStat(info->getTime());
258	if (info->useSolidThermInt \|\| info->useLiquidThermInt)
259	statOut->writeRaw(info->getTime());
260	calcPot = 0;
261	calcStress = 0;
262	currStatus += statusTime;
263	}
264
265	if (info->resetIntegrator){
266	if (info->getTime() >= currReset){
267	this->resetIntegrator();
268	currReset += resetTime;
269	}
270	}
271
272	#ifdef PROFILE
273	endProfile( pro2 );
274	#endif //profile
275
276	#ifdef IS_MPI
277	strcpy(checkPointMsg, "successfully took a time step.");
278	MPIcheckPoint();
279	#endif // is_mpi
280	}
281
282	// dump out a file containing the omega values for the final configuration
283	if (info->useSolidThermInt && !info->useLiquidThermInt)
284	myFF->dumpzAngle();
285
286
287	delete dumpOut;
288	delete statOut;
289	}
290
291	template<typename T> void Integrator<T>::integrateStep(int calcPot,
292	int calcStress){
293	// Position full step, and velocity half step
294
295	#ifdef PROFILE
296	startProfile(pro3);
297	#endif //profile
298
299	preMove();
300
301	#ifdef PROFILE
302	endProfile(pro3);
303
304	startProfile(pro4);
305	#endif // profile
306
307	moveA();
308
309	#ifdef PROFILE
310	endProfile(pro4);
311
312	startProfile(pro5);
313	#endif//profile
314
315
316	#ifdef IS_MPI
317	strcpy(checkPointMsg, "Succesful moveA\n");
318	MPIcheckPoint();
319	#endif // is_mpi
320
321	// calc forces
322	calcForce(calcPot, calcStress);
323
324	#ifdef IS_MPI
325	strcpy(checkPointMsg, "Succesful doForces\n");
326	MPIcheckPoint();
327	#endif // is_mpi
328
329	#ifdef PROFILE
330	endProfile( pro5 );
331
332	startProfile( pro6 );
333	#endif //profile
334
335	// finish the velocity half step
336
337	moveB();
338
339	#ifdef PROFILE
340	endProfile(pro6);
341	#endif // profile
342
343	#ifdef IS_MPI
344	strcpy(checkPointMsg, "Succesful moveB\n");
345	MPIcheckPoint();
346	#endif // is_mpi
347	}
348
349
350	template<typename T> void Integrator<T>::moveA(void){
351	size_t i, j;
352	DirectionalAtom* dAtom;
353	double Tb[3], ji[3];
354	double vel[3], pos[3], frc[3];
355	double mass;
356	double omega;
357
358	for (i = 0; i < integrableObjects.size() ; i++){
359	integrableObjects[i]->getVel(vel);
360	integrableObjects[i]->getPos(pos);
361	integrableObjects[i]->getFrc(frc);
362
363	mass = integrableObjects[i]->getMass();
364
365	for (j = 0; j < 3; j++){
366	// velocity half step
367	vel[j] += (dt2 * frc[j] / mass) * eConvert;
368	// position whole step
369	pos[j] += dt * vel[j];
370	}
371
372	integrableObjects[i]->setVel(vel);
373	integrableObjects[i]->setPos(pos);
374
375	if (integrableObjects[i]->isDirectional()){
376
377	// get and convert the torque to body frame
378
379	integrableObjects[i]->getTrq(Tb);
380	integrableObjects[i]->lab2Body(Tb);
381
382	// get the angular momentum, and propagate a half step
383
384	integrableObjects[i]->getJ(ji);
385
386	for (j = 0; j < 3; j++)
387	ji[j] += (dt2 * Tb[j]) * eConvert;
388
389	this->rotationPropagation( integrableObjects[i], ji );
390
391	integrableObjects[i]->setJ(ji);
392	}
393	}
394
395	if (nConstrained){
396	constrainA();
397	}
398	}
399
400
401	template<typename T> void Integrator<T>::moveB(void){
402	int i, j;
403	double Tb[3], ji[3];
404	double vel[3], frc[3];
405	double mass;
406
407	for (i = 0; i < integrableObjects.size(); i++){
408	integrableObjects[i]->getVel(vel);
409	integrableObjects[i]->getFrc(frc);
410
411	mass = integrableObjects[i]->getMass();
412
413	// velocity half step
414	for (j = 0; j < 3; j++)
415	vel[j] += (dt2 * frc[j] / mass) * eConvert;
416
417	integrableObjects[i]->setVel(vel);
418
419	if (integrableObjects[i]->isDirectional()){
420
421	// get and convert the torque to body frame
422
423	integrableObjects[i]->getTrq(Tb);
424	integrableObjects[i]->lab2Body(Tb);
425
426	// get the angular momentum, and propagate a half step
427
428	integrableObjects[i]->getJ(ji);
429
430	for (j = 0; j < 3; j++)
431	ji[j] += (dt2 * Tb[j]) * eConvert;
432
433
434	integrableObjects[i]->setJ(ji);
435	}
436	}
437
438	if (nConstrained){
439	constrainB();
440	}
441	}
442
443	template<typename T> void Integrator<T>::preMove(void){
444	int i, j;
445	double pos[3];
446
447	if (nConstrained){
448	for (i = 0; i < nAtoms; i++){
449	atoms[i]->getPos(pos);
450
451	for (j = 0; j < 3; j++){
452	oldPos[3 * i + j] = pos[j];
453	}
454	}
455	}
456	}
457
458	template<typename T> void Integrator<T>::constrainA(){
459	int i, j;
460	int done;
461	double posA[3], posB[3];
462	double velA[3], velB[3];
463	double pab[3];
464	double rab[3];
465	int a, b, ax, ay, az, bx, by, bz;
466	double rma, rmb;
467	double dx, dy, dz;
468	double rpab;
469	double rabsq, pabsq, rpabsq;
470	double diffsq;
471	double gab;
472	int iteration;
473
474	for (i = 0; i < nAtoms; i++){
475	moving[i] = 0;
476	moved[i] = 1;
477	}
478
479	iteration = 0;
480	done = 0;
481	while (!done && (iteration < maxIteration)){
482	done = 1;
483	for (i = 0; i < nConstrained; i++){
484	a = constrainedA[i];
485	b = constrainedB[i];
486
487	ax = (a * 3) + 0;
488	ay = (a * 3) + 1;
489	az = (a * 3) + 2;
490
491	bx = (b * 3) + 0;
492	by = (b * 3) + 1;
493	bz = (b * 3) + 2;
494
495	if (moved[a] \|\| moved[b]){
496	atoms[a]->getPos(posA);
497	atoms[b]->getPos(posB);
498
499	for (j = 0; j < 3; j++)
500	pab[j] = posA[j] - posB[j];
501
502	//periodic boundary condition
503
504	info->wrapVector(pab);
505
506	pabsq = pab[0] * pab[0] + pab[1] * pab[1] + pab[2] * pab[2];
507
508	rabsq = constrainedDsqr[i];
509	diffsq = rabsq - pabsq;
510
511	// the original rattle code from alan tidesley
512	if (fabs(diffsq) > (tol * rabsq * 2)){
513	rab[0] = oldPos[ax] - oldPos[bx];
514	rab[1] = oldPos[ay] - oldPos[by];
515	rab[2] = oldPos[az] - oldPos[bz];
516
517	info->wrapVector(rab);
518
519	rpab = rab[0] * pab[0] + rab[1] * pab[1] + rab[2] * pab[2];
520
521	rpabsq = rpab * rpab;
522
523
524	if (rpabsq < (rabsq * -diffsq)){
525	#ifdef IS_MPI
526	a = atoms[a]->getGlobalIndex();
527	b = atoms[b]->getGlobalIndex();
528	#endif //is_mpi
529	sprintf(painCave.errMsg,
530	"Constraint failure in constrainA at atom %d and %d.\n", a,
531	b);
532	painCave.isFatal = 1;
533	simError();
534	}
535
536	rma = 1.0 / atoms[a]->getMass();
537	rmb = 1.0 / atoms[b]->getMass();
538
539	gab = diffsq / (2.0 * (rma + rmb) * rpab);
540
541	dx = rab[0] * gab;
542	dy = rab[1] * gab;
543	dz = rab[2] * gab;
544
545	posA[0] += rma * dx;
546	posA[1] += rma * dy;
547	posA[2] += rma * dz;
548
549	atoms[a]->setPos(posA);
550
551	posB[0] -= rmb * dx;
552	posB[1] -= rmb * dy;
553	posB[2] -= rmb * dz;
554
555	atoms[b]->setPos(posB);
556
557	dx = dx / dt;
558	dy = dy / dt;
559	dz = dz / dt;
560
561	atoms[a]->getVel(velA);
562
563	velA[0] += rma * dx;
564	velA[1] += rma * dy;
565	velA[2] += rma * dz;
566
567	atoms[a]->setVel(velA);
568
569	atoms[b]->getVel(velB);
570
571	velB[0] -= rmb * dx;
572	velB[1] -= rmb * dy;
573	velB[2] -= rmb * dz;
574
575	atoms[b]->setVel(velB);
576
577	moving[a] = 1;
578	moving[b] = 1;
579	done = 0;
580	}
581	}
582	}
583
584	for (i = 0; i < nAtoms; i++){
585	moved[i] = moving[i];
586	moving[i] = 0;
587	}
588
589	iteration++;
590	}
591
592	if (!done){
593	sprintf(painCave.errMsg,
594	"Constraint failure in constrainA, too many iterations: %d\n",
595	iteration);
596	painCave.isFatal = 1;
597	simError();
598	}
599
600	}
601
602	template<typename T> void Integrator<T>::constrainB(void){
603	int i, j;
604	int done;
605	double posA[3], posB[3];
606	double velA[3], velB[3];
607	double vxab, vyab, vzab;
608	double rab[3];
609	int a, b, ax, ay, az, bx, by, bz;
610	double rma, rmb;
611	double dx, dy, dz;
612	double rvab;
613	double gab;
614	int iteration;
615
616	for (i = 0; i < nAtoms; i++){
617	moving[i] = 0;
618	moved[i] = 1;
619	}
620
621	done = 0;
622	iteration = 0;
623	while (!done && (iteration < maxIteration)){
624	done = 1;
625
626	for (i = 0; i < nConstrained; i++){
627	a = constrainedA[i];
628	b = constrainedB[i];
629
630	ax = (a * 3) + 0;
631	ay = (a * 3) + 1;
632	az = (a * 3) + 2;
633
634	bx = (b * 3) + 0;
635	by = (b * 3) + 1;
636	bz = (b * 3) + 2;
637
638	if (moved[a] \|\| moved[b]){
639	atoms[a]->getVel(velA);
640	atoms[b]->getVel(velB);
641
642	vxab = velA[0] - velB[0];
643	vyab = velA[1] - velB[1];
644	vzab = velA[2] - velB[2];
645
646	atoms[a]->getPos(posA);
647	atoms[b]->getPos(posB);
648
649	for (j = 0; j < 3; j++)
650	rab[j] = posA[j] - posB[j];
651
652	info->wrapVector(rab);
653
654	rma = 1.0 / atoms[a]->getMass();
655	rmb = 1.0 / atoms[b]->getMass();
656
657	rvab = rab[0] * vxab + rab[1] * vyab + rab[2] * vzab;
658
659	gab = -rvab / ((rma + rmb) * constrainedDsqr[i]);
660
661	if (fabs(gab) > tol){
662	dx = rab[0] * gab;
663	dy = rab[1] * gab;
664	dz = rab[2] * gab;
665
666	velA[0] += rma * dx;
667	velA[1] += rma * dy;
668	velA[2] += rma * dz;
669
670	atoms[a]->setVel(velA);
671
672	velB[0] -= rmb * dx;
673	velB[1] -= rmb * dy;
674	velB[2] -= rmb * dz;
675
676	atoms[b]->setVel(velB);
677
678	moving[a] = 1;
679	moving[b] = 1;
680	done = 0;
681	}
682	}
683	}
684
685	for (i = 0; i < nAtoms; i++){
686	moved[i] = moving[i];
687	moving[i] = 0;
688	}
689
690	iteration++;
691	}
692
693	if (!done){
694	sprintf(painCave.errMsg,
695	"Constraint failure in constrainB, too many iterations: %d\n",
696	iteration);
697	painCave.isFatal = 1;
698	simError();
699	}
700	}
701
702	template<typename T> void Integrator<T>::rotationPropagation
703	( StuntDouble* sd, double ji[3] ){
704
705	double angle;
706	double A[3][3], I[3][3];
707	int i, j, k;
708
709	// use the angular velocities to propagate the rotation matrix a
710	// full time step
711
712	sd->getA(A);
713	sd->getI(I);
714
715	if (sd->isLinear()) {
716	i = sd->linearAxis();
717	j = (i+1)%3;
718	k = (i+2)%3;
719
720	angle = dt2 * ji[j] / I[j][j];
721	this->rotate( k, i, angle, ji, A );
722
723	angle = dt * ji[k] / I[k][k];
724	this->rotate( i, j, angle, ji, A);
725
726	angle = dt2 * ji[j] / I[j][j];
727	this->rotate( k, i, angle, ji, A );
728
729	} else {
730	// rotate about the x-axis
731	angle = dt2 * ji[0] / I[0][0];
732	this->rotate( 1, 2, angle, ji, A );
733
734	// rotate about the y-axis
735	angle = dt2 * ji[1] / I[1][1];
736	this->rotate( 2, 0, angle, ji, A );
737
738	// rotate about the z-axis
739	angle = dt * ji[2] / I[2][2];
740	sd->addZangle(angle);
741	this->rotate( 0, 1, angle, ji, A);
742
743	// rotate about the y-axis
744	angle = dt2 * ji[1] / I[1][1];
745	this->rotate( 2, 0, angle, ji, A );
746
747	// rotate about the x-axis
748	angle = dt2 * ji[0] / I[0][0];
749	this->rotate( 1, 2, angle, ji, A );
750
751	}
752	sd->setA( A );
753	}
754
755	template<typename T> void Integrator<T>::rotate(int axes1, int axes2,
756	double angle, double ji[3],
757	double A[3][3]){
758	int i, j, k;
759	double sinAngle;
760	double cosAngle;
761	double angleSqr;
762	double angleSqrOver4;
763	double top, bottom;
764	double rot[3][3];
765	double tempA[3][3];
766	double tempJ[3];
767
768	// initialize the tempA
769
770	for (i = 0; i < 3; i++){
771	for (j = 0; j < 3; j++){
772	tempA[j][i] = A[i][j];
773	}
774	}
775
776	// initialize the tempJ
777
778	for (i = 0; i < 3; i++)
779	tempJ[i] = ji[i];
780
781	// initalize rot as a unit matrix
782
783	rot[0][0] = 1.0;
784	rot[0][1] = 0.0;
785	rot[0][2] = 0.0;
786
787	rot[1][0] = 0.0;
788	rot[1][1] = 1.0;
789	rot[1][2] = 0.0;
790
791	rot[2][0] = 0.0;
792	rot[2][1] = 0.0;
793	rot[2][2] = 1.0;
794
795	// use a small angle aproximation for sin and cosine
796
797	angleSqr = angle * angle;
798	angleSqrOver4 = angleSqr / 4.0;
799	top = 1.0 - angleSqrOver4;
800	bottom = 1.0 + angleSqrOver4;
801
802	cosAngle = top / bottom;
803	sinAngle = angle / bottom;
804
805	rot[axes1][axes1] = cosAngle;
806	rot[axes2][axes2] = cosAngle;
807
808	rot[axes1][axes2] = sinAngle;
809	rot[axes2][axes1] = -sinAngle;
810
811	// rotate the momentum acoording to: ji[] = rot[][] * ji[]
812
813	for (i = 0; i < 3; i++){
814	ji[i] = 0.0;
815	for (k = 0; k < 3; k++){
816	ji[i] += rot[i][k] * tempJ[k];
817	}
818	}
819
820	// rotate the Rotation matrix acording to:
821	// A[][] = A[][] * transpose(rot[][])
822
823
824	// NOte for as yet unknown reason, we are performing the
825	// calculation as:
826	// transpose(A[][]) = transpose(A[][]) * transpose(rot[][])
827
828	for (i = 0; i < 3; i++){
829	for (j = 0; j < 3; j++){
830	A[j][i] = 0.0;
831	for (k = 0; k < 3; k++){
832	A[j][i] += tempA[i][k] * rot[j][k];
833	}
834	}
835	}
836	}
837
838	template<typename T> void Integrator<T>::calcForce(int calcPot, int calcStress){
839	myFF->doForces(calcPot, calcStress);
840	}
841
842	template<typename T> void Integrator<T>::thermalize(){
843	tStats->velocitize();
844	}
845
846	template<typename T> double Integrator<T>::getConservedQuantity(void){
847	return tStats->getTotalE();
848	}
849	template<typename T> string Integrator<T>::getAdditionalParameters(void){
850	//By default, return a null string
851	//The reason we use string instead of char* is that if we use char*, we will
852	//return a pointer point to local variable which might cause problem
853	return string();
854	}