OOPSE/libmdtools/Integrator.cpp

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

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

#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;

  // 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 balanceing 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 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();

  // 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){
    if ((info->getTime() + dt) >= currStatus){
      calcPot = 1;
      calcStress = 1;
    }

    integrateStep(calcPot, calcStress);

    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());
      calcPot = 0;
      calcStress = 0;
      currStatus += statusTime;
    }

    if (info->resetIntegrator){
      if (info->getTime() >= currReset){
        this->resetIntegrator();
        currReset += resetTime;
      }
    }

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


  // write the last frame
  dumpOut->writeDump(info->getTime());

  delete dumpOut;
  delete statOut;
}

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

  moveA();


#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


  // finish the velocity  half step

  moveB();


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


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

  for (i = 0; i < nAtoms; i++){
    atoms[i]->getVel(vel);
    atoms[i]->getPos(pos);
    atoms[i]->getFrc(frc);

    mass = atoms[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];
    }

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

    if (atoms[i]->isDirectional()){
      dAtom = (DirectionalAtom *) atoms[i];

      // get and convert the torque to body frame

      dAtom->getTrq(Tb);
      dAtom->lab2Body(Tb);

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

      dAtom->getJ(ji);

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

      this->rotationPropagation( dAtom, ji );

      dAtom->setJ(ji);
    }
  }

  if (nConstrained){
    constrainA();
  }
}


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

  for (i = 0; i < nAtoms; i++){
    atoms[i]->getVel(vel);
    atoms[i]->getFrc(frc);

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

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

    atoms[i]->setVel(vel);

    if (atoms[i]->isDirectional()){
      dAtom = (DirectionalAtom *) atoms[i];

      // get and convert the torque to body frame

      dAtom->getTrq(Tb);
      dAtom->lab2Body(Tb);

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

      dAtom->getJ(ji);

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


      dAtom->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
( DirectionalAtom* dAtom, double ji[3] ){

  double angle;
  double A[3][3], I[3][3];

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

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

  // 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];
  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 );

  dAtom->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:	843
Committed:	Wed Oct 29 20:41:39 2003 UTC (22 years ago) by mmeineke
File size:	16796 byte(s)
Log Message:	fixed a stdlib.h include error in bass.l fixed a little bug in the first time step, regarding the setting of ecr and est in fortran
#	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	#include "Integrator.hpp"
11	#include "simError.h"
12
13
14	template<typename T> Integrator<T>::Integrator(SimInfo* theInfo,
15	ForceFields* the_ff){
16	info = theInfo;
17	myFF = the_ff;
18	isFirst = 1;
19
20	molecules = info->molecules;
21	nMols = info->n_mol;
22
23	// give a little love back to the SimInfo object
24
25	if (info->the_integrator != NULL){
26	delete info->the_integrator;
27	}
28
29	nAtoms = info->n_atoms;
30
31	// check for constraints
32
33	constrainedA = NULL;
34	constrainedB = NULL;
35	constrainedDsqr = NULL;
36	moving = NULL;
37	moved = NULL;
38	oldPos = NULL;
39
40	nConstrained = 0;
41
42	checkConstraints();
43	}
44
45	template<typename T> Integrator<T>::~Integrator(){
46	if (nConstrained){
47	delete[] constrainedA;
48	delete[] constrainedB;
49	delete[] constrainedDsqr;
50	delete[] moving;
51	delete[] moved;
52	delete[] oldPos;
53	}
54	}
55
56	template<typename T> void Integrator<T>::checkConstraints(void){
57	isConstrained = 0;
58
59	Constraint* temp_con;
60	Constraint* dummy_plug;
61	temp_con = new Constraint[info->n_SRI];
62	nConstrained = 0;
63	int constrained = 0;
64
65	SRI** theArray;
66	for (int i = 0; i < nMols; i++){
67	theArray = (SRI * *) molecules[i].getMyBonds();
68	for (int j = 0; j < molecules[i].getNBonds(); j++){
69	constrained = theArray[j]->is_constrained();
70
71	if (constrained){
72	dummy_plug = theArray[j]->get_constraint();
73	temp_con[nConstrained].set_a(dummy_plug->get_a());
74	temp_con[nConstrained].set_b(dummy_plug->get_b());
75	temp_con[nConstrained].set_dsqr(dummy_plug->get_dsqr());
76
77	nConstrained++;
78	constrained = 0;
79	}
80	}
81
82	theArray = (SRI * *) molecules[i].getMyBends();
83	for (int j = 0; j < molecules[i].getNBends(); j++){
84	constrained = theArray[j]->is_constrained();
85
86	if (constrained){
87	dummy_plug = theArray[j]->get_constraint();
88	temp_con[nConstrained].set_a(dummy_plug->get_a());
89	temp_con[nConstrained].set_b(dummy_plug->get_b());
90	temp_con[nConstrained].set_dsqr(dummy_plug->get_dsqr());
91
92	nConstrained++;
93	constrained = 0;
94	}
95	}
96
97	theArray = (SRI * *) molecules[i].getMyTorsions();
98	for (int j = 0; j < molecules[i].getNTorsions(); j++){
99	constrained = theArray[j]->is_constrained();
100
101	if (constrained){
102	dummy_plug = theArray[j]->get_constraint();
103	temp_con[nConstrained].set_a(dummy_plug->get_a());
104	temp_con[nConstrained].set_b(dummy_plug->get_b());
105	temp_con[nConstrained].set_dsqr(dummy_plug->get_dsqr());
106
107	nConstrained++;
108	constrained = 0;
109	}
110	}
111	}
112
113	if (nConstrained > 0){
114	isConstrained = 1;
115
116	if (constrainedA != NULL)
117	delete[] constrainedA;
118	if (constrainedB != NULL)
119	delete[] constrainedB;
120	if (constrainedDsqr != NULL)
121	delete[] constrainedDsqr;
122
123	constrainedA = new int[nConstrained];
124	constrainedB = new int[nConstrained];
125	constrainedDsqr = new double[nConstrained];
126
127	for (int i = 0; i < nConstrained; i++){
128	constrainedA[i] = temp_con[i].get_a();
129	constrainedB[i] = temp_con[i].get_b();
130	constrainedDsqr[i] = temp_con[i].get_dsqr();
131	}
132
133
134	// save oldAtoms to check for lode balanceing later on.
135
136	oldAtoms = nAtoms;
137
138	moving = new int[nAtoms];
139	moved = new int[nAtoms];
140
141	oldPos = new double[nAtoms * 3];
142	}
143
144	delete[] temp_con;
145	}
146
147
148	template<typename T> void Integrator<T>::integrate(void){
149
150	double runTime = info->run_time;
151	double sampleTime = info->sampleTime;
152	double statusTime = info->statusTime;
153	double thermalTime = info->thermalTime;
154	double resetTime = info->resetTime;
155
156
157	double currSample;
158	double currThermal;
159	double currStatus;
160	double currReset;
161
162	int calcPot, calcStress;
163
164	tStats = new Thermo(info);
165	statOut = new StatWriter(info);
166	dumpOut = new DumpWriter(info);
167
168	atoms = info->atoms;
169
170	dt = info->dt;
171	dt2 = 0.5 * dt;
172
173	readyCheck();
174
175	// initialize the forces before the first step
176
177	calcForce(1, 1);
178
179	if (nConstrained){
180	preMove();
181	constrainA();
182	calcForce(1, 1);
183	constrainB();
184	}
185
186	if (info->setTemp){
187	thermalize();
188	}
189
190	calcPot = 0;
191	calcStress = 0;
192	currSample = sampleTime + info->getTime();
193	currThermal = thermalTime+ info->getTime();
194	currStatus = statusTime + info->getTime();
195	currReset = resetTime + info->getTime();
196
197	dumpOut->writeDump(info->getTime());
198	statOut->writeStat(info->getTime());
199
200
201	#ifdef IS_MPI
202	strcpy(checkPointMsg, "The integrator is ready to go.");
203	MPIcheckPoint();
204	#endif // is_mpi
205
206	while (info->getTime() < runTime){
207	if ((info->getTime() + dt) >= currStatus){
208	calcPot = 1;
209	calcStress = 1;
210	}
211
212	integrateStep(calcPot, calcStress);
213
214	info->incrTime(dt);
215
216	if (info->setTemp){
217	if (info->getTime() >= currThermal){
218	thermalize();
219	currThermal += thermalTime;
220	}
221	}
222
223	if (info->getTime() >= currSample){
224	dumpOut->writeDump(info->getTime());
225	currSample += sampleTime;
226	}
227
228	if (info->getTime() >= currStatus){
229	statOut->writeStat(info->getTime());
230	calcPot = 0;
231	calcStress = 0;
232	currStatus += statusTime;
233	}
234
235	if (info->resetIntegrator){
236	if (info->getTime() >= currReset){
237	this->resetIntegrator();
238	currReset += resetTime;
239	}
240	}
241
242	#ifdef IS_MPI
243	strcpy(checkPointMsg, "successfully took a time step.");
244	MPIcheckPoint();
245	#endif // is_mpi
246	}
247
248
249	// write the last frame
250	dumpOut->writeDump(info->getTime());
251
252	delete dumpOut;
253	delete statOut;
254	}
255
256	template<typename T> void Integrator<T>::integrateStep(int calcPot,
257	int calcStress){
258	// Position full step, and velocity half step
259	preMove();
260
261	moveA();
262
263
264
265
266	#ifdef IS_MPI
267	strcpy(checkPointMsg, "Succesful moveA\n");
268	MPIcheckPoint();
269	#endif // is_mpi
270
271
272	// calc forces
273
274	calcForce(calcPot, calcStress);
275
276	#ifdef IS_MPI
277	strcpy(checkPointMsg, "Succesful doForces\n");
278	MPIcheckPoint();
279	#endif // is_mpi
280
281
282	// finish the velocity half step
283
284	moveB();
285
286
287
288	#ifdef IS_MPI
289	strcpy(checkPointMsg, "Succesful moveB\n");
290	MPIcheckPoint();
291	#endif // is_mpi
292	}
293
294
295	template<typename T> void Integrator<T>::moveA(void){
296	int i, j;
297	DirectionalAtom* dAtom;
298	double Tb[3], ji[3];
299	double vel[3], pos[3], frc[3];
300	double mass;
301
302	for (i = 0; i < nAtoms; i++){
303	atoms[i]->getVel(vel);
304	atoms[i]->getPos(pos);
305	atoms[i]->getFrc(frc);
306
307	mass = atoms[i]->getMass();
308
309	for (j = 0; j < 3; j++){
310	// velocity half step
311	vel[j] += (dt2 * frc[j] / mass) * eConvert;
312	// position whole step
313	pos[j] += dt * vel[j];
314	}
315
316	atoms[i]->setVel(vel);
317	atoms[i]->setPos(pos);
318
319	if (atoms[i]->isDirectional()){
320	dAtom = (DirectionalAtom *) atoms[i];
321
322	// get and convert the torque to body frame
323
324	dAtom->getTrq(Tb);
325	dAtom->lab2Body(Tb);
326
327	// get the angular momentum, and propagate a half step
328
329	dAtom->getJ(ji);
330
331	for (j = 0; j < 3; j++)
332	ji[j] += (dt2 * Tb[j]) * eConvert;
333
334	this->rotationPropagation( dAtom, ji );
335
336	dAtom->setJ(ji);
337	}
338	}
339
340	if (nConstrained){
341	constrainA();
342	}
343	}
344
345
346	template<typename T> void Integrator<T>::moveB(void){
347	int i, j;
348	DirectionalAtom* dAtom;
349	double Tb[3], ji[3];
350	double vel[3], frc[3];
351	double mass;
352
353	for (i = 0; i < nAtoms; i++){
354	atoms[i]->getVel(vel);
355	atoms[i]->getFrc(frc);
356
357	mass = atoms[i]->getMass();
358
359	// velocity half step
360	for (j = 0; j < 3; j++)
361	vel[j] += (dt2 * frc[j] / mass) * eConvert;
362
363	atoms[i]->setVel(vel);
364
365	if (atoms[i]->isDirectional()){
366	dAtom = (DirectionalAtom *) atoms[i];
367
368	// get and convert the torque to body frame
369
370	dAtom->getTrq(Tb);
371	dAtom->lab2Body(Tb);
372
373	// get the angular momentum, and propagate a half step
374
375	dAtom->getJ(ji);
376
377	for (j = 0; j < 3; j++)
378	ji[j] += (dt2 * Tb[j]) * eConvert;
379
380
381	dAtom->setJ(ji);
382	}
383	}
384
385	if (nConstrained){
386	constrainB();
387	}
388	}
389
390	template<typename T> void Integrator<T>::preMove(void){
391	int i, j;
392	double pos[3];
393
394	if (nConstrained){
395	for (i = 0; i < nAtoms; i++){
396	atoms[i]->getPos(pos);
397
398	for (j = 0; j < 3; j++){
399	oldPos[3 * i + j] = pos[j];
400	}
401	}
402	}
403	}
404
405	template<typename T> void Integrator<T>::constrainA(){
406	int i, j;
407	int done;
408	double posA[3], posB[3];
409	double velA[3], velB[3];
410	double pab[3];
411	double rab[3];
412	int a, b, ax, ay, az, bx, by, bz;
413	double rma, rmb;
414	double dx, dy, dz;
415	double rpab;
416	double rabsq, pabsq, rpabsq;
417	double diffsq;
418	double gab;
419	int iteration;
420
421	for (i = 0; i < nAtoms; i++){
422	moving[i] = 0;
423	moved[i] = 1;
424	}
425
426	iteration = 0;
427	done = 0;
428	while (!done && (iteration < maxIteration)){
429	done = 1;
430	for (i = 0; i < nConstrained; i++){
431	a = constrainedA[i];
432	b = constrainedB[i];
433
434	ax = (a * 3) + 0;
435	ay = (a * 3) + 1;
436	az = (a * 3) + 2;
437
438	bx = (b * 3) + 0;
439	by = (b * 3) + 1;
440	bz = (b * 3) + 2;
441
442	if (moved[a] \|\| moved[b]){
443	atoms[a]->getPos(posA);
444	atoms[b]->getPos(posB);
445
446	for (j = 0; j < 3; j++)
447	pab[j] = posA[j] - posB[j];
448
449	//periodic boundary condition
450
451	info->wrapVector(pab);
452
453	pabsq = pab[0] * pab[0] + pab[1] * pab[1] + pab[2] * pab[2];
454
455	rabsq = constrainedDsqr[i];
456	diffsq = rabsq - pabsq;
457
458	// the original rattle code from alan tidesley
459	if (fabs(diffsq) > (tol * rabsq * 2)){
460	rab[0] = oldPos[ax] - oldPos[bx];
461	rab[1] = oldPos[ay] - oldPos[by];
462	rab[2] = oldPos[az] - oldPos[bz];
463
464	info->wrapVector(rab);
465
466	rpab = rab[0] * pab[0] + rab[1] * pab[1] + rab[2] * pab[2];
467
468	rpabsq = rpab * rpab;
469
470
471	if (rpabsq < (rabsq * -diffsq)){
472	#ifdef IS_MPI
473	a = atoms[a]->getGlobalIndex();
474	b = atoms[b]->getGlobalIndex();
475	#endif //is_mpi
476	sprintf(painCave.errMsg,
477	"Constraint failure in constrainA at atom %d and %d.\n", a,
478	b);
479	painCave.isFatal = 1;
480	simError();
481	}
482
483	rma = 1.0 / atoms[a]->getMass();
484	rmb = 1.0 / atoms[b]->getMass();
485
486	gab = diffsq / (2.0 * (rma + rmb) * rpab);
487
488	dx = rab[0] * gab;
489	dy = rab[1] * gab;
490	dz = rab[2] * gab;
491
492	posA[0] += rma * dx;
493	posA[1] += rma * dy;
494	posA[2] += rma * dz;
495
496	atoms[a]->setPos(posA);
497
498	posB[0] -= rmb * dx;
499	posB[1] -= rmb * dy;
500	posB[2] -= rmb * dz;
501
502	atoms[b]->setPos(posB);
503
504	dx = dx / dt;
505	dy = dy / dt;
506	dz = dz / dt;
507
508	atoms[a]->getVel(velA);
509
510	velA[0] += rma * dx;
511	velA[1] += rma * dy;
512	velA[2] += rma * dz;
513
514	atoms[a]->setVel(velA);
515
516	atoms[b]->getVel(velB);
517
518	velB[0] -= rmb * dx;
519	velB[1] -= rmb * dy;
520	velB[2] -= rmb * dz;
521
522	atoms[b]->setVel(velB);
523
524	moving[a] = 1;
525	moving[b] = 1;
526	done = 0;
527	}
528	}
529	}
530
531	for (i = 0; i < nAtoms; i++){
532	moved[i] = moving[i];
533	moving[i] = 0;
534	}
535
536	iteration++;
537	}
538
539	if (!done){
540	sprintf(painCave.errMsg,
541	"Constraint failure in constrainA, too many iterations: %d\n",
542	iteration);
543	painCave.isFatal = 1;
544	simError();
545	}
546
547	}
548
549	template<typename T> void Integrator<T>::constrainB(void){
550	int i, j;
551	int done;
552	double posA[3], posB[3];
553	double velA[3], velB[3];
554	double vxab, vyab, vzab;
555	double rab[3];
556	int a, b, ax, ay, az, bx, by, bz;
557	double rma, rmb;
558	double dx, dy, dz;
559	double rvab;
560	double gab;
561	int iteration;
562
563	for (i = 0; i < nAtoms; i++){
564	moving[i] = 0;
565	moved[i] = 1;
566	}
567
568	done = 0;
569	iteration = 0;
570	while (!done && (iteration < maxIteration)){
571	done = 1;
572
573	for (i = 0; i < nConstrained; i++){
574	a = constrainedA[i];
575	b = constrainedB[i];
576
577	ax = (a * 3) + 0;
578	ay = (a * 3) + 1;
579	az = (a * 3) + 2;
580
581	bx = (b * 3) + 0;
582	by = (b * 3) + 1;
583	bz = (b * 3) + 2;
584
585	if (moved[a] \|\| moved[b]){
586	atoms[a]->getVel(velA);
587	atoms[b]->getVel(velB);
588
589	vxab = velA[0] - velB[0];
590	vyab = velA[1] - velB[1];
591	vzab = velA[2] - velB[2];
592
593	atoms[a]->getPos(posA);
594	atoms[b]->getPos(posB);
595
596	for (j = 0; j < 3; j++)
597	rab[j] = posA[j] - posB[j];
598
599	info->wrapVector(rab);
600
601	rma = 1.0 / atoms[a]->getMass();
602	rmb = 1.0 / atoms[b]->getMass();
603
604	rvab = rab[0] * vxab + rab[1] * vyab + rab[2] * vzab;
605
606	gab = -rvab / ((rma + rmb) * constrainedDsqr[i]);
607
608	if (fabs(gab) > tol){
609	dx = rab[0] * gab;
610	dy = rab[1] * gab;
611	dz = rab[2] * gab;
612
613	velA[0] += rma * dx;
614	velA[1] += rma * dy;
615	velA[2] += rma * dz;
616
617	atoms[a]->setVel(velA);
618
619	velB[0] -= rmb * dx;
620	velB[1] -= rmb * dy;
621	velB[2] -= rmb * dz;
622
623	atoms[b]->setVel(velB);
624
625	moving[a] = 1;
626	moving[b] = 1;
627	done = 0;
628	}
629	}
630	}
631
632	for (i = 0; i < nAtoms; i++){
633	moved[i] = moving[i];
634	moving[i] = 0;
635	}
636
637	iteration++;
638	}
639
640	if (!done){
641	sprintf(painCave.errMsg,
642	"Constraint failure in constrainB, too many iterations: %d\n",
643	iteration);
644	painCave.isFatal = 1;
645	simError();
646	}
647	}
648
649	template<typename T> void Integrator<T>::rotationPropagation
650	( DirectionalAtom* dAtom, double ji[3] ){
651
652	double angle;
653	double A[3][3], I[3][3];
654
655	// use the angular velocities to propagate the rotation matrix a
656	// full time step
657
658	dAtom->getA(A);
659	dAtom->getI(I);
660
661	// rotate about the x-axis
662	angle = dt2 * ji[0] / I[0][0];
663	this->rotate( 1, 2, angle, ji, A );
664
665	// rotate about the y-axis
666	angle = dt2 * ji[1] / I[1][1];
667	this->rotate( 2, 0, angle, ji, A );
668
669	// rotate about the z-axis
670	angle = dt * ji[2] / I[2][2];
671	this->rotate( 0, 1, angle, ji, A);
672
673	// rotate about the y-axis
674	angle = dt2 * ji[1] / I[1][1];
675	this->rotate( 2, 0, angle, ji, A );
676
677	// rotate about the x-axis
678	angle = dt2 * ji[0] / I[0][0];
679	this->rotate( 1, 2, angle, ji, A );
680
681	dAtom->setA( A );
682	}
683
684	template<typename T> void Integrator<T>::rotate(int axes1, int axes2,
685	double angle, double ji[3],
686	double A[3][3]){
687	int i, j, k;
688	double sinAngle;
689	double cosAngle;
690	double angleSqr;
691	double angleSqrOver4;
692	double top, bottom;
693	double rot[3][3];
694	double tempA[3][3];
695	double tempJ[3];
696
697	// initialize the tempA
698
699	for (i = 0; i < 3; i++){
700	for (j = 0; j < 3; j++){
701	tempA[j][i] = A[i][j];
702	}
703	}
704
705	// initialize the tempJ
706
707	for (i = 0; i < 3; i++)
708	tempJ[i] = ji[i];
709
710	// initalize rot as a unit matrix
711
712	rot[0][0] = 1.0;
713	rot[0][1] = 0.0;
714	rot[0][2] = 0.0;
715
716	rot[1][0] = 0.0;
717	rot[1][1] = 1.0;
718	rot[1][2] = 0.0;
719
720	rot[2][0] = 0.0;
721	rot[2][1] = 0.0;
722	rot[2][2] = 1.0;
723
724	// use a small angle aproximation for sin and cosine
725
726	angleSqr = angle * angle;
727	angleSqrOver4 = angleSqr / 4.0;
728	top = 1.0 - angleSqrOver4;
729	bottom = 1.0 + angleSqrOver4;
730
731	cosAngle = top / bottom;
732	sinAngle = angle / bottom;
733
734	rot[axes1][axes1] = cosAngle;
735	rot[axes2][axes2] = cosAngle;
736
737	rot[axes1][axes2] = sinAngle;
738	rot[axes2][axes1] = -sinAngle;
739
740	// rotate the momentum acoording to: ji[] = rot[][] * ji[]
741
742	for (i = 0; i < 3; i++){
743	ji[i] = 0.0;
744	for (k = 0; k < 3; k++){
745	ji[i] += rot[i][k] * tempJ[k];
746	}
747	}
748
749	// rotate the Rotation matrix acording to:
750	// A[][] = A[][] * transpose(rot[][])
751
752
753	// NOte for as yet unknown reason, we are performing the
754	// calculation as:
755	// transpose(A[][]) = transpose(A[][]) * transpose(rot[][])
756
757	for (i = 0; i < 3; i++){
758	for (j = 0; j < 3; j++){
759	A[j][i] = 0.0;
760	for (k = 0; k < 3; k++){
761	A[j][i] += tempA[i][k] * rot[j][k];
762	}
763	}
764	}
765	}
766
767	template<typename T> void Integrator<T>::calcForce(int calcPot, int calcStress){
768	myFF->doForces(calcPot, calcStress);
769	}
770
771	template<typename T> void Integrator<T>::thermalize(){
772	tStats->velocitize();
773	}
774
775	template<typename T> double Integrator<T>::getConservedQuantity(void){
776	return tStats->getTotalE();
777	}
778	template<typename T> string Integrator<T>::getAdditionalParameters(void){
779	//By default, return a null string
780	//The reason we use string instead of char* is that if we use char*, we will
781	//return a pointer point to local variable which might cause problem
782	return string();
783	}