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root/OpenMD/branches/development/src/integrators/Integrator.cpp

Comparing:
trunk/src/integrators/Integrator.cpp (file contents), Revision 221 by chrisfen, Tue Nov 23 22:48:31 2004 UTC vs.
branches/development/src/integrators/Integrator.cpp (file contents), Revision 1738 by gezelter, Tue Jun 5 17:58:01 2012 UTC

#	Line 1 | Line 1
1	<	#include <iostream>
2	<	#include <stdlib.h>
3	<	#include <math.h>
4	<	#ifdef IS_MPI
5	<	#include "brains/mpiSimulation.hpp"
6	<	#include <unistd.h>
7	<	#endif //is_mpi
8	<
9	<	#ifdef PROFILE
10	<	#include "profiling/mdProfile.hpp"
11	<	#endif // profile
12	<
1	>	/*
2	>	* Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
3	>	*
4	>	* The University of Notre Dame grants you ("Licensee") a
5	>	* non-exclusive, royalty free, license to use, modify and
6	>	* redistribute this software in source and binary code form, provided
7	>	* that the following conditions are met:
8	>	*
9	>	* 1. Redistributions of source code must retain the above copyright
10	>	*    notice, this list of conditions and the following disclaimer.
11	>	*
12	>	* 2. Redistributions in binary form must reproduce the above copyright
13	>	*    notice, this list of conditions and the following disclaimer in the
14	>	*    documentation and/or other materials provided with the
15	>	*    distribution.
16	>	*
17	>	* This software is provided "AS IS," without a warranty of any
18	>	* kind. All express or implied conditions, representations and
19	>	* warranties, including any implied warranty of merchantability,
20	>	* fitness for a particular purpose or non-infringement, are hereby
21	>	* excluded.  The University of Notre Dame and its licensors shall not
22	>	* be liable for any damages suffered by licensee as a result of
23	>	* using, modifying or distributing the software or its
24	>	* derivatives. In no event will the University of Notre Dame or its
25	>	* licensors be liable for any lost revenue, profit or data, or for
26	>	* direct, indirect, special, consequential, incidental or punitive
27	>	* damages, however caused and regardless of the theory of liability,
28	>	* arising out of the use of or inability to use software, even if the
29	>	* University of Notre Dame has been advised of the possibility of
30	>	* such damages.
31	>	*
32	>	* SUPPORT OPEN SCIENCE!  If you use OpenMD or its source code in your
33	>	* research, please cite the appropriate papers when you publish your
34	>	* work.  Good starting points are:
35	>	*
36	>	* [1]  Meineke, et al., J. Comp. Chem. 26, 252-271 (2005).
37	>	* [2]  Fennell & Gezelter, J. Chem. Phys. 124, 234104 (2006).
38	>	* [3]  Sun, Lin & Gezelter, J. Chem. Phys. 128, 24107 (2008).
39	>	* [4]  Kuang & Gezelter,  J. Chem. Phys. 133, 164101 (2010).
40	>	* [5]  Vardeman, Stocker & Gezelter, J. Chem. Theory Comput. 7, 834 (2011).
41	>	*/
42	>
43	>	#include "brains/Snapshot.hpp"
44		#include "integrators/Integrator.hpp"
45	+	#include "integrators/DLM.hpp"
46	+	#include "flucq/FluctuatingChargeNVT.hpp"
47		#include "utils/simError.h"
48
49	<
50	<	template<typename T> Integrator<T>::Integrator(SimInfo* theInfo,
51	<	ForceFields* the_ff){
52	<	info = theInfo;
53	<	myFF = the_ff;
54	<	isFirst = 1;
55	<
56	<	molecules = info->molecules;
57	<	nMols = info->n_mol;
58	<
59	<	// give a little love back to the SimInfo object
60	<
61	<	if (info->the_integrator != NULL){
62	<	delete info->the_integrator;
63	<	}
64	<
65	<	nAtoms = info->n_atoms;
33	<	integrableObjects = info->integrableObjects;
34	<
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	<
53	<	if (nConstrained){
54	<	delete[] constrainedA;
55	<	delete[] constrainedB;
56	<	delete[] constrainedDsqr;
57	<	delete[] moving;
58	<	delete[] moved;
59	<	delete[] oldPos;
60	<	}
61	<
62	<	}
63	<
64	<
65	<	template<typename T> void Integrator<T>::checkConstraints(void){
66	<	isConstrained = 0;
67	<
68	<	Constraint* temp_con;
69	<	Constraint* dummy_plug;
70	<	temp_con = new Constraint[info->n_SRI];
71	<	nConstrained = 0;
72	<	int constrained = 0;
73	<
74	<	SRI** theArray;
75	<	for (int i = 0; i < nMols; i++){
76	<
77	<	theArray = (SRI * *) molecules[i].getMyBonds();
78	<	for (int j = 0; j < molecules[i].getNBonds(); j++){
79	<	constrained = theArray[j]->is_constrained();
80	<
81	<	if (constrained){
82	<	dummy_plug = theArray[j]->get_constraint();
83	<	temp_con[nConstrained].set_a(dummy_plug->get_a());
84	<	temp_con[nConstrained].set_b(dummy_plug->get_b());
85	<	temp_con[nConstrained].set_dsqr(dummy_plug->get_dsqr());
86	<
87	<	nConstrained++;
88	<	constrained = 0;
89	<	}
49	>	namespace OpenMD {
50	>	Integrator::Integrator(SimInfo* info)
51	>	: info_(info), forceMan_(NULL) , needPotential(false), needStress(false),
52	>	needReset(false), velocitizer_(NULL), needVelocityScaling(false),
53	>	rnemd_(NULL), useRNEMD(false), rotAlgo_(NULL), flucQ_(NULL),
54	>	rattle_(NULL), dumpWriter(NULL), statWriter(NULL), thermo(info),
55	>	currentSnapshot_(info->getSnapshotManager()->getCurrentSnapshot()) {
56	>
57	>	simParams = info->getSimParams();
58	>
59	>	if (simParams->haveDt()) {
60	>	dt = simParams->getDt();
61	>	} else {
62	>	sprintf(painCave.errMsg,
63	>	"Integrator Error: dt is not set\n");
64	>	painCave.isFatal = 1;
65	>	simError();
66		}
67	<
68	<	theArray = (SRI * *) molecules[i].getMyBends();
69	<	for (int j = 0; j < molecules[i].getNBends(); j++){
70	<	constrained = theArray[j]->is_constrained();
71	<
72	<	if (constrained){
73	<	dummy_plug = theArray[j]->get_constraint();
74	<	temp_con[nConstrained].set_a(dummy_plug->get_a());
99	<	temp_con[nConstrained].set_b(dummy_plug->get_b());
100	<	temp_con[nConstrained].set_dsqr(dummy_plug->get_dsqr());
101	<
102	<	nConstrained++;
103	<	constrained = 0;
104	<	}
67	>
68	>	if (simParams->haveRunTime()) {
69	>	runTime = simParams->getRunTime();
70	>	} else {
71	>	sprintf(painCave.errMsg,
72	>	"Integrator Error: runTime is not set\n");
73	>	painCave.isFatal = 1;
74	>	simError();
75		}
76	<
77	<	theArray = (SRI * *) molecules[i].getMyTorsions();
78	<	for (int j = 0; j < molecules[i].getNTorsions(); j++){
79	<	constrained = theArray[j]->is_constrained();
80	<
81	<	if (constrained){
82	<	dummy_plug = theArray[j]->get_constraint();
83	<	temp_con[nConstrained].set_a(dummy_plug->get_a());
114	<	temp_con[nConstrained].set_b(dummy_plug->get_b());
115	<	temp_con[nConstrained].set_dsqr(dummy_plug->get_dsqr());
116	<
117	<	nConstrained++;
118	<	constrained = 0;
119	<	}
76	>
77	>	// set the status, sample, and thermal kick times
78	>	if (simParams->haveSampleTime()){
79	>	sampleTime = simParams->getSampleTime();
80	>	statusTime = sampleTime;
81	>	} else{
82	>	sampleTime = simParams->getRunTime();
83	>	statusTime = sampleTime;
84		}
85	<	}
86	<
87	<
124	<	if (nConstrained > 0){
125	<	isConstrained = 1;
126	<
127	<	if (constrainedA != NULL)
128	<	delete[] constrainedA;
129	<	if (constrainedB != NULL)
130	<	delete[] constrainedB;
131	<	if (constrainedDsqr != NULL)
132	<	delete[] constrainedDsqr;
133	<
134	<	constrainedA = new int[nConstrained];
135	<	constrainedB = new int[nConstrained];
136	<	constrainedDsqr = new double[nConstrained];
137	<
138	<	for (int i = 0; i < nConstrained; i++){
139	<	constrainedA[i] = temp_con[i].get_a();
140	<	constrainedB[i] = temp_con[i].get_b();
141	<	constrainedDsqr[i] = temp_con[i].get_dsqr();
85	>
86	>	if (simParams->haveStatusTime()){
87	>	statusTime = simParams->getStatusTime();
88		}
89	<
90	<
91	<	// save oldAtoms to check for lode balancing later on.
92	<
93	<	oldAtoms = nAtoms;
148	<
149	<	moving = new int[nAtoms];
150	<	moved = new int[nAtoms];
151	<
152	<	oldPos = new double[nAtoms * 3];
153	<	}
154	<
155	<	delete[] temp_con;
156	<	}
157	<
158	<
159	<	template<typename T> void Integrator<T>::integrate(void){
160	<
161	<	double runTime = info->run_time;
162	<	double sampleTime = info->sampleTime;
163	<	double statusTime = info->statusTime;
164	<	double thermalTime = info->thermalTime;
165	<	double resetTime = info->resetTime;
166	<
167	<	double difference;
168	<	double currSample;
169	<	double currThermal;
170	<	double currStatus;
171	<	double currReset;
172	<
173	<	int calcPot, calcStress;
174	<	int i;
175	<	int localIndex;
176	<
177	<	#ifdef IS_MPI
178	<	int which_node;
179	<	#endif // is_mpi
180	<
181	<	vector<StuntDouble*> particles;
182	<	string inAngle;
183	<
184	<	tStats = new Thermo(info);
185	<	statOut = new StatWriter(info);
186	<	dumpOut = new DumpWriter(info);
187	<
188	<	if (info->useSolidThermInt && !info->useLiquidThermInt) {
189	<	restOut = new RestraintWriter(info);
190	<	initRestraints = new RestraintReader(info);
191	<	}
192	<
193	<	atoms = info->atoms;
194	<
195	<	dt = info->dt;
196	<	dt2 = 0.5 * dt;
197	<
198	<	readyCheck();
199	<
200	<	// remove center of mass drift velocity (in case we passed in a configuration
201	<	// that was drifting
202	<	tStats->removeCOMdrift();
203	<
204	<	// initialize the retraints if necessary
205	<	if (info->useSolidThermInt && !info->useLiquidThermInt) {
206	<	initRestraints->zeroZangle();
207	<	inAngle = info->zAngleName + "_in";
208	<	initRestraints->readZangle(inAngle.c_str());
209	<	initRestraints->readIdealCrystal();
210	<	}
211	<
212	<	// initialize the forces before the first step
213	<	calcForce(1, 1);
214	<
215	<	//execute constraint algorithm to make sure at the very beginning the system is constrained
216	<	if(nConstrained){
217	<	preMove();
218	<	constrainA();
219	<	calcForce(1, 1);
220	<	constrainB();
221	<	}
222	<
223	<	if (info->setTemp){
224	<	thermalize();
225	<	}
226	<
227	<	calcPot     = 0;
228	<	calcStress  = 0;
229	<	currSample  = sampleTime + info->getTime();
230	<	currThermal = thermalTime+ info->getTime();
231	<	currStatus  = statusTime + info->getTime();
232	<	currReset   = resetTime  + info->getTime();
233	<
234	<	dumpOut->writeDump(info->getTime());
235	<	statOut->writeStat(info->getTime());
236	<	restOut->writeZangle(info->getTime());
237	<
238	<	#ifdef IS_MPI
239	<	strcpy(checkPointMsg, "The integrator is ready to go.");
240	<	MPIcheckPoint();
241	<	#endif // is_mpi
242	<
243	<	while (info->getTime() < runTime && !stopIntegrator()){
244	<	difference = info->getTime() + dt - currStatus;
245	<	if (difference > 0 || fabs(difference) < 1e-4 ){
246	<	calcPot = 1;
247	<	calcStress = 1;
89	>
90	>	if (simParams->haveThermalTime()){
91	>	thermalTime = simParams->getThermalTime();
92	>	} else {
93	>	thermalTime = simParams->getRunTime();
94		}
249	–
250	–	#ifdef PROFILE
251	–	startProfile( pro1 );
252	–	#endif
95
96	<	integrateStep(calcPot, calcStress);
97	<
256	<	#ifdef PROFILE
257	<	endProfile( pro1 );
258	<
259	<	startProfile( pro2 );
260	<	#endif // profile
261	<
262	<	info->incrTime(dt);
263	<
264	<	if (info->setTemp){
265	<	if (info->getTime() >= currThermal){
266	<	thermalize();
267	<	currThermal += thermalTime;
268	<	}
96	>	if (!simParams->getUseInitalTime()) {
97	>	currentSnapshot_->setTime(0.0);
98		}
99	<
100	<	if (info->getTime() >= currSample){
101	<	dumpOut->writeDump(info->getTime());
102	<	// write a zAng file to coincide with each dump or eor file
274	<	if (info->useSolidThermInt && !info->useLiquidThermInt)
275	<	restOut->writeZangle(info->getTime());
276	<	currSample += sampleTime;
99	>
100	>	if (simParams->haveResetTime()) {
101	>	needReset = true;
102	>	resetTime = simParams->getResetTime();
103		}
278	–
279	–	if (info->getTime() >= currStatus){
280	–	statOut->writeStat(info->getTime());
281	–	calcPot = 0;
282	–	calcStress = 0;
283	–	currStatus += statusTime;
284	–	}
285	–
286	–	if (info->resetIntegrator){
287	–	if (info->getTime() >= currReset){
288	–	this->resetIntegrator();
289	–	currReset += resetTime;
290	–	}
291	–	}
104
105	<	#ifdef PROFILE
106	<	endProfile( pro2 );
295	<	#endif //profile
105	>	// Create a default ForceManager: If the subclass wants to use
106	>	// a different ForceManager, use setForceManager
107
108	<	#ifdef IS_MPI
298	<	strcpy(checkPointMsg, "successfully took a time step.");
299	<	MPIcheckPoint();
300	<	#endif // is_mpi
301	<	}
302	<
303	<	dumpOut->writeFinal(info->getTime());
304	<
305	<	// write the file containing the omega values of the final configuration
306	<	if (info->useSolidThermInt && !info->useLiquidThermInt){
307	<	restOut->writeZangle(info->getTime());
308	<	restOut->writeZangle(info->getTime(), inAngle.c_str());
309	<	}
310	<
311	<	delete dumpOut;
312	<	delete statOut;
313	<	}
314	<
315	<	template<typename T> void Integrator<T>::integrateStep(int calcPot,
316	<	int calcStress){
317	<	// Position full step, and velocity half step
318	<
319	<	#ifdef PROFILE
320	<	startProfile(pro3);
321	<	#endif //profile
322	<
323	<	//save old state (position, velocity etc)
324	<	preMove();
325	<	#ifdef PROFILE
326	<	endProfile(pro3);
327	<
328	<	startProfile(pro4);
329	<	#endif // profile
330	<
331	<	moveA();
332	<
333	<	#ifdef PROFILE
334	<	endProfile(pro4);
335	<
336	<	startProfile(pro5);
337	<	#endif//profile
338	<
339	<
340	<	#ifdef IS_MPI
341	<	strcpy(checkPointMsg, "Succesful moveA\n");
342	<	MPIcheckPoint();
343	<	#endif // is_mpi
344	<
345	<	// calc forces
346	<	calcForce(calcPot, calcStress);
347	<
348	<	#ifdef IS_MPI
349	<	strcpy(checkPointMsg, "Succesful doForces\n");
350	<	MPIcheckPoint();
351	<	#endif // is_mpi
352	<
353	<	#ifdef PROFILE
354	<	endProfile( pro5 );
355	<
356	<	startProfile( pro6 );
357	<	#endif //profile
358	<
359	<	// finish the velocity  half step
360	<
361	<	moveB();
362	<
363	<	#ifdef PROFILE
364	<	endProfile(pro6);
365	<	#endif // profile
366	<
367	<	#ifdef IS_MPI
368	<	strcpy(checkPointMsg, "Succesful moveB\n");
369	<	MPIcheckPoint();
370	<	#endif // is_mpi
371	<	}
372	<
373	<
374	<	template<typename T> void Integrator<T>::moveA(void){
375	<	size_t i, j;
376	<	DirectionalAtom* dAtom;
377	<	double Tb[3], ji[3];
378	<	double vel[3], pos[3], frc[3];
379	<	double mass;
380	<	double omega;
381	<
382	<	for (i = 0; i < integrableObjects.size() ; i++){
383	<	integrableObjects[i]->getVel(vel);
384	<	integrableObjects[i]->getPos(pos);
385	<	integrableObjects[i]->getFrc(frc);
386	<	//    std::cerr << "f = " << frc[0] << "\t" << frc[1] << "\t" << frc[2] << "\n";
108	>	forceMan_ = new ForceManager(info);
109
110	<	mass = integrableObjects[i]->getMass();
110	>	// check for the temperature set flag (velocity scaling)
111	>	if (simParams->haveTempSet()) {
112	>	needVelocityScaling = simParams->getTempSet();
113
114	<	for (j = 0; j < 3; j++){
115	<	// velocity half step
116	<	vel[j] += (dt2 * frc[j] / mass) * eConvert;
117	<	// position whole step
118	<	pos[j] += dt * vel[j];
119	<	}
114	>	if (simParams->haveTargetTemp()) {
115	>	targetScalingTemp = simParams->getTargetTemp();
116	>	}
117	>	else {
118	>	sprintf(painCave.errMsg,
119	>	"Integrator Error: Target Temperature is not set\n");
120	>	painCave.isFatal = 1;
121	>	simError();
122
397	–	integrableObjects[i]->setVel(vel);
398	–	integrableObjects[i]->setPos(pos);
399	–
400	–
401	–	if (integrableObjects[i]->isDirectional()){
402	–
403	–	// get and convert the torque to body frame
404	–
405	–	integrableObjects[i]->getTrq(Tb);
406	–
407	–	//      std::cerr << "t = " << Tb[0] << "\t" << Tb[1] << "\t" << Tb[2] << "\n";
408	–	integrableObjects[i]->lab2Body(Tb);
409	–
410	–	// get the angular momentum, and propagate a half step
411	–
412	–	integrableObjects[i]->getJ(ji);
413	–
414	–	for (j = 0; j < 3; j++)
415	–	ji[j] += (dt2 * Tb[j]) * eConvert;
416	–
417	–	this->rotationPropagation( integrableObjects[i], ji );
418	–
419	–	integrableObjects[i]->setJ(ji);
420	–	}
421	–	}
422	–
423	–	if(nConstrained)
424	–	constrainA();
425	–	}
426	–
427	–
428	–	template<typename T> void Integrator<T>::moveB(void){
429	–	int i, j;
430	–	double Tb[3], ji[3];
431	–	double vel[3], frc[3];
432	–	double mass;
433	–
434	–	for (i = 0; i < integrableObjects.size(); i++){
435	–	integrableObjects[i]->getVel(vel);
436	–	integrableObjects[i]->getFrc(frc);
437	–
438	–	mass = integrableObjects[i]->getMass();
439	–
440	–	// velocity half step
441	–	for (j = 0; j < 3; j++)
442	–	vel[j] += (dt2 * frc[j] / mass) * eConvert;
443	–
444	–	integrableObjects[i]->setVel(vel);
445	–
446	–	if (integrableObjects[i]->isDirectional()){
447	–
448	–	// get and convert the torque to body frame
449	–
450	–	integrableObjects[i]->getTrq(Tb);
451	–	integrableObjects[i]->lab2Body(Tb);
452	–
453	–	// get the angular momentum, and propagate a half step
454	–
455	–	integrableObjects[i]->getJ(ji);
456	–
457	–	for (j = 0; j < 3; j++)
458	–	ji[j] += (dt2 * Tb[j]) * eConvert;
459	–
460	–
461	–	integrableObjects[i]->setJ(ji);
462	–	}
463	–	}
464	–
465	–	if(nConstrained)
466	–	constrainB();
467	–	}
468	–
469	–
470	–	template<typename T> void Integrator<T>::preMove(void){
471	–	int i, j;
472	–	double pos[3];
473	–
474	–	if (nConstrained){
475	–	for (i = 0; i < nAtoms; i++){
476	–	atoms[i]->getPos(pos);
477	–
478	–	for (j = 0; j < 3; j++){
479	–	oldPos[3 * i + j] = pos[j];
123		}
124		}
125	<	}
126	<	}
127	<
128	<	template<typename T> void Integrator<T>::constrainA(){
129	<	int i, j;
130	<	int done;
131	<	double posA[3], posB[3];
132	<	double velA[3], velB[3];
133	<	double pab[3];
134	<	double rab[3];
135	<	int a, b, ax, ay, az, bx, by, bz;
136	<	double rma, rmb;
137	<	double dx, dy, dz;
495	<	double rpab;
496	<	double rabsq, pabsq, rpabsq;
497	<	double diffsq;
498	<	double gab;
499	<	int iteration;
500	<
501	<	for (i = 0; i < nAtoms; i++){
502	<	moving[i] = 0;
503	<	moved[i] = 1;
504	<	}
505	<
506	<	iteration = 0;
507	<	done = 0;
508	<	while (!done && (iteration < maxIteration)){
509	<	done = 1;
510	<	for (i = 0; i < nConstrained; i++){
511	<	a = constrainedA[i];
512	<	b = constrainedB[i];
513	<
514	<	ax = (a * 3) + 0;
515	<	ay = (a * 3) + 1;
516	<	az = (a * 3) + 2;
517	<
518	<	bx = (b * 3) + 0;
519	<	by = (b * 3) + 1;
520	<	bz = (b * 3) + 2;
521	<
522	<	if (moved[a] || moved[b]){
523	<	atoms[a]->getPos(posA);
524	<	atoms[b]->getPos(posB);
525	<
526	<	for (j = 0; j < 3; j++)
527	<	pab[j] = posA[j] - posB[j];
528	<
529	<	//periodic boundary condition
530	<
531	<	info->wrapVector(pab);
532	<
533	<	pabsq = pab[0] * pab[0] + pab[1] * pab[1] + pab[2] * pab[2];
534	<
535	<	rabsq = constrainedDsqr[i];
536	<	diffsq = rabsq - pabsq;
537	<
538	<	// the original rattle code from alan tidesley
539	<	if (fabs(diffsq) > (tol * rabsq * 2)){
540	<	rab[0] = oldPos[ax] - oldPos[bx];
541	<	rab[1] = oldPos[ay] - oldPos[by];
542	<	rab[2] = oldPos[az] - oldPos[bz];
543	<
544	<	info->wrapVector(rab);
545	<
546	<	rpab = rab[0] * pab[0] + rab[1] * pab[1] + rab[2] * pab[2];
547	<
548	<	rpabsq = rpab * rpab;
549	<
550	<
551	<	if (rpabsq < (rabsq * -diffsq)){
552	<	#ifdef IS_MPI
553	<	a = atoms[a]->getGlobalIndex();
554	<	b = atoms[b]->getGlobalIndex();
555	<	#endif //is_mpi
556	<	sprintf(painCave.errMsg,
557	<	"Constraint failure in constrainA at atom %d and %d.\n", a,
558	<	b);
559	<	painCave.isFatal = 1;
560	<	simError();
561	<	}
562	<
563	<	rma = 1.0 / atoms[a]->getMass();
564	<	rmb = 1.0 / atoms[b]->getMass();
565	<
566	<	gab = diffsq / (2.0 * (rma + rmb) * rpab);
567	<
568	<	dx = rab[0] * gab;
569	<	dy = rab[1] * gab;
570	<	dz = rab[2] * gab;
571	<
572	<	posA[0] += rma * dx;
573	<	posA[1] += rma * dy;
574	<	posA[2] += rma * dz;
575	<
576	<	atoms[a]->setPos(posA);
577	<
578	<	posB[0] -= rmb * dx;
579	<	posB[1] -= rmb * dy;
580	<	posB[2] -= rmb * dz;
581	<
582	<	atoms[b]->setPos(posB);
583	<
584	<	dx = dx / dt;
585	<	dy = dy / dt;
586	<	dz = dz / dt;
587	<
588	<	atoms[a]->getVel(velA);
589	<
590	<	velA[0] += rma * dx;
591	<	velA[1] += rma * dy;
592	<	velA[2] += rma * dz;
593	<
594	<	atoms[a]->setVel(velA);
595	<
596	<	atoms[b]->getVel(velB);
597	<
598	<	velB[0] -= rmb * dx;
599	<	velB[1] -= rmb * dy;
600	<	velB[2] -= rmb * dz;
601	<
602	<	atoms[b]->setVel(velB);
603	<
604	<	moving[a] = 1;
605	<	moving[b] = 1;
606	<	done = 0;
607	<	}
125	>
126	>	// Create a default a velocitizer: If the subclass wants to use
127	>	// a different velocitizer, use setVelocitizer
128	>	velocitizer_ = new Velocitizer(info);
129	>
130	>	if (simParams->getRNEMDParameters()->haveUseRNEMD()) {
131	>	if (simParams->getRNEMDParameters()->getUseRNEMD()) {
132	>	// Create a default a RNEMD.
133	>	rnemd_ = new RNEMD(info);
134	>	useRNEMD = simParams->getRNEMDParameters()->getUseRNEMD();
135	>	if (simParams->getRNEMDParameters()->haveExchangeTime()) {
136	>	RNEMD_exchangeTime = simParams->getRNEMDParameters()->getExchangeTime();
137	>	}
138		}
139		}
140	<
141	<	for (i = 0; i < nAtoms; i++){
142	<	moved[i] = moving[i];
143	<	moving[i] = 0;
144	<	}
615	<
616	<	iteration++;
140	>
141	>	rotAlgo_ = new DLM();
142	>	rattle_ = new Rattle(info);
143	>	forceMan_->initialize();
144	>	flucQ_ = new FluctuatingChargeNVT(info, forceMan_);
145		}
146	<
147	<	if (!done){
148	<	sprintf(painCave.errMsg,
149	<	"Constraint failure in constrainA, too many iterations: %d\n",
150	<	iteration);
151	<	painCave.isFatal = 1;
152	<	simError();
153	<	}
626	<
627	<	}
628	<
629	<	template<typename T> void Integrator<T>::constrainB(void){
630	<	int i, j;
631	<	int done;
632	<	double posA[3], posB[3];
633	<	double velA[3], velB[3];
634	<	double vxab, vyab, vzab;
635	<	double rab[3];
636	<	int a, b, ax, ay, az, bx, by, bz;
637	<	double rma, rmb;
638	<	double dx, dy, dz;
639	<	double rvab;
640	<	double gab;
641	<	int iteration;
642	<
643	<	for (i = 0; i < nAtoms; i++){
644	<	moving[i] = 0;
645	<	moved[i] = 1;
646	<	}
647	<
648	<	done = 0;
649	<	iteration = 0;
650	<	while (!done && (iteration < maxIteration)){
651	<	done = 1;
652	<
653	<	for (i = 0; i < nConstrained; i++){
654	<	a = constrainedA[i];
655	<	b = constrainedB[i];
656	<
657	<	ax = (a * 3) + 0;
658	<	ay = (a * 3) + 1;
659	<	az = (a * 3) + 2;
660	<
661	<	bx = (b * 3) + 0;
662	<	by = (b * 3) + 1;
663	<	bz = (b * 3) + 2;
664	<
665	<	if (moved[a] || moved[b]){
666	<	atoms[a]->getVel(velA);
667	<	atoms[b]->getVel(velB);
668	<
669	<	vxab = velA[0] - velB[0];
670	<	vyab = velA[1] - velB[1];
671	<	vzab = velA[2] - velB[2];
672	<
673	<	atoms[a]->getPos(posA);
674	<	atoms[b]->getPos(posB);
675	<
676	<	for (j = 0; j < 3; j++)
677	<	rab[j] = posA[j] - posB[j];
678	<
679	<	info->wrapVector(rab);
680	<
681	<	rma = 1.0 / atoms[a]->getMass();
682	<	rmb = 1.0 / atoms[b]->getMass();
683	<
684	<	rvab = rab[0] * vxab + rab[1] * vyab + rab[2] * vzab;
685	<
686	<	gab = -rvab / ((rma + rmb) * constrainedDsqr[i]);
687	<
688	<	if (fabs(gab) > tol){
689	<	dx = rab[0] * gab;
690	<	dy = rab[1] * gab;
691	<	dz = rab[2] * gab;
692	<
693	<	velA[0] += rma * dx;
694	<	velA[1] += rma * dy;
695	<	velA[2] += rma * dz;
696	<
697	<	atoms[a]->setVel(velA);
698	<
699	<	velB[0] -= rmb * dx;
700	<	velB[1] -= rmb * dy;
701	<	velB[2] -= rmb * dz;
702	<
703	<	atoms[b]->setVel(velB);
704	<
705	<	moving[a] = 1;
706	<	moving[b] = 1;
707	<	done = 0;
708	<	}
709	<	}
710	<	}
711	<
712	<	for (i = 0; i < nAtoms; i++){
713	<	moved[i] = moving[i];
714	<	moving[i] = 0;
715	<	}
716	<
717	<	iteration++;
718	<	}
719	<
720	<	if (!done){
721	<	sprintf(painCave.errMsg,
722	<	"Constraint failure in constrainB, too many iterations: %d\n",
723	<	iteration);
724	<	painCave.isFatal = 1;
725	<	simError();
726	<	}
727	<	}
728	<
729	<	template<typename T> void Integrator<T>::rotationPropagation
730	<	( StuntDouble* sd, double ji[3] ){
731	<
732	<	double angle;
733	<	double A[3][3], I[3][3];
734	<	int i, j, k;
735	<
736	<	// use the angular velocities to propagate the rotation matrix a
737	<	// full time step
738	<
739	<	sd->getA(A);
740	<	sd->getI(I);
741	<
742	<	if (sd->isLinear()) {
743	<
744	<	i = sd->linearAxis();
745	<	j = (i+1)%3;
746	<	k = (i+2)%3;
747	<
748	<	angle = dt2 * ji[j] / I[j][j];
749	<	this->rotate( k, i, angle, ji, A );
750	<
751	<	angle = dt * ji[k] / I[k][k];
752	<	this->rotate( i, j, angle, ji, A);
753	<
754	<	angle = dt2 * ji[j] / I[j][j];
755	<	this->rotate( k, i, angle, ji, A );
756	<
757	<	} else {
758	<	// rotate about the x-axis
759	<	angle = dt2 * ji[0] / I[0][0];
760	<	this->rotate( 1, 2, angle, ji, A );
146	>
147	>	Integrator::~Integrator(){
148	>	delete forceMan_;
149	>	delete velocitizer_;
150	>	delete rnemd_;
151	>	delete flucQ_;
152	>	delete rotAlgo_;
153	>	delete rattle_;
154
155	<	// rotate about the y-axis
156	<	angle = dt2 * ji[1] / I[1][1];
764	<	this->rotate( 2, 0, angle, ji, A );
765	<
766	<	// rotate about the z-axis
767	<	angle = dt * ji[2] / I[2][2];
768	<	sd->addZangle(angle);
769	<	this->rotate( 0, 1, angle, ji, A);
770	<
771	<	// rotate about the y-axis
772	<	angle = dt2 * ji[1] / I[1][1];
773	<	this->rotate( 2, 0, angle, ji, A );
774	<
775	<	// rotate about the x-axis
776	<	angle = dt2 * ji[0] / I[0][0];
777	<	this->rotate( 1, 2, angle, ji, A );
778	<
155	>	delete dumpWriter;
156	>	delete statWriter;
157		}
780	–	sd->setA( A  );
158		}
159
783	–	template<typename T> void Integrator<T>::rotate(int axes1, int axes2,
784	–	double angle, double ji[3],
785	–	double A[3][3]){
786	–	int i, j, k;
787	–	double sinAngle;
788	–	double cosAngle;
789	–	double angleSqr;
790	–	double angleSqrOver4;
791	–	double top, bottom;
792	–	double rot[3][3];
793	–	double tempA[3][3];
794	–	double tempJ[3];
795	–
796	–	// initialize the tempA
797	–
798	–	for (i = 0; i < 3; i++){
799	–	for (j = 0; j < 3; j++){
800	–	tempA[j][i] = A[i][j];
801	–	}
802	–	}
803	–
804	–	// initialize the tempJ
805	–
806	–	for (i = 0; i < 3; i++)
807	–	tempJ[i] = ji[i];
808	–
809	–	// initalize rot as a unit matrix
810	–
811	–	rot[0][0] = 1.0;
812	–	rot[0][1] = 0.0;
813	–	rot[0][2] = 0.0;
814	–
815	–	rot[1][0] = 0.0;
816	–	rot[1][1] = 1.0;
817	–	rot[1][2] = 0.0;
818	–
819	–	rot[2][0] = 0.0;
820	–	rot[2][1] = 0.0;
821	–	rot[2][2] = 1.0;
822	–
823	–	// use a small angle aproximation for sin and cosine
824	–
825	–	angleSqr = angle * angle;
826	–	angleSqrOver4 = angleSqr / 4.0;
827	–	top = 1.0 - angleSqrOver4;
828	–	bottom = 1.0 + angleSqrOver4;
829	–
830	–	cosAngle = top / bottom;
831	–	sinAngle = angle / bottom;
832	–
833	–	rot[axes1][axes1] = cosAngle;
834	–	rot[axes2][axes2] = cosAngle;
835	–
836	–	rot[axes1][axes2] = sinAngle;
837	–	rot[axes2][axes1] = -sinAngle;
838	–
839	–	// rotate the momentum acoording to: ji[] = rot[][] * ji[]
840	–
841	–	for (i = 0; i < 3; i++){
842	–	ji[i] = 0.0;
843	–	for (k = 0; k < 3; k++){
844	–	ji[i] += rot[i][k] * tempJ[k];
845	–	}
846	–	}
847	–
848	–	// rotate the Rotation matrix acording to:
849	–	//            A[][] = A[][] * transpose(rot[][])
850	–
851	–
852	–	// NOte for as yet unknown reason, we are performing the
853	–	// calculation as:
854	–	//                transpose(A[][]) = transpose(A[][]) * transpose(rot[][])
855	–
856	–	for (i = 0; i < 3; i++){
857	–	for (j = 0; j < 3; j++){
858	–	A[j][i] = 0.0;
859	–	for (k = 0; k < 3; k++){
860	–	A[j][i] += tempA[i][k] * rot[j][k];
861	–	}
862	–	}
863	–	}
864	–	}
865	–
866	–	template<typename T> void Integrator<T>::calcForce(int calcPot, int calcStress){
867	–	myFF->doForces(calcPot, calcStress);
868	–	}
869	–
870	–	template<typename T> void Integrator<T>::thermalize(){
871	–	tStats->velocitize();
872	–	}
873	–
874	–	template<typename T> double Integrator<T>::getConservedQuantity(void){
875	–	return tStats->getTotalE();
876	–	}
877	–	template<typename T> string Integrator<T>::getAdditionalParameters(void){
878	–	//By default, return a null string
879	–	//The reason we use string instead of char* is that if we use char*, we will
880	–	//return a pointer point to local variable which might cause problem
881	–	return string();
882	–	}

Comparing:
trunk/src/integrators/Integrator.cpp (property svn:keywords), Revision 221 by chrisfen, Tue Nov 23 22:48:31 2004 UTC vs.
branches/development/src/integrators/Integrator.cpp (property svn:keywords), Revision 1738 by gezelter, Tue Jun 5 17:58:01 2012 UTC

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