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root/group/trunk/OOPSE/libmdtools/ZConstraint.cpp

Comparing trunk/OOPSE/libmdtools/ZConstraint.cpp (file contents):
Revision 738 by tim, Tue Sep 2 14:30:12 2003 UTC vs.
Revision 1093 by tim, Wed Mar 17 14:22:59 2004 UTC

#	Line 1 | Line 1
1	<	#include "Integrator.hpp"
2	<	#include "simError.h"
3	<	#include <cmath>
4	<	template<typename T> ZConstraint<T>::ZConstraint(SimInfo* theInfo, ForceFields* the_ff)
5	<	: T(theInfo, the_ff), fz(NULL), curZPos(NULL), fzOut(NULL),
6	<	indexOfZConsMols(NULL), forcePolicy(NULL), curZconsTime(0)
7	<	{
8	<
9	<	//get properties from SimInfo
10	<	GenericData* data;
11	<	ZConsParaData* zConsParaData;
12	<	DoubleData* sampleTime;
13	<	DoubleData* tolerance;
14	<	StringData* policy;
15	<	StringData* filename;
16	<	double COM[3];
17	<
18	<	//by default, the direction of constraint is z
19	<	// 0 --> x
20	<	// 1 --> y
21	<	// 2 --> z
22	<	whichDirection = 2;
23	<
24	<	//estimate the force constant of harmonical potential
25	<	double Kb = 1.986E-3 ; //in kcal/K
26	<
27	<	double halfOfLargestBox = max(info->boxL[0], max(info->boxL[1], info->boxL[2])) /2;
28	<	zForceConst = Kb * info->target_temp /(halfOfLargestBox * halfOfLargestBox);
29	<
30	<	//creat force Subtraction policy
31	<	data = info->getProperty(ZCONSFORCEPOLICY_ID);
32	<	if(!data){
33	<	sprintf( painCave.errMsg,
34	<	"ZConstraint Warning: User does not set force Subtraction policy, "
35	<	"PolicyByMass is used\n");
36	<	painCave.isFatal = 0;
37	<	simError();
38	<
39	<	forcePolicy = (ForceSubtractionPolicy*) new PolicyByMass(this);
40	<	}
41	<	else{
42	<	policy = dynamic_cast<StringData*>(data);
43	<
44	<	if(!policy){
45	<	sprintf( painCave.errMsg,
46	<	"ZConstraint Error: Convertion from GenericData to StringData failure, "
47	<	"PolicyByMass is used\n");
48	<	painCave.isFatal = 0;
49	<	simError();
50	<
51	<	forcePolicy = (ForceSubtractionPolicy*) new PolicyByMass(this);
52	<	}
53	<	else{
54	<	if(policy->getData() == "BYNUMBER")
55	<	forcePolicy = (ForceSubtractionPolicy*) new PolicyByNumber(this);
56	<	else if(policy->getData() == "BYMASS")
57	<	forcePolicy = (ForceSubtractionPolicy*) new PolicyByMass(this);
58	<	else{
59	<	sprintf( painCave.errMsg,
60	<	"ZConstraint Warning: unknown force Subtraction policy, "
61	<	"PolicyByMass is used\n");
62	<	painCave.isFatal = 0;
63	<	simError();
64	<	forcePolicy = (ForceSubtractionPolicy*) new PolicyByMass(this);
65	<	}
66	<	}
67	<	}
68	<
69	<
70	<	//retrieve sample time of z-contraint
71	<	data = info->getProperty(ZCONSTIME_ID);
72	<
73	<	if(!data) {
74	<
75	<	sprintf( painCave.errMsg,
76	<	"ZConstraint error: If you use an ZConstraint\n"
77	<	" , you must set sample time.\n");
78	<	painCave.isFatal = 1;
79	<	simError();
80	<	}
81	<	else{
82	<
83	<	sampleTime = dynamic_cast<DoubleData*>(data);
84	<
85	<	if(!sampleTime){
86	<
87	<	sprintf( painCave.errMsg,
88	<	"ZConstraint error: Can not get property from SimInfo\n");
89	<	painCave.isFatal = 1;
90	<	simError();
91	<
92	<	}
93	<	else{
94	<	this->zconsTime = sampleTime->getData();
95	<	}
96	<
97	<	}
98	<
99	<	//retrieve output filename of z force
100	<	data = info->getProperty(ZCONSFILENAME_ID);
101	<	if(!data) {
102	<
103	<
104	<	sprintf( painCave.errMsg,
105	<	"ZConstraint error: If you use an ZConstraint\n"
106	<	" , you must set output filename of z-force.\n");
107	<	painCave.isFatal = 1;
108	<	simError();
109	<
110	<	}
111	<	else{
112	<
113	<	filename = dynamic_cast<StringData*>(data);
114	<
115	<	if(!filename){
116	<
117	<	sprintf( painCave.errMsg,
118	<	"ZConstraint error: Can not get property from SimInfo\n");
119	<	painCave.isFatal = 1;
120	<	simError();
121	<
122	<	}
123	<	else{
124	<	this->zconsOutput = filename->getData();
125	<	}
126	<
127	<	}
128	<
129	<	//retrieve tolerance for z-constraint molecuels
130	<	data = info->getProperty(ZCONSTOL_ID);
131	<
132	<	if(!data) {
133	<
134	<	sprintf( painCave.errMsg,
135	<	"ZConstraint error: can not get tolerance \n");
136	<	painCave.isFatal = 1;
137	<	simError();
138	<	}
139	<	else{
140	<
141	<	tolerance = dynamic_cast<DoubleData*>(data);
142	<
143	<	if(!tolerance){
144	<
145	<	sprintf( painCave.errMsg,
146	<	"ZConstraint error: Can not get property from SimInfo\n");
147	<	painCave.isFatal = 1;
148	<	simError();
149	<
150	<	}
151	<	else{
152	<	this->zconsTol = tolerance->getData();
153	<	}
154	<
155	<	}
156	<
157	<	//retrieve index of z-constraint molecules
158	<	data = info->getProperty(ZCONSPARADATA_ID);
159	<	if(!data) {
160	<
161	<	sprintf( painCave.errMsg,
162	<	"ZConstraint error: If you use an ZConstraint\n"
163	<	" , you must set index of z-constraint molecules.\n");
164	<	painCave.isFatal = 1;
165	<	simError();
166	<	}
167	<	else{
168	<
169	<	zConsParaData = dynamic_cast<ZConsParaData*>(data);
170	<
171	<	if(!zConsParaData){
172	<
173	<	sprintf( painCave.errMsg,
174	<	"ZConstraint error: Can not get parameters of zconstraint method from SimInfo\n");
175	<	painCave.isFatal = 1;
176	<	simError();
177	<
178	<	}
179	<	else{
180	<
181	<	parameters = zConsParaData->getData();
182	<
183	<	//check the range of zconsIndex
184	<	//and the minimum value of index is the first one (we already sorted the data)
185	<	//the maximum value of index is the last one
186	<
187	<	int maxIndex;
188	<	int minIndex;
189	<	int totalNumMol;
190	<
191	<	minIndex = (*parameters)[0].zconsIndex;
192	<	if(minIndex < 0){
193	<	sprintf( painCave.errMsg,
194	<	"ZConstraint error: index is out of range\n");
195	<	painCave.isFatal = 1;
196	<	simError();
197	<	}
198	<
199	<	maxIndex = (*parameters)[parameters->size() - 1].zconsIndex;
200	<
201	<	#ifndef IS_MPI
202	<	totalNumMol = nMols;
203	<	#else
204	<	totalNumMol = mpiSim->getTotNmol();
205	<	#endif
206	<
207	<	if(maxIndex > totalNumMol - 1){
208	<	sprintf( painCave.errMsg,
209	<	"ZConstraint error: index is out of range\n");
210	<	painCave.isFatal = 1;
211	<	simError();
212	<	}
213	<
214	<	//if user does not specify the zpos for the zconstraint molecule
215	<	//its initial z coordinate  will be used as default
216	<	for(int i = 0; i < parameters->size(); i++){
217	<
218	<	if(!(*parameters)[i].havingZPos){
219	<	#ifndef IS_MPI
220	<	for(int j = 0; j < nMols; j++){
221	<	if (molecules[j].getGlobalIndex() == (*parameters)[i].zconsIndex){
222	<	molecules[j].getCOM(COM);
223	<	break;
224	<	}
225	<	}
226	<	#else
227	<	//query which processor current zconstraint molecule belongs to
228	<	int *MolToProcMap;
229	<	int whichNode;
230	<	double initZPos;
231	<	MolToProcMap = mpiSim->getMolToProcMap();
232	<	whichNode = MolToProcMap[(*parameters)[i].zconsIndex];
233	<
234	<	//broadcast the zpos of current z-contraint molecule
235	<	//the node which contain this
236	<
237	<	if (worldRank == whichNode ){
238	<
239	<	for(int j = 0; j < nMols; j++)
240	<	if (molecules[j].getGlobalIndex() == (*parameters)[i].zconsIndex){
241	<	molecules[j].getCOM(COM);
242	<	break;
243	<	}
244	<
245	<	}
246	<
247	<	MPI_Bcast(&COM[whichDirection], 1, MPI_DOUBLE_PRECISION, whichNode, MPI_COMM_WORLD);
248	<	#endif
249	<
250	<	(*parameters)[i].zPos = COM[whichDirection];
251	<
252	<	sprintf( painCave.errMsg,
253	<	"ZConstraint warning: Does not specify zpos for z-constraint molecule "
254	<	"initial z coornidate will be used \n");
255	<	painCave.isFatal = 0;
256	<	simError();
257	<
258	<	}
259	<	}
260	<
261	<	}//end if (!zConsParaData)
262	<	}//end  if (!data)
263	<
264	<	//
265	<	#ifdef IS_MPI
266	<	update();
267	<	#else
268	<	int searchResult;
269	<
270	<	for(int i = 0; i < nMols; i++){
271	<
272	<	searchResult = isZConstraintMol(&molecules[i]);
273	<
274	<	if(searchResult > -1){
275	<
276	<	zconsMols.push_back(&molecules[i]);
277	<	massOfZConsMols.push_back(molecules[i].getTotalMass());
278	<
279	<	zPos.push_back((*parameters)[searchResult].zPos);
280	<	//       cout << "index: "<< (*parameters)[searchResult].zconsIndex
281	<	//              <<"\tzPos = " << (*parameters)[searchResult].zPos << endl;
282	<	kz.push_back((*parameters)[searchResult]. kRatio * zForceConst);
283	<
284	<	molecules[i].getCOM(COM);
285	<	}
286	<	else
287	<	{
288	<
289	<	unconsMols.push_back(&molecules[i]);
290	<	massOfUnconsMols.push_back(molecules[i].getTotalMass());
291	<
292	<	}
293	<	}
294	<
295	<	fz = new double[zconsMols.size()];
296	<	curZPos = new double[zconsMols.size()];
297	<	indexOfZConsMols = new int [zconsMols.size()];
298	<
299	<	if(!fz || !curZPos || !indexOfZConsMols){
300	<	sprintf( painCave.errMsg,
301	<	"Memory allocation failure in class Zconstraint\n");
302	<	painCave.isFatal = 1;
303	<	simError();
304	<	}
305	<
306	<	//determine the states of z-constraint molecules
307	<	for(int i = 0; i < zconsMols.size(); i++){
308	<	indexOfZConsMols[i] = zconsMols[i]->getGlobalIndex();
309	<
310	<	zconsMols[i]->getCOM(COM);
311	<	if (fabs(zPos[i] - COM[whichDirection]) < zconsTol)
312	<	states.push_back(zcsFixed);
313	<	else
314	<	states.push_back(zcsMoving);
315	<	}
316	<
317	<	#endif
318	<
319	<	//get total masss of unconstraint molecules
320	<	double totalMassOfUncons_local;
321	<	totalMassOfUncons_local = 0;
322	<
323	<	for(int i = 0; i < unconsMols.size(); i++)
324	<	totalMassOfUncons_local += unconsMols[i]->getTotalMass();
325	<
326	<	#ifndef IS_MPI
327	<	totalMassOfUncons = totalMassOfUncons_local;
328	<	#else
329	<	MPI_Allreduce(&totalMassOfUncons_local, &totalMassOfUncons, 1,
330	<	MPI_DOUBLE, MPI_SUM, MPI_COMM_WORLD);
331	<	#endif
332	<
333	<	//get total number of unconstrained atoms
334	<	int nUnconsAtoms_local;
335	<	nUnconsAtoms_local = 0;
336	<	for(int i = 0; i < unconsMols.size(); i++)
337	<	nUnconsAtoms_local += unconsMols[i]->getNAtoms();
338	<
339	<	#ifndef IS_MPI
340	<	totNumOfUnconsAtoms = nUnconsAtoms_local;
341	<	#else
342	<	MPI_Allreduce(&nUnconsAtoms_local, &totNumOfUnconsAtoms, 1,
343	<	MPI_INT,MPI_SUM, MPI_COMM_WORLD);
344	<	#endif
345	<
346	<	forcePolicy->update();
347	<	}
348	<
349	<	template<typename T> ZConstraint<T>::~ZConstraint()
350	<	{
351	<	if(fz)
352	<	delete[] fz;
353	<
354	<	if(curZPos)
355	<	delete[] curZPos;
356	<
357	<	if(indexOfZConsMols)
358	<	delete[] indexOfZConsMols;
359	<
360	<	if(fzOut)
361	<	delete fzOut;
362	<
363	<	if(forcePolicy)
364	<	delete forcePolicy;
365	<	}
366	<
367	<
368	<	/**
369	<	*
370	<	*/
371	<
372	<	#ifdef IS_MPI
373	<	template<typename T> void ZConstraint<T>::update()
374	<	{
375	<	double COM[3];
376	<	int index;
377	<
378	<	zconsMols.clear();
379	<	massOfZConsMols.clear();
380	<	zPos.clear();
381	<	kz.clear();
382	<
383	<	unconsMols.clear();
384	<	massOfUnconsMols.clear();
385	<
386	<
387	<	//creat zconsMol and unconsMol lists
388	<	for(int i = 0; i < nMols; i++){
389	<
390	<	index = isZConstraintMol(&molecules[i]);
391	<
392	<	if(index > -1){
393	<
394	<	zconsMols.push_back(&molecules[i]);
395	<	zPos.push_back((*parameters)[index].zPos);
396	<	kz.push_back((*parameters)[index].kRatio * zForceConst);
397	<
398	<	massOfZConsMols.push_back(molecules[i].getTotalMass());
399	<
400	<	molecules[i].getCOM(COM);
401	<	}
402	<	else
403	<	{
404	<
405	<	unconsMols.push_back(&molecules[i]);
406	<	massOfUnconsMols.push_back(molecules[i].getTotalMass());
407	<
408	<	}
409	<	}
410	<
411	<	//determine the states of z-constraint molecules
412	<	for(int i = 0; i < zconsMols.size(); i++){
413	<	zconsMols[i]->getCOM(COM);
414	<	if (fabs(zPos[i] - COM[whichDirection]) < zconsTol)
415	<	states.push_back(zcsFixed);
416	<	else
417	<	states.push_back(zcsMoving);
418	<	}
419	<
420	<
421	<	//The reason to declare fz and indexOfZconsMols as pointer to array is
422	<	// that we want to make the MPI communication simple
423	<	if(fz)
424	<	delete[] fz;
425	<
426	<	if(curZPos)
427	<	delete[] curZPos;
428	<
429	<	if(indexOfZConsMols)
430	<	delete[] indexOfZConsMols;
431	<
432	<	if (zconsMols.size() > 0){
433	<	fz = new double[zconsMols.size()];
434	<	curZPos = new double[zconsMols.size()];
435	<	indexOfZConsMols =  new int[zconsMols.size()];
436	<
437	<	if(!fz || !curZPos || !indexOfZConsMols){
438	<	sprintf( painCave.errMsg,
439	<	"Memory allocation failure in class Zconstraint\n");
440	<	painCave.isFatal = 1;
441	<	simError();
442	<	}
443	<
444	<	for(int i = 0; i < zconsMols.size(); i++){
445	<	indexOfZConsMols[i] = zconsMols[i]->getGlobalIndex();
446	<	}
447	<
448	<	}
449	<	else{
450	<	fz = NULL;
451	<	curZPos = NULL;
452	<	indexOfZConsMols = NULL;
453	<	}
454	<
455	<	//
456	<	forcePolicy->update();
457	<
458	<	}
459	<
460	<	#endif
461	<
462	<	/**
463	<	*  Function Name: isZConstraintMol
464	<	*  Parameter
465	<	*    Molecule* mol
466	<	*  Return value:
467	<	*    -1, if the molecule is not z-constraint molecule,
468	<	*    other non-negative values, its index in indexOfAllZConsMols vector
469	<	*/
470	<
471	<	template<typename T> int ZConstraint<T>::isZConstraintMol(Molecule* mol)
472	<	{
473	<	int index;
474	<	int low;
475	<	int high;
476	<	int mid;
477	<
478	<	index = mol->getGlobalIndex();
479	<
480	<	low = 0;
481	<	high = parameters->size() - 1;
482	<
483	<	//Binary Search (we have sorted the array)
484	<	while(low <= high){
485	<	mid = (low + high) /2;
486	<	if ((*parameters)[mid].zconsIndex == index)
487	<	return mid;
488	<	else if ((*parameters)[mid].zconsIndex > index )
489	<	high = mid -1;
490	<	else
491	<	low = mid + 1;
492	<	}
493	<
494	<	return -1;
495	<	}
496	<
497	<	template<typename T> void ZConstraint<T>::integrate(){
498	<
499	<	// creat zconsWriter
500	<	fzOut = new ZConsWriter(zconsOutput.c_str(), parameters);
501	<
502	<	if(!fzOut){
503	<	sprintf( painCave.errMsg,
504	<	"Memory allocation failure in class Zconstraint\n");
505	<	painCave.isFatal = 1;
506	<	simError();
507	<	}
508	<
509	<	//zero out the velocities of center of mass of unconstrained molecules
510	<	//and the velocities of center of mass of every single z-constrained molecueles
511	<	zeroOutVel();
512	<
513	<	curZconsTime = zconsTime + info->getTime();
514	<
515	<	T::integrate();
516	<
517	<	}
518	<
519	<
520	<	/**
521	<	*
522	<	*
523	<	*
524	<	*
525	<	*/
526	<	template<typename T> void ZConstraint<T>::calcForce(int calcPot, int calcStress){
527	<	double zsys;
528	<	double COM[3];
529	<	double force[3];
530	<	double zSysCOMVel;
531	<
532	<	T::calcForce(calcPot, calcStress);
533	<
534	<	if (checkZConsState()){
535	<	zeroOutVel();
536	<	forcePolicy->update();
537	<	}
538	<
539	<	zsys = calcZSys();
540	<	zSysCOMVel = calcSysCOMVel();
541	<	#ifdef IS_MPI
542	<	if(worldRank == 0){
543	<	#endif
544	<	//cout << "---------------------------------------------------------------------" <<endl;
545	<	//cout << "current time: " << info->getTime() << endl;
546	<	//cout << "center of mass at z: " << zsys << endl;
547	<	//cout << "before calcForce, the COMVel of system is " << zSysCOMVel <<endl;
548	<
549	<	#ifdef IS_MPI
550	<	}
551	<	#endif
552	<
553	<	//do zconstraint force;
554	<	if (haveFixedZMols())
555	<	this->doZconstraintForce();
556	<
557	<	//use harmonical poteintial to move the molecules to the specified positions
558	<	if (haveMovingZMols())
559	<	this->doHarmonic();
560	<
561	<	//write out forces and current positions of z-constraint molecules
562	<	if(info->getTime() >= curZconsTime){
563	<	for(int i = 0; i < zconsMols.size(); i++){
564	<	zconsMols[i]->getCOM(COM);
565	<	curZPos[i] = COM[whichDirection];
566	<
567	<	//if the z-constraint molecule is still moving, just record its force
568	<	if(states[i] == zcsMoving){
569	<	fz[i] = 0;
570	<	Atom** movingZAtoms;
571	<	movingZAtoms = zconsMols[i]->getMyAtoms();
572	<	for(int j = 0; j < zconsMols[i]->getNAtoms(); j++){
573	<	movingZAtoms[j]->getFrc(force);
574	<	fz[i] += force[whichDirection];
575	<	}
576	<	}
577	<	}
578	<	fzOut->writeFZ(info->getTime(), zconsMols.size(), indexOfZConsMols, fz, curZPos);
579	<	curZconsTime += zconsTime;
580	<	}
581	<
582	<	zSysCOMVel = calcSysCOMVel();
583	<	#ifdef IS_MPI
584	<	if(worldRank == 0){
585	<	#endif
586	<	//cout << "after calcForce, the COMVel of system is " << zSysCOMVel <<endl;
587	<	#ifdef IS_MPI
588	<	}
589	<	#endif
590	<	}
591	<
592	<
593	<	/**
594	<	*
595	<	*/
596	<
597	<	template<typename T> double ZConstraint<T>::calcZSys()
598	<	{
599	<	//calculate reference z coordinate for z-constraint molecules
600	<	double totalMass_local;
601	<	double totalMass;
602	<	double totalMZ_local;
603	<	double totalMZ;
604	<	double massOfCurMol;
605	<	double COM[3];
606	<
607	<	totalMass_local = 0;
608	<	totalMZ_local = 0;
609	<
610	<	for(int i = 0; i < nMols; i++){
611	<	massOfCurMol = molecules[i].getTotalMass();
612	<	molecules[i].getCOM(COM);
613	<
614	<	totalMass_local += massOfCurMol;
615	<	totalMZ_local += massOfCurMol * COM[whichDirection];
616	<
617	<	}
618	<
619	<
620	<	#ifdef IS_MPI
621	<	MPI_Allreduce(&totalMass_local, &totalMass, 1,
622	<	MPI_DOUBLE, MPI_SUM, MPI_COMM_WORLD);
623	<	MPI_Allreduce(&totalMZ_local, &totalMZ, 1,
624	<	MPI_DOUBLE, MPI_SUM, MPI_COMM_WORLD);
625	<	#else
626	<	totalMass = totalMass_local;
627	<	totalMZ = totalMZ_local;
628	<	#endif
629	<
630	<	double zsys;
631	<	zsys = totalMZ / totalMass;
632	<
633	<	return zsys;
634	<	}
635	<
636	<	/**
637	<	*
638	<	*/
639	<	template<typename T> void ZConstraint<T>::thermalize( void ){
640	<
641	<	T::thermalize();
642	<	zeroOutVel();
643	<	}
644	<
645	<	/**
646	<	*
647	<	*/
648	<
649	<	template<typename T> void ZConstraint<T>::zeroOutVel(){
650	<
651	<	Atom** fixedZAtoms;
652	<	double COMvel[3];
653	<	double vel[3];
654	<	double zSysCOMVel;
655	<
656	<	//zero out the velocities of center of mass of fixed z-constrained molecules
657	<
658	<	for(int i = 0; i < zconsMols.size(); i++){
659	<
660	<	if (states[i] == zcsFixed){
661	<
662	<	zconsMols[i]->getCOMvel(COMvel);
663	<	//cout << "before resetting " << indexOfZConsMols[i] <<"'s vz is " << COMvel[whichDirection] << endl;
664	<
665	<	fixedZAtoms = zconsMols[i]->getMyAtoms();
666	<
667	<	for(int j =0; j < zconsMols[i]->getNAtoms(); j++){
668	<	fixedZAtoms[j]->getVel(vel);
669	<	vel[whichDirection] -= COMvel[whichDirection];
670	<	fixedZAtoms[j]->setVel(vel);
671	<	}
672	<
673	<	zconsMols[i]->getCOMvel(COMvel);
674	<	//cout << "after resetting " << indexOfZConsMols[i] <<"'s vz is " << COMvel[whichDirection] << endl;
675	<	}
676	<
677	<	}
678	<
679	<	//cout << "before resetting the COMVel of moving molecules is " << calcMovingMolsCOMVel() <<endl;
680	<
681	<	zSysCOMVel = calcSysCOMVel();
682	<	#ifdef IS_MPI
683	<	if(worldRank == 0){
684	<	#endif
685	<	//cout << "before resetting the COMVel of sytem is " << zSysCOMVel << endl;
686	<	#ifdef IS_MPI
687	<	}
688	<	#endif
689	<
690	<	// calculate the vz of center of mass of unconstrained molecules and moving z-constrained molecules
691	<	double MVzOfMovingMols_local;
692	<	double MVzOfMovingMols;
693	<	double totalMassOfMovingZMols_local;
694	<	double totalMassOfMovingZMols;
695	<
696	<	MVzOfMovingMols_local = 0;
697	<	totalMassOfMovingZMols_local = 0;
698	<
699	<	for(int i =0; i < unconsMols.size(); i++){
700	<	unconsMols[i]->getCOMvel(COMvel);
701	<	MVzOfMovingMols_local += massOfUnconsMols[i] * COMvel[whichDirection];
702	<	}
703	<
704	<	for(int i = 0; i < zconsMols.size(); i++){
705	<	if (states[i] == zcsMoving){
706	<	zconsMols[i]->getCOMvel(COMvel);
707	<	MVzOfMovingMols_local += massOfZConsMols[i] * COMvel[whichDirection];
708	<	totalMassOfMovingZMols_local += massOfZConsMols[i];
709	<	}
710	<
711	<	}
712	<
713	<	#ifndef IS_MPI
714	<	MVzOfMovingMols = MVzOfMovingMols_local;
715	<	totalMassOfMovingZMols = totalMassOfMovingZMols_local;
716	<	#else
717	<	MPI_Allreduce(&MVzOfMovingMols_local, &MVzOfMovingMols, 1, MPI_DOUBLE,MPI_SUM, MPI_COMM_WORLD);
718	<	MPI_Allreduce(&totalMassOfMovingZMols_local, &totalMassOfMovingZMols, 1, MPI_DOUBLE,MPI_SUM, MPI_COMM_WORLD);
719	<	#endif
720	<
721	<	double vzOfMovingMols;
722	<	vzOfMovingMols = MVzOfMovingMols / (totalMassOfUncons + totalMassOfMovingZMols);
723	<
724	<	//modify the velocites of unconstrained molecules
725	<	Atom** unconsAtoms;
726	<	for(int i = 0; i < unconsMols.size(); i++){
727	<
728	<	unconsAtoms = unconsMols[i]->getMyAtoms();
729	<	for(int j = 0; j < unconsMols[i]->getNAtoms();j++){
730	<	unconsAtoms[j]->getVel(vel);
731	<	vel[whichDirection] -= vzOfMovingMols;
732	<	unconsAtoms[j]->setVel(vel);
733	<	}
734	<
735	<	}
736	<
737	<	//modify the velocities of moving z-constrained molecuels
738	<	Atom** movingZAtoms;
739	<	for(int i = 0; i < zconsMols.size(); i++){
740	<
741	<	if (states[i] ==zcsMoving){
742	<
743	<	movingZAtoms = zconsMols[i]->getMyAtoms();
744	<	for(int j = 0; j < zconsMols[i]->getNAtoms(); j++){
745	<	movingZAtoms[j]->getVel(vel);
746	<	vel[whichDirection] -= vzOfMovingMols;
747	<	movingZAtoms[j]->setVel(vel);
748	<	}
749	<
750	<	}
751	<
752	<	}
753	<
754	<
755	<	zSysCOMVel = calcSysCOMVel();
756	<	#ifdef IS_MPI
757	<	if(worldRank == 0){
758	<	#endif
759	<	//cout << "after resetting the COMVel of moving molecules is " << zSysCOMVel << endl;
760	<	#ifdef IS_MPI
761	<	}
762	<	#endif
763	<
764	<	}
765	<
766	<	/**
767	<	*
768	<	*/
769	<
770	<	template<typename T> void ZConstraint<T>::doZconstraintForce(){
771	<
772	<	Atom** zconsAtoms;
773	<	double totalFZ;
774	<	double totalFZ_local;
775	<	double COMvel[3];
776	<	double COM[3];
777	<	double force[3];
778	<
779	<	//constrain the molecules which do not reach the specified positions
780	<
781	<	//Zero Out the force of z-contrained molecules
782	<	totalFZ_local = 0;
783	<
784	<	//calculate the total z-contrained force of fixed z-contrained molecules
785	<
786	<	//cout << "before zero out z-constraint force on fixed z-constraint molecuels "
787	<	//       << "total force is " << calcTotalForce() << endl;
788	<
789	<	for(int i = 0; i < zconsMols.size(); i++){
790	<
791	<	if (states[i] == zcsFixed){
792	<
793	<	zconsMols[i]->getCOM(COM);
794	<	zconsAtoms = zconsMols[i]->getMyAtoms();
795	<
796	<	fz[i] = 0;
797	<	for(int j =0; j < zconsMols[i]->getNAtoms(); j++) {
798	<	zconsAtoms[j]->getFrc(force);
799	<	fz[i] += force[whichDirection];
800	<	}
801	<	totalFZ_local += fz[i];
802	<
803	<	//cout << "Fixed Molecule\tindex: " << indexOfZConsMols[i]
804	<	//      <<"\tcurrent zpos: " << COM[whichDirection]
805	<	//      << "\tcurrent fz: " <<fz[i] << endl;
806	<
807	<
808	<	}
809	<
810	<	}
811	<
812	<	//calculate total z-constraint force
813	<	#ifdef IS_MPI
814	<	MPI_Allreduce(&totalFZ_local, &totalFZ, 1, MPI_DOUBLE,MPI_SUM, MPI_COMM_WORLD);
815	<	#else
816	<	totalFZ = totalFZ_local;
817	<	#endif
818	<
819	<
820	<	// apply negative to fixed z-constrained molecues;
821	<	force[0]= 0;
822	<	force[1]= 0;
823	<	force[2]= 0;
824	<
825	<	for(int i = 0; i < zconsMols.size(); i++){
826	<
827	<	if (states[i] == zcsFixed){
828	<
829	<	int nAtomOfCurZConsMol = zconsMols[i]->getNAtoms();
830	<	zconsAtoms = zconsMols[i]->getMyAtoms();
831	<
832	<	for(int j =0; j < nAtomOfCurZConsMol; j++) {
833	<	//force[whichDirection] = -fz[i]/ nAtomOfCurZConsMol;
834	<	force[whichDirection] = - forcePolicy->getZFOfFixedZMols(zconsMols[i], zconsAtoms[j], fz[i]);
835	<	zconsAtoms[j]->addFrc(force);
836	<	}
837	<
838	<	}
839	<
840	<	}
841	<
842	<	//cout << "after zero out z-constraint force on fixed z-constraint molecuels "
843	<	//      << "total force is " << calcTotalForce() << endl;
844	<
845	<
846	<	force[0]= 0;
847	<	force[1]= 0;
848	<	force[2]= 0;
849	<
850	<	//modify the forces of unconstrained molecules
851	<	for(int i = 0; i < unconsMols.size(); i++){
852	<
853	<	Atom** unconsAtoms = unconsMols[i]->getMyAtoms();
854	<
855	<	for(int j = 0; j < unconsMols[i]->getNAtoms(); j++){
856	<	//force[whichDirection] = totalFZ / (totNumOfUnconsAtoms + nMovingZAtoms);
857	<	force[whichDirection] = forcePolicy->getZFOfMovingMols(unconsAtoms[j],totalFZ);
858	<	unconsAtoms[j]->addFrc(force);
859	<	}
860	<
861	<	}
862	<
863	<	//modify the forces of moving z-constrained molecules
864	<	for(int i = 0; i < zconsMols.size(); i++) {
865	<	if (states[i] == zcsMoving){
866	<
867	<	Atom** movingZAtoms = zconsMols[i]->getMyAtoms();
868	<
869	<	for(int j = 0; j < zconsMols[i]->getNAtoms(); j++){
870	<	//force[whichDirection] = totalFZ / (totNumOfUnconsAtoms + nMovingZAtoms);
871	<	force[whichDirection] = forcePolicy->getZFOfMovingMols(movingZAtoms[j],totalFZ);
872	<	movingZAtoms[j]->addFrc(force);
873	<	}
874	<	}
875	<	}
876	<	//  cout << "after substracting z-constraint force from moving molecuels "
877	<	//        << "total force is " << calcTotalForce()  << endl;
878	<
879	<	}
880	<
881	<	/**
882	<	*
883	<	*
884	<	*/
885	<
886	<	template<typename T> void ZConstraint<T>::doHarmonic(){
887	<	double force[3];
888	<	double harmonicU;
889	<	double harmonicF;
890	<	double COM[3];
891	<	double diff;
892	<	double totalFZ_local;
893	<	double totalFZ;
894	<
895	<	force[0] = 0;
896	<	force[1] = 0;
897	<	force[2] = 0;
898	<
899	<	totalFZ_local = 0;
900	<
901	<	for(int i = 0; i < zconsMols.size(); i++) {
902	<
903	<	if (states[i] == zcsMoving){
904	<	zconsMols[i]->getCOM(COM);
905	<	//       cout << "Moving Molecule\tindex: " << indexOfZConsMols[i]
906	<	//         << "\tcurrent zpos: " << COM[whichDirection] << endl;
907	<
908	<	diff = COM[whichDirection] -zPos[i];
909	<
910	<	harmonicU = 0.5 * kz[i] * diff * diff;
911	<	info->lrPot += harmonicU;
912	<
913	<	harmonicF =  - kz[i] * diff;
914	<	totalFZ_local += harmonicF;
915	<
916	<	//adjust force
917	<
918	<	Atom** movingZAtoms = zconsMols[i]->getMyAtoms();
919	<
920	<	for(int j = 0; j < zconsMols[i]->getNAtoms(); j++){
921	<	//force[whichDirection] = harmonicF / zconsMols[i]->getNAtoms();
922	<	force[whichDirection] = forcePolicy->getHFOfFixedZMols(zconsMols[i], movingZAtoms[j], harmonicF);
923	<	movingZAtoms[j]->addFrc(force);
924	<	}
925	<	}
926	<
927	<	}
928	<
929	<	#ifndef IS_MPI
930	<	totalFZ = totalFZ_local;
931	<	#else
932	<	MPI_Allreduce(&totalFZ_local, &totalFZ, 1, MPI_DOUBLE,MPI_SUM, MPI_COMM_WORLD);
933	<	#endif
934	<
935	<	cout << "before substracting harmonic force from moving molecuels "
936	<	<< "total force is " << calcTotalForce()  << endl;
937	<
938	<	force[0]= 0;
939	<	force[1]= 0;
940	<	force[2]= 0;
941	<
942	<	//modify the forces of unconstrained molecules
943	<	for(int i = 0; i < unconsMols.size(); i++){
944	<
945	<	Atom** unconsAtoms = unconsMols[i]->getMyAtoms();
946	<
947	<	for(int j = 0; j < unconsMols[i]->getNAtoms(); j++){
948	<	//force[whichDirection] = - totalFZ /totNumOfUnconsAtoms;
949	<	force[whichDirection] = - forcePolicy->getHFOfUnconsMols(unconsAtoms[j], totalFZ);
950	<	unconsAtoms[j]->addFrc(force);
951	<	}
952	<	}
953	<
954	<	cout << "after substracting harmonic force from moving molecuels "
955	<	<< "total force is " << calcTotalForce()  << endl;
956	<
957	<	}
958	<
959	<	/**
960	<	*
961	<	*/
962	<
963	<	template<typename T> bool ZConstraint<T>::checkZConsState(){
964	<	double COM[3];
965	<	double diff;
966	<
967	<	int changed_local;
968	<	int changed;
969	<
970	<	changed_local = 0;
971	<
972	<	for(int i =0; i < zconsMols.size(); i++){
973	<
974	<	zconsMols[i]->getCOM(COM);
975	<	diff = fabs(COM[whichDirection] - zPos[i]);
976	<	if (  diff <= zconsTol && states[i] == zcsMoving){
977	<	states[i] = zcsFixed;
978	<	changed_local = 1;
979	<	}
980	<	else if ( diff > zconsTol && states[i] == zcsFixed){
981	<	states[i] = zcsMoving;
982	<	changed_local = 1;
983	<	}
984	<
985	<	}
986	<
987	<	#ifndef IS_MPI
988	<	changed =changed_local;
989	<	#else
990	<	MPI_Allreduce(&changed_local, &changed, 1, MPI_INT,MPI_SUM, MPI_COMM_WORLD);
991	<	#endif
992	<
993	<	return (changed > 0);
994	<
995	<	}
996	<
997	<	template<typename T> bool ZConstraint<T>::haveFixedZMols(){
998	<
999	<	int havingFixed_local;
1000	<	int havingFixed;
1001	<
1002	<	havingFixed_local = 0;
1003	<
1004	<	for(int i = 0; i < zconsMols.size(); i++)
1005	<	if (states[i] == zcsFixed){
1006	<	havingFixed_local = 1;
1007	<	break;
1008	<	}
1009	<
1010	<	#ifndef IS_MPI
1011	<	havingFixed = havingFixed_local;
1012	<	#else
1013	<	MPI_Allreduce(&havingFixed_local, &havingFixed, 1, MPI_INT,MPI_SUM, MPI_COMM_WORLD);
1014	<	#endif
1015	<
1016	<	return (havingFixed > 0);
1017	<	}
1018	<
1019	<
1020	<	/**
1021	<	*
1022	<	*/
1023	<	template<typename T> bool ZConstraint<T>::haveMovingZMols(){
1024	<
1025	<	int havingMoving_local;
1026	<	int havingMoving;
1027	<
1028	<	havingMoving_local = 0;
1029	<
1030	<	for(int i = 0; i < zconsMols.size(); i++)
1031	<	if (states[i] == zcsMoving){
1032	<	havingMoving_local = 1;
1033	<	break;
1034	<	}
1035	<
1036	<	#ifndef IS_MPI
1037	<	havingMoving = havingMoving_local;
1038	<	#else
1039	<	MPI_Allreduce(&havingMoving_local, &havingMoving, 1, MPI_INT,MPI_SUM, MPI_COMM_WORLD);
1040	<	#endif
1041	<
1042	<	return (havingMoving > 0);
1043	<
1044	<	}
1045	<
1046	<	/**
1047	<	*
1048	<	*/
1049	<
1050	<	template<typename T> double ZConstraint<T>::calcMovingMolsCOMVel()
1051	<	{
1052	<	double MVzOfMovingMols_local;
1053	<	double MVzOfMovingMols;
1054	<	double totalMassOfMovingZMols_local;
1055	<	double totalMassOfMovingZMols;
1056	<	double COMvel[3];
1057	<
1058	<	MVzOfMovingMols_local = 0;
1059	<	totalMassOfMovingZMols_local = 0;
1060	<
1061	<	for(int i =0; i < unconsMols.size(); i++){
1062	<	unconsMols[i]->getCOMvel(COMvel);
1063	<	MVzOfMovingMols_local += massOfUnconsMols[i] * COMvel[whichDirection];
1064	<	}
1065	<
1066	<	for(int i = 0; i < zconsMols.size(); i++){
1067	<
1068	<	if (states[i] == zcsMoving){
1069	<	zconsMols[i]->getCOMvel(COMvel);
1070	<	MVzOfMovingMols_local += massOfZConsMols[i] * COMvel[whichDirection];
1071	<	totalMassOfMovingZMols_local += massOfZConsMols[i];
1072	<	}
1073	<
1074	<	}
1075	<
1076	<	#ifndef IS_MPI
1077	<	MVzOfMovingMols = MVzOfMovingMols_local;
1078	<	totalMassOfMovingZMols = totalMassOfMovingZMols_local;
1079	<	#else
1080	<	MPI_Allreduce(&MVzOfMovingMols_local, &MVzOfMovingMols, 1, MPI_DOUBLE,MPI_SUM, MPI_COMM_WORLD);
1081	<	MPI_Allreduce(&totalMassOfMovingZMols_local, &totalMassOfMovingZMols, 1, MPI_DOUBLE,MPI_SUM, MPI_COMM_WORLD);
1082	<	#endif
1083	<
1084	<	double vzOfMovingMols;
1085	<	vzOfMovingMols = MVzOfMovingMols / (totalMassOfUncons + totalMassOfMovingZMols);
1086	<
1087	<	return vzOfMovingMols;
1088	<	}
1089	<
1090	<	/**
1091	<	*
1092	<	*/
1093	<
1094	<	template<typename T> double ZConstraint<T>::calcSysCOMVel()
1095	<	{
1096	<	double COMvel[3];
1097	<	double tempMVz_local;
1098	<	double tempMVz;
1099	<	double massOfZCons_local;
1100	<	double massOfZCons;
1101	<
1102	<
1103	<	tempMVz_local = 0;
1104	<
1105	<	for(int i =0 ; i < nMols; i++){
1106	<	molecules[i].getCOMvel(COMvel);
1107	<	tempMVz_local += molecules[i].getTotalMass()*COMvel[whichDirection];
1108	<	}
1109	<
1110	<	massOfZCons_local = 0;
1111	<
1112	<	for(int i = 0; i < massOfZConsMols.size(); i++){
1113	<	massOfZCons_local += massOfZConsMols[i];
1114	<	}
1115	<	#ifndef IS_MPI
1116	<	massOfZCons = massOfZCons_local;
1117	<	tempMVz = tempMVz_local;
1118	<	#else
1119	<	MPI_Allreduce(&massOfZCons_local, &massOfZCons, 1, MPI_DOUBLE,MPI_SUM, MPI_COMM_WORLD);
1120	<	MPI_Allreduce(&tempMVz_local, &tempMVz, 1, MPI_DOUBLE,MPI_SUM, MPI_COMM_WORLD);
1121	<	#endif
1122	<
1123	<	return tempMVz /(totalMassOfUncons + massOfZCons);
1124	<	}
1125	<
1126	<	/**
1127	<	*
1128	<	*/
1129	<
1130	<	template<typename T> double ZConstraint<T>::calcTotalForce(){
1131	<
1132	<	double force[3];
1133	<	double totalForce_local;
1134	<	double totalForce;
1135	<
1136	<	totalForce_local = 0;
1137	<
1138	<	for(int i = 0; i < nAtoms; i++){
1139	<	atoms[i]->getFrc(force);
1140	<	totalForce_local += force[whichDirection];
1141	<	}
1142	<
1143	<	#ifndef IS_MPI
1144	<	totalForce = totalForce_local;
1145	<	#else
1146	<	MPI_Allreduce(&totalForce_local, &totalForce, 1, MPI_DOUBLE,MPI_SUM, MPI_COMM_WORLD);
1147	<	#endif
1148	<
1149	<	return totalForce;
1150	<
1151	<	}
1152	<
1153	<	/**
1154	<	*
1155	<	*/
1156	<
1157	<	template<typename T> void ZConstraint<T>::PolicyByNumber::update(){
1158	<	//calculate the number of atoms of moving z-constrained molecules
1159	<	int nMovingZAtoms_local;
1160	<	int nMovingZAtoms;
1161	<
1162	<	nMovingZAtoms_local = 0;
1163	<	for(int i = 0; i < (zconsIntegrator->zconsMols).size(); i++)
1164	<	if((zconsIntegrator->states)[i] == (zconsIntegrator->zcsMoving))
1165	<	nMovingZAtoms_local += (zconsIntegrator->zconsMols)[i]->getNAtoms();
1166	<
1167	<	#ifdef IS_MPI
1168	<	MPI_Allreduce(&nMovingZAtoms_local, &nMovingZAtoms, 1, MPI_INT, MPI_SUM, MPI_COMM_WORLD);
1169	<	#else
1170	<	nMovingZAtoms = nMovingZAtoms_local;
1171	<	#endif
1172	<	totNumOfMovingAtoms = nMovingZAtoms + zconsIntegrator->totNumOfUnconsAtoms;
1173	<	}
1174	<
1175	<	template<typename T>double ZConstraint<T>::PolicyByNumber::getZFOfFixedZMols(Molecule* mol, Atom* atom, double totalForce){
1176	<	return totalForce / mol->getNAtoms();
1177	<	}
1178	<
1179	<	template<typename T> double ZConstraint<T>::PolicyByNumber::getZFOfMovingMols(Atom* atom, double totalForce){
1180	<	return totalForce / totNumOfMovingAtoms;
1181	<	}
1182	<
1183	<	template<typename T> double ZConstraint<T>::PolicyByNumber::getHFOfFixedZMols(Molecule* mol, Atom* atom, double totalForce){
1184	<	return totalForce / mol->getNAtoms();
1185	<	}
1186	<
1187	<	template<typename T> double ZConstraint<T>::PolicyByNumber::getHFOfUnconsMols(Atom* atom, double totalForce){
1188	<	return totalForce / zconsIntegrator->totNumOfUnconsAtoms;
1189	<	}
1190	<
1191	<	/**
1192	<	*
1193	<	*/
1194	<
1195	<	template<typename T> void ZConstraint<T>::PolicyByMass::update(){
1196	<	//calculate the number of atoms of moving z-constrained molecules
1197	<	double massOfMovingZAtoms_local;
1198	<	double massOfMovingZAtoms;
1199	<
1200	<	massOfMovingZAtoms_local = 0;
1201	<	for(int i = 0; i < (zconsIntegrator->zconsMols).size(); i++)
1202	<	if((zconsIntegrator->states)[i] == (zconsIntegrator->zcsMoving))
1203	<	massOfMovingZAtoms_local += (zconsIntegrator->zconsMols)[i]->getTotalMass();
1204	<
1205	<	#ifdef IS_MPI
1206	<	MPI_Allreduce(&massOfMovingZAtoms_local, &massOfMovingZAtoms, 1, MPI_DOUBLE,MPI_SUM, MPI_COMM_WORLD);
1207	<	#else
1208	<	massOfMovingZAtoms = massOfMovingZAtoms_local;
1209	<	#endif
1210	<	totMassOfMovingAtoms = massOfMovingZAtoms + zconsIntegrator->totalMassOfUncons;
1211	<	}
1212	<
1213	<	template<typename T> double ZConstraint<T>::PolicyByMass::getZFOfFixedZMols(Molecule* mol, Atom* atom, double totalForce){
1214	<	return totalForce * atom->getMass() / mol->getTotalMass();
1215	<	}
1216	<
1217	<	template<typename T> double ZConstraint<T>::PolicyByMass::getZFOfMovingMols( Atom* atom, double totalForce){
1218	<	return totalForce * atom->getMass() / totMassOfMovingAtoms;
1219	<	}
1220	<
1221	<	template<typename T> double ZConstraint<T>::PolicyByMass::getHFOfFixedZMols(Molecule* mol, Atom* atom, double totalForce){
1222	<	return totalForce * atom->getMass() / mol->getTotalMass();
1223	<	}
1224	<
1225	<	template<typename T> double ZConstraint<T>::PolicyByMass::getHFOfUnconsMols(Atom* atom, double totalForce){
1226	<	return totalForce * atom->getMass() / zconsIntegrator->totalMassOfUncons;
1227	<	}
1228	<
1	>	#include "Integrator.hpp"
2	>	#include "simError.h"
3	>	#include <math.h>
4	>
5	>	const double INFINITE_TIME = 10e30;
6	>	template<typename T> ZConstraint<T>::ZConstraint(SimInfo* theInfo,
7	>	ForceFields* the_ff): T(theInfo, the_ff),
8	>	fzOut(NULL),
9	>	curZconsTime(0),
10	>	forcePolicy(NULL),
11	>	usingSMD(false),
12	>	hasZConsGap(false){
13	>	//get properties from SimInfo
14	>	GenericData* data;
15	>	ZConsParaData* zConsParaData;
16	>	DoubleData* sampleTime;
17	>	DoubleData* tolerance;
18	>	DoubleData* gap;
19	>	DoubleData* fixtime;
20	>	StringData* policy;
21	>	StringData* filename;
22	>	IntData* smdFlag;
23	>	double COM[3];
24	>
25	>	//by default, the direction of constraint is z
26	>	// 0 --> x
27	>	// 1 --> y
28	>	// 2 --> z
29	>	whichDirection = 2;
30	>
31	>	//estimate the force constant of harmonical potential
32	>	double Kb = 1.986E-3 ; //in kcal/K
33	>
34	>	double halfOfLargestBox = max(info->boxL[0], max(info->boxL[1], info->boxL[2])) /
35	>	2;
36	>	zForceConst = Kb * info->target_temp / (halfOfLargestBox * halfOfLargestBox);
37	>
38	>	//creat force Subtraction policy
39	>	data = info->getProperty(ZCONSFORCEPOLICY_ID);
40	>	if (!data){
41	>	sprintf(painCave.errMsg,
42	>	"ZConstraint Warning: User does not set force Subtraction policy, "
43	>	"PolicyByMass is used\n");
44	>	painCave.isFatal = 0;
45	>	simError();
46	>
47	>	forcePolicy = (ForceSubtractionPolicy *) new PolicyByMass(this);
48	>	}
49	>	else{
50	>	policy = dynamic_cast<StringData*>(data);
51	>
52	>	if (!policy){
53	>	sprintf(painCave.errMsg,
54	>	"ZConstraint Error: Convertion from GenericData to StringData failure, "
55	>	"PolicyByMass is used\n");
56	>	painCave.isFatal = 0;
57	>	simError();
58	>
59	>	forcePolicy = (ForceSubtractionPolicy *) new PolicyByMass(this);
60	>	}
61	>	else{
62	>	if (policy->getData() == "BYNUMBER")
63	>	forcePolicy = (ForceSubtractionPolicy *) new PolicyByNumber(this);
64	>	else if (policy->getData() == "BYMASS")
65	>	forcePolicy = (ForceSubtractionPolicy *) new PolicyByMass(this);
66	>	else{
67	>	sprintf(painCave.errMsg,
68	>	"ZConstraint Warning: unknown force Subtraction policy, "
69	>	"PolicyByMass is used\n");
70	>	painCave.isFatal = 0;
71	>	simError();
72	>	forcePolicy = (ForceSubtractionPolicy *) new PolicyByMass(this);
73	>	}
74	>	}
75	>	}
76	>
77	>
78	>	//retrieve sample time of z-contraint
79	>	data = info->getProperty(ZCONSTIME_ID);
80	>
81	>	if (!data){
82	>	sprintf(painCave.errMsg,
83	>	"ZConstraint error: If you use an ZConstraint\n"
84	>	" , you must set sample time.\n");
85	>	painCave.isFatal = 1;
86	>	simError();
87	>	}
88	>	else{
89	>	sampleTime = dynamic_cast<DoubleData*>(data);
90	>
91	>	if (!sampleTime){
92	>	sprintf(painCave.errMsg,
93	>	"ZConstraint error: Can not get property from SimInfo\n");
94	>	painCave.isFatal = 1;
95	>	simError();
96	>	}
97	>	else{
98	>	this->zconsTime = sampleTime->getData();
99	>	}
100	>	}
101	>
102	>	//retrieve output filename of z force
103	>	data = info->getProperty(ZCONSFILENAME_ID);
104	>	if (!data){
105	>	sprintf(painCave.errMsg,
106	>	"ZConstraint error: If you use an ZConstraint\n"
107	>	" , you must set output filename of z-force.\n");
108	>	painCave.isFatal = 1;
109	>	simError();
110	>	}
111	>	else{
112	>	filename = dynamic_cast<StringData*>(data);
113	>
114	>	if (!filename){
115	>	sprintf(painCave.errMsg,
116	>	"ZConstraint error: Can not get property from SimInfo\n");
117	>	painCave.isFatal = 1;
118	>	simError();
119	>	}
120	>	else{
121	>	this->zconsOutput = filename->getData();
122	>	}
123	>	}
124	>
125	>	//retrieve tolerance for z-constraint molecuels
126	>	data = info->getProperty(ZCONSTOL_ID);
127	>
128	>	if (!data){
129	>	sprintf(painCave.errMsg, "ZConstraint error: can not get tolerance \n");
130	>	painCave.isFatal = 1;
131	>	simError();
132	>	}
133	>	else{
134	>	tolerance = dynamic_cast<DoubleData*>(data);
135	>
136	>	if (!tolerance){
137	>	sprintf(painCave.errMsg,
138	>	"ZConstraint error: Can not get property from SimInfo\n");
139	>	painCave.isFatal = 1;
140	>	simError();
141	>	}
142	>	else{
143	>	this->zconsTol = tolerance->getData();
144	>	}
145	>	}
146	>
147	>	//quick hack here
148	>	data = info->getProperty(ZCONSGAP_ID);
149	>
150	>	if (data){
151	>	gap = dynamic_cast<DoubleData*>(data);
152	>
153	>	if (!gap){
154	>	sprintf(painCave.errMsg,
155	>	"ZConstraint error: Can not get property from SimInfo\n");
156	>	painCave.isFatal = 1;
157	>	simError();
158	>	}
159	>	else{
160	>	this->hasZConsGap = true;
161	>	this->zconsGap = gap->getData();
162	>	}
163	>	}
164	>
165	>
166	>
167	>	data = info->getProperty(ZCONSFIXTIME_ID);
168	>
169	>	if (data){
170	>	fixtime = dynamic_cast<DoubleData*>(data);
171	>	if (!fixtime){
172	>	sprintf(painCave.errMsg,
173	>	"ZConstraint error: Can not get zconsFixTime from SimInfo\n");
174	>	painCave.isFatal = 1;
175	>	simError();
176	>	}
177	>	else{
178	>	this->zconsFixTime = fixtime->getData();
179	>	}
180	>	}
181	>	else if(hasZConsGap){
182	>	sprintf(painCave.errMsg,
183	>	"ZConstraint error: must set fixtime if already set zconsGap\n");
184	>	painCave.isFatal = 1;
185	>	simError();
186	>	}
187	>
188	>
189	>
190	>	data = info->getProperty(ZCONSUSINGSMD_ID);
191	>
192	>	if (data){
193	>	smdFlag = dynamic_cast<IntData*>(data);
194	>
195	>	if (!smdFlag){
196	>	sprintf(painCave.errMsg,
197	>	"ZConstraint error: Can not get property from SimInfo\n");
198	>	painCave.isFatal = 1;
199	>	simError();
200	>	}
201	>	else{
202	>	this->usingSMD= smdFlag->getData() ? true : false;
203	>	}
204	>
205	>	}
206	>
207	>
208	>
209	>	//retrieve index of z-constraint molecules
210	>	data = info->getProperty(ZCONSPARADATA_ID);
211	>	if (!data){
212	>	sprintf(painCave.errMsg,
213	>	"ZConstraint error: If you use an ZConstraint\n"
214	>	" , you must set index of z-constraint molecules.\n");
215	>	painCave.isFatal = 1;
216	>	simError();
217	>	}
218	>	else{
219	>	zConsParaData = dynamic_cast<ZConsParaData*>(data);
220	>
221	>	if (!zConsParaData){
222	>	sprintf(painCave.errMsg,
223	>	"ZConstraint error: Can not get parameters of zconstraint method from SimInfo\n");
224	>	painCave.isFatal = 1;
225	>	simError();
226	>	}
227	>	else{
228	>	parameters = zConsParaData->getData();
229	>
230	>	//check the range of zconsIndex
231	>	//and the minimum value of index is the first one (we already sorted the data)
232	>	//the maximum value of index is the last one
233	>
234	>	int maxIndex;
235	>	int minIndex;
236	>	int totalNumMol;
237	>
238	>	minIndex = (*parameters)[0].zconsIndex;
239	>	if (minIndex < 0){
240	>	sprintf(painCave.errMsg, "ZConstraint error: index is out of range\n");
241	>	painCave.isFatal = 1;
242	>	simError();
243	>	}
244	>
245	>	maxIndex = (*parameters)[parameters->size() - 1].zconsIndex;
246	>
247	>	#ifndef IS_MPI
248	>	totalNumMol = nMols;
249	>	#else
250	>	totalNumMol = mpiSim->getTotNmol();
251	>	#endif
252	>
253	>	if (maxIndex > totalNumMol - 1){
254	>	sprintf(painCave.errMsg, "ZConstraint error: index is out of range\n");
255	>	painCave.isFatal = 1;
256	>	simError();
257	>	}
258	>
259	>	//if user does not specify the zpos for the zconstraint molecule
260	>	//its initial z coordinate  will be used as default
261	>	for (int i = 0; i < (int) (parameters->size()); i++){
262	>	if (!(*parameters)[i].havingZPos){
263	>	#ifndef IS_MPI
264	>	for (int j = 0; j < nMols; j++){
265	>	if (molecules[j].getGlobalIndex() == (*parameters)[i].zconsIndex){
266	>	molecules[j].getCOM(COM);
267	>	break;
268	>	}
269	>	}
270	>	#else
271	>	//query which processor current zconstraint molecule belongs to
272	>	int* MolToProcMap;
273	>	int whichNode;
274	>
275	>	MolToProcMap = mpiSim->getMolToProcMap();
276	>	whichNode = MolToProcMap[(*parameters)[i].zconsIndex];
277	>
278	>	//broadcast the zpos of current z-contraint molecule
279	>	//the node which contain this
280	>
281	>	if (worldRank == whichNode){
282	>	for (int j = 0; j < nMols; j++)
283	>	if (molecules[j].getGlobalIndex() == (*parameters)[i].zconsIndex){
284	>	molecules[j].getCOM(COM);
285	>	break;
286	>	}
287	>	}
288	>
289	>	MPI_Bcast(&COM[whichDirection], 1, MPI_DOUBLE, whichNode,
290	>	MPI_COMM_WORLD);
291	>	#endif
292	>
293	>	(*parameters)[i].zPos = COM[whichDirection];
294	>
295	>	sprintf(painCave.errMsg,
296	>	"ZConstraint warning: Does not specify zpos for z-constraint molecule "
297	>	"initial z coornidate will be used \n");
298	>	painCave.isFatal = 0;
299	>	simError();
300	>	}
301	>	}
302	>	}//end if (!zConsParaData)
303	>
304	>	}//end  if (!data)
305	>
306	>	//
307	>	#ifdef IS_MPI
308	>	update();
309	>	#else
310	>	int searchResult;
311	>
312	>	for (int i = 0; i < nMols; i++){
313	>	searchResult = isZConstraintMol(&molecules[i]);
314	>
315	>	if (searchResult > -1){
316	>	zconsMols.push_back(&molecules[i]);
317	>	massOfZConsMols.push_back(molecules[i].getTotalMass());
318	>
319	>	zPos.push_back((*parameters)[searchResult].zPos);
320	>	kz.push_back((*parameters)[searchResult]. kRatio * zForceConst);
321	>
322	>	if(usingSMD)
323	>	cantVel.push_back((*parameters)[searchResult].cantVel);
324	>
325	>	}
326	>	else{
327	>	unconsMols.push_back(&molecules[i]);
328	>	massOfUnconsMols.push_back(molecules[i].getTotalMass());
329	>	}
330	>	}
331	>
332	>	fz.resize(zconsMols.size());
333	>	curZPos.resize(zconsMols.size());
334	>	indexOfZConsMols.resize(zconsMols.size());
335	>
336	>	//determine the states of z-constraint molecules
337	>	for (size_t i = 0; i < zconsMols.size(); i++){
338	>	indexOfZConsMols[i] = zconsMols[i]->getGlobalIndex();
339	>
340	>	zconsMols[i]->getCOM(COM);
341	>
342	>	if (fabs(zPos[i] - COM[whichDirection]) < zconsTol){
343	>	states.push_back(zcsFixed);
344	>
345	>	if (hasZConsGap)
346	>	endFixTime.push_back(info->getTime() + zconsFixTime);
347	>	}
348	>	else{
349	>	states.push_back(zcsMoving);
350	>
351	>	if (hasZConsGap)
352	>	endFixTime.push_back(INFINITE_TIME);
353	>	}
354	>
355	>	if(usingSMD)
356	>	cantPos.push_back(COM[whichDirection]);
357	>	}
358	>
359	>	#endif
360	>
361	>
362	>	//get total masss of unconstraint molecules
363	>	double totalMassOfUncons_local;
364	>	totalMassOfUncons_local = 0;
365	>
366	>	for (size_t i = 0; i < unconsMols.size(); i++)
367	>	totalMassOfUncons_local += unconsMols[i]->getTotalMass();
368	>
369	>	#ifndef IS_MPI
370	>	totalMassOfUncons = totalMassOfUncons_local;
371	>	#else
372	>	MPI_Allreduce(&totalMassOfUncons_local, &totalMassOfUncons, 1, MPI_DOUBLE,
373	>	MPI_SUM, MPI_COMM_WORLD);
374	>	#endif
375	>
376	>	//get total number of unconstrained atoms
377	>	int nUnconsAtoms_local;
378	>	nUnconsAtoms_local = 0;
379	>	for (int i = 0; i < (int) (unconsMols.size()); i++)
380	>	nUnconsAtoms_local += unconsMols[i]->getNAtoms();
381	>
382	>	#ifndef IS_MPI
383	>	totNumOfUnconsAtoms = nUnconsAtoms_local;
384	>	#else
385	>	MPI_Allreduce(&nUnconsAtoms_local, &totNumOfUnconsAtoms, 1, MPI_INT, MPI_SUM,
386	>	MPI_COMM_WORLD);
387	>	#endif
388	>
389	>	forcePolicy->update();
390	>	}
391	>
392	>	template<typename T> ZConstraint<T>::~ZConstraint(){
393	>
394	>	if (fzOut){
395	>	delete fzOut;
396	>	}
397	>
398	>	if (forcePolicy){
399	>	delete forcePolicy;
400	>	}
401	>	}
402	>
403	>
404	>	/**
405	>	*
406	>	*/
407	>
408	>	#ifdef IS_MPI
409	>	template<typename T> void ZConstraint<T>::update(){
410	>	double COM[3];
411	>	int index;
412	>
413	>	zconsMols.clear();
414	>	massOfZConsMols.clear();
415	>	zPos.clear();
416	>	kz.clear();
417	>	cantPos.clear();
418	>	cantVel.clear();
419	>
420	>	unconsMols.clear();
421	>	massOfUnconsMols.clear();
422	>
423	>
424	>	//creat zconsMol and unconsMol lists
425	>	for (int i = 0; i < nMols; i++){
426	>	index = isZConstraintMol(&molecules[i]);
427	>
428	>	if (index > -1){
429	>	zconsMols.push_back(&molecules[i]);
430	>	zPos.push_back((*parameters)[index].zPos);
431	>	kz.push_back((*parameters)[index].kRatio * zForceConst);
432	>	massOfZConsMols.push_back(molecules[i].getTotalMass());
433	>
434	>	if(usingSMD)
435	>	cantVel.push_back((*parameters)[index].cantVel);
436	>
437	>	}
438	>	else{
439	>	unconsMols.push_back(&molecules[i]);
440	>	massOfUnconsMols.push_back(molecules[i].getTotalMass());
441	>	}
442	>	}
443	>
444	>	fz.resize(zconsMols.size());
445	>	curZPos.resize(zconsMols.size());
446	>	indexOfZConsMols.resize(zconsMols.size());
447	>
448	>	for (size_t i = 0; i < zconsMols.size(); i++){
449	>	indexOfZConsMols[i] = zconsMols[i]->getGlobalIndex();
450	>	}
451	>
452	>	//determine the states of z-constraint molecules
453	>	for (int i = 0; i < (int) (zconsMols.size()); i++){
454	>
455	>	zconsMols[i]->getCOM(COM);
456	>
457	>	if (fabs(zPos[i] - COM[whichDirection]) < zconsTol){
458	>	states.push_back(zcsFixed);
459	>
460	>	if (hasZConsGap)
461	>	endFixTime.push_back(info->getTime() + zconsFixTime);
462	>	}
463	>	else{
464	>	states.push_back(zcsMoving);
465	>
466	>	if (hasZConsGap)
467	>	endFixTime.push_back(INFINITE_TIME);
468	>	}
469	>
470	>	if(usingSMD)
471	>	cantPos.push_back(COM[whichDirection]);
472	>	}
473	>	//
474	>	forcePolicy->update();
475	>	}
476	>
477	>	#endif
478	>
479	>	/**
480	>	*  Function Name: isZConstraintMol
481	>	*  Parameter
482	>	*    Molecule* mol
483	>	*  Return value:
484	>	*    -1, if the molecule is not z-constraint molecule,
485	>	*    other non-negative values, its index in indexOfAllZConsMols vector
486	>	*/
487	>
488	>	template<typename T> int ZConstraint<T>::isZConstraintMol(Molecule* mol){
489	>	int index;
490	>	int low;
491	>	int high;
492	>	int mid;
493	>
494	>	index = mol->getGlobalIndex();
495	>
496	>	low = 0;
497	>	high = parameters->size() - 1;
498	>
499	>	//Binary Search (we have sorted the array)
500	>	while (low <= high){
501	>	mid = (low + high) / 2;
502	>	if ((*parameters)[mid].zconsIndex == index)
503	>	return mid;
504	>	else if ((*parameters)[mid].zconsIndex > index)
505	>	high = mid - 1;
506	>	else
507	>	low = mid + 1;
508	>	}
509	>
510	>	return -1;
511	>	}
512	>
513	>	template<typename T> void ZConstraint<T>::integrate(){
514	>	// creat zconsWriter
515	>	fzOut = new ZConsWriter(zconsOutput.c_str(), parameters);
516	>
517	>	if (!fzOut){
518	>	sprintf(painCave.errMsg, "Memory allocation failure in class Zconstraint\n");
519	>	painCave.isFatal = 1;
520	>	simError();
521	>	}
522	>
523	>	//zero out the velocities of center of mass of unconstrained molecules
524	>	//and the velocities of center of mass of every single z-constrained molecueles
525	>	zeroOutVel();
526	>
527	>	curZconsTime = zconsTime + info->getTime();
528	>
529	>	T::integrate();
530	>	}
531	>
532	>
533	>	/**
534	>	*
535	>	*
536	>	*
537	>	*
538	>	*/
539	>	template<typename T> void ZConstraint<T>::calcForce(int calcPot, int calcStress){
540	>	double zsys;
541	>	double COM[3];
542	>	double force[3];
543	>	double zSysCOMVel;
544	>
545	>	T::calcForce(calcPot, calcStress);
546	>
547	>
548	>	if (hasZConsGap){
549	>	updateZPos();
550	>	}
551	>
552	>	if (checkZConsState()){
553	>	zeroOutVel();
554	>	forcePolicy->update();
555	>	}
556	>
557	>	zsys = calcZSys();
558	>	zSysCOMVel = calcSysCOMVel();
559	>	#ifdef IS_MPI
560	>	if (worldRank == 0){
561	>	#endif
562	>	//cout << "---------------------------------------------------------------------" <<endl;
563	>	//cout << "current time: " << info->getTime() << endl;
564	>	//cout << "center of mass at z: " << zsys << endl;
565	>	//cout << "before calcForce, the COMVel of system is " << zSysCOMVel <<endl;
566	>
567	>	#ifdef IS_MPI
568	>	}
569	>	#endif
570	>
571	>	//do zconstraint force;
572	>	if (haveFixedZMols()){
573	>	this->doZconstraintForce();
574	>	}
575	>
576	>	//use external force to move the molecules to the specified positions
577	>	if (haveMovingZMols()){
578	>	if (usingSMD)
579	>	this->doHarmonic(cantPos);
580	>	else
581	>	this->doHarmonic(zPos);
582	>	}
583	>
584	>	//write out forces and current positions of z-constraint molecules
585	>	if (info->getTime() >= curZconsTime){
586	>	for (int i = 0; i < (int) (zconsMols.size()); i++){
587	>	zconsMols[i]->getCOM(COM);
588	>	curZPos[i] = COM[whichDirection];
589	>
590	>	//if the z-constraint molecule is still moving, just record its force
591	>	if (states[i] == zcsMoving){
592	>	fz[i] = 0;
593	>	Atom** movingZAtoms;
594	>	movingZAtoms = zconsMols[i]->getMyAtoms();
595	>	for (int j = 0; j < zconsMols[i]->getNAtoms(); j++){
596	>	movingZAtoms[j]->getFrc(force);
597	>	fz[i] += force[whichDirection];
598	>	}
599	>	}
600	>	}
601	>	fzOut->writeFZ(info->getTime(), zconsMols.size(), &indexOfZConsMols[0], &fz[0],
602	>	&curZPos[0], &zPos[0]);
603	>	curZconsTime += zconsTime;
604	>	}
605	>
606	>	zSysCOMVel = calcSysCOMVel();
607	>	#ifdef IS_MPI
608	>	if (worldRank == 0){
609	>	#endif
610	>	//cout << "after calcForce, the COMVel of system is " << zSysCOMVel <<endl;
611	>	#ifdef IS_MPI
612	>	}
613	>	#endif
614	>	}
615	>
616	>
617	>	/**
618	>	*
619	>	*/
620	>
621	>	template<typename T> double ZConstraint<T>::calcZSys(){
622	>	//calculate reference z coordinate for z-constraint molecules
623	>	double totalMass_local;
624	>	double totalMass;
625	>	double totalMZ_local;
626	>	double totalMZ;
627	>	double massOfCurMol;
628	>	double COM[3];
629	>
630	>	totalMass_local = 0;
631	>	totalMZ_local = 0;
632	>
633	>	for (int i = 0; i < nMols; i++){
634	>	massOfCurMol = molecules[i].getTotalMass();
635	>	molecules[i].getCOM(COM);
636	>
637	>	totalMass_local += massOfCurMol;
638	>	totalMZ_local += massOfCurMol * COM[whichDirection];
639	>	}
640	>
641	>
642	>	#ifdef IS_MPI
643	>	MPI_Allreduce(&totalMass_local, &totalMass, 1, MPI_DOUBLE, MPI_SUM,
644	>	MPI_COMM_WORLD);
645	>	MPI_Allreduce(&totalMZ_local, &totalMZ, 1, MPI_DOUBLE, MPI_SUM, MPI_COMM_WORLD);
646	>	#else
647	>	totalMass = totalMass_local;
648	>	totalMZ = totalMZ_local;
649	>	#endif
650	>
651	>	double zsys;
652	>	zsys = totalMZ / totalMass;
653	>
654	>	return zsys;
655	>	}
656	>
657	>	/**
658	>	*
659	>	*/
660	>	template<typename T> void ZConstraint<T>::thermalize(void){
661	>	T::thermalize();
662	>	zeroOutVel();
663	>	}
664	>
665	>	/**
666	>	*
667	>	*/
668	>
669	>	template<typename T> void ZConstraint<T>::zeroOutVel(){
670	>	Atom** fixedZAtoms;
671	>	double COMvel[3];
672	>	double vel[3];
673	>	double zSysCOMVel;
674	>
675	>	//zero out the velocities of center of mass of fixed z-constrained molecules
676	>
677	>	for (int i = 0; i < (int) (zconsMols.size()); i++){
678	>	if (states[i] == zcsFixed){
679	>	zconsMols[i]->getCOMvel(COMvel);
680	>	//cout << "before resetting " << indexOfZConsMols[i] <<"'s vz is " << COMvel[whichDirection] << endl;
681	>
682	>	fixedZAtoms = zconsMols[i]->getMyAtoms();
683	>
684	>	for (int j = 0; j < zconsMols[i]->getNAtoms(); j++){
685	>	fixedZAtoms[j]->getVel(vel);
686	>	vel[whichDirection] -= COMvel[whichDirection];
687	>	fixedZAtoms[j]->setVel(vel);
688	>	}
689	>
690	>	zconsMols[i]->getCOMvel(COMvel);
691	>	//cout << "after resetting " << indexOfZConsMols[i] <<"'s vz is " << COMvel[whichDirection] << endl;
692	>	}
693	>	}
694	>
695	>	//cout << "before resetting the COMVel of moving molecules is " << calcMovingMolsCOMVel() <<endl;
696	>
697	>	zSysCOMVel = calcSysCOMVel();
698	>	#ifdef IS_MPI
699	>	if (worldRank == 0){
700	>	#endif
701	>	//cout << "before resetting the COMVel of sytem is " << zSysCOMVel << endl;
702	>	#ifdef IS_MPI
703	>	}
704	>	#endif
705	>
706	>	// calculate the vz of center of mass of unconstrained molecules and moving z-constrained molecules
707	>	double MVzOfMovingMols_local;
708	>	double MVzOfMovingMols;
709	>	double totalMassOfMovingZMols_local;
710	>	double totalMassOfMovingZMols;
711	>
712	>	MVzOfMovingMols_local = 0;
713	>	totalMassOfMovingZMols_local = 0;
714	>
715	>	for (int i = 0; i < (int) (unconsMols.size()); i++){
716	>	unconsMols[i]->getCOMvel(COMvel);
717	>	MVzOfMovingMols_local += massOfUnconsMols[i] * COMvel[whichDirection];
718	>	}
719	>
720	>	for (int i = 0; i < (int) (zconsMols.size()); i++){
721	>	if (states[i] == zcsMoving){
722	>	zconsMols[i]->getCOMvel(COMvel);
723	>	MVzOfMovingMols_local += massOfZConsMols[i] * COMvel[whichDirection];
724	>	totalMassOfMovingZMols_local += massOfZConsMols[i];
725	>	}
726	>	}
727	>
728	>	#ifndef IS_MPI
729	>	MVzOfMovingMols = MVzOfMovingMols_local;
730	>	totalMassOfMovingZMols = totalMassOfMovingZMols_local;
731	>	#else
732	>	MPI_Allreduce(&MVzOfMovingMols_local, &MVzOfMovingMols, 1, MPI_DOUBLE,
733	>	MPI_SUM, MPI_COMM_WORLD);
734	>	MPI_Allreduce(&totalMassOfMovingZMols_local, &totalMassOfMovingZMols, 1,
735	>	MPI_DOUBLE, MPI_SUM, MPI_COMM_WORLD);
736	>	#endif
737	>
738	>	double vzOfMovingMols;
739	>	vzOfMovingMols = MVzOfMovingMols /
740	>	(totalMassOfUncons + totalMassOfMovingZMols);
741	>
742	>	//modify the velocites of unconstrained molecules
743	>	Atom** unconsAtoms;
744	>	for (int i = 0; i < (int) (unconsMols.size()); i++){
745	>	unconsAtoms = unconsMols[i]->getMyAtoms();
746	>	for (int j = 0; j < unconsMols[i]->getNAtoms(); j++){
747	>	unconsAtoms[j]->getVel(vel);
748	>	vel[whichDirection] -= vzOfMovingMols;
749	>	unconsAtoms[j]->setVel(vel);
750	>	}
751	>	}
752	>
753	>	//modify the velocities of moving z-constrained molecuels
754	>	Atom** movingZAtoms;
755	>	for (int i = 0; i < (int) (zconsMols.size()); i++){
756	>	if (states[i] == zcsMoving){
757	>	movingZAtoms = zconsMols[i]->getMyAtoms();
758	>	for (int j = 0; j < zconsMols[i]->getNAtoms(); j++){
759	>	movingZAtoms[j]->getVel(vel);
760	>	vel[whichDirection] -= vzOfMovingMols;
761	>	movingZAtoms[j]->setVel(vel);
762	>	}
763	>	}
764	>	}
765	>
766	>
767	>	zSysCOMVel = calcSysCOMVel();
768	>	#ifdef IS_MPI
769	>	if (worldRank == 0){
770	>	#endif
771	>	//cout << "after resetting the COMVel of moving molecules is " << zSysCOMVel << endl;
772	>	#ifdef IS_MPI
773	>	}
774	>	#endif
775	>	}
776	>
777	>	/**
778	>	*
779	>	*/
780	>
781	>	template<typename T> void ZConstraint<T>::doZconstraintForce(){
782	>	Atom** zconsAtoms;
783	>	double totalFZ;
784	>	double totalFZ_local;
785	>	double COM[3];
786	>	double force[3];
787	>
788	>	//constrain the molecules which do not reach the specified positions
789	>
790	>	//Zero Out the force of z-contrained molecules
791	>	totalFZ_local = 0;
792	>
793	>	//calculate the total z-contrained force of fixed z-contrained molecules
794	>
795	>	//cout << "before zero out z-constraint force on fixed z-constraint molecuels "
796	>	//       << "total force is " << calcTotalForce() << endl;
797	>
798	>	for (int i = 0; i < (int) (zconsMols.size()); i++){
799	>	if (states[i] == zcsFixed){
800	>	zconsMols[i]->getCOM(COM);
801	>	zconsAtoms = zconsMols[i]->getMyAtoms();
802	>
803	>	fz[i] = 0;
804	>	for (int j = 0; j < zconsMols[i]->getNAtoms(); j++){
805	>	zconsAtoms[j]->getFrc(force);
806	>	fz[i] += force[whichDirection];
807	>	}
808	>	totalFZ_local += fz[i];
809	>
810	>	//cout << "Fixed Molecule\tindex: " << indexOfZConsMols[i]
811	>	//      <<"\tcurrent zpos: " << COM[whichDirection]
812	>	//      << "\tcurrent fz: " <<fz[i] << endl;
813	>	}
814	>	}
815	>
816	>	//calculate total z-constraint force
817	>	#ifdef IS_MPI
818	>	MPI_Allreduce(&totalFZ_local, &totalFZ, 1, MPI_DOUBLE, MPI_SUM, MPI_COMM_WORLD);
819	>	#else
820	>	totalFZ = totalFZ_local;
821	>	#endif
822	>
823	>
824	>	// apply negative to fixed z-constrained molecues;
825	>	force[0] = 0;
826	>	force[1] = 0;
827	>	force[2] = 0;
828	>
829	>	for (int i = 0; i < (int) (zconsMols.size()); i++){
830	>	if (states[i] == zcsFixed){
831	>	int nAtomOfCurZConsMol = zconsMols[i]->getNAtoms();
832	>	zconsAtoms = zconsMols[i]->getMyAtoms();
833	>
834	>	for (int j = 0; j < nAtomOfCurZConsMol; j++){
835	>	//force[whichDirection] = -fz[i]/ nAtomOfCurZConsMol;
836	>	force[whichDirection] = -forcePolicy->getZFOfFixedZMols(zconsMols[i],
837	>	zconsAtoms[j],
838	>	fz[i]);
839	>	zconsAtoms[j]->addFrc(force);
840	>	}
841	>	}
842	>	}
843	>
844	>	//cout << "after zero out z-constraint force on fixed z-constraint molecuels "
845	>	//      << "total force is " << calcTotalForce() << endl;
846	>
847	>
848	>	force[0] = 0;
849	>	force[1] = 0;
850	>	force[2] = 0;
851	>
852	>	//modify the forces of unconstrained molecules
853	>	for (int i = 0; i < (int) (unconsMols.size()); i++){
854	>	Atom** unconsAtoms = unconsMols[i]->getMyAtoms();
855	>
856	>	for (int j = 0; j < unconsMols[i]->getNAtoms(); j++){
857	>	//force[whichDirection] = totalFZ / (totNumOfUnconsAtoms + nMovingZAtoms);
858	>	force[whichDirection] = forcePolicy->getZFOfMovingMols(unconsAtoms[j],
859	>	totalFZ);
860	>	unconsAtoms[j]->addFrc(force);
861	>	}
862	>	}
863	>
864	>	//modify the forces of moving z-constrained molecules
865	>	for (int i = 0; i < (int) (zconsMols.size()); i++){
866	>	if (states[i] == zcsMoving){
867	>	Atom** movingZAtoms = zconsMols[i]->getMyAtoms();
868	>
869	>	for (int j = 0; j < zconsMols[i]->getNAtoms(); j++){
870	>	//force[whichDirection] = totalFZ / (totNumOfUnconsAtoms + nMovingZAtoms);
871	>	force[whichDirection] = forcePolicy->getZFOfMovingMols(movingZAtoms[j],
872	>	totalFZ);
873	>	movingZAtoms[j]->addFrc(force);
874	>	}
875	>	}
876	>	}
877	>	//  cout << "after substracting z-constraint force from moving molecuels "
878	>	//        << "total force is " << calcTotalForce()  << endl;
879	>	}
880	>
881	>	/**
882	>	*
883	>	*
884	>	*/
885	>
886	>	template<typename T> void ZConstraint<T>::doHarmonic(vector<double>& resPos){
887	>	double force[3];
888	>	double harmonicU;
889	>	double harmonicF;
890	>	double COM[3];
891	>	double diff;
892	>	double totalFZ_local;
893	>	double totalFZ;
894	>
895	>	force[0] = 0;
896	>	force[1] = 0;
897	>	force[2] = 0;
898	>
899	>	totalFZ_local = 0;
900	>
901	>	for (int i = 0; i < (int) (zconsMols.size()); i++){
902	>	if (states[i] == zcsMoving){
903	>	zconsMols[i]->getCOM(COM);
904	>	//       cout << "Moving Molecule\tindex: " << indexOfZConsMols[i]
905	>	//     << "\tcurrent zpos: " << COM[whichDirection] << endl;
906	>
907	>	diff = COM[whichDirection] - resPos[i];
908	>
909	>	harmonicU = 0.5 * kz[i] * diff * diff;
910	>	info->lrPot += harmonicU;
911	>
912	>	harmonicF = -kz[i] * diff;
913	>	totalFZ_local += harmonicF;
914	>
915	>	//adjust force
916	>
917	>	Atom** movingZAtoms = zconsMols[i]->getMyAtoms();
918	>
919	>	for (int j = 0; j < zconsMols[i]->getNAtoms(); j++){
920	>	//force[whichDirection] = harmonicF / zconsMols[i]->getNAtoms();
921	>	force[whichDirection] = forcePolicy->getHFOfFixedZMols(zconsMols[i],
922	>	movingZAtoms[j],
923	>	harmonicF);
924	>	movingZAtoms[j]->addFrc(force);
925	>	}
926	>	}
927	>	}
928	>
929	>	#ifndef IS_MPI
930	>	totalFZ = totalFZ_local;
931	>	#else
932	>	MPI_Allreduce(&totalFZ_local, &totalFZ, 1, MPI_DOUBLE, MPI_SUM, MPI_COMM_WORLD);
933	>	#endif
934	>
935	>	//cout << "before substracting harmonic force from moving molecuels "
936	>	//      << "total force is " << calcTotalForce()  << endl;
937	>
938	>	force[0] = 0;
939	>	force[1] = 0;
940	>	force[2] = 0;
941	>
942	>	//modify the forces of unconstrained molecules
943	>	for (int i = 0; i < (int) (unconsMols.size()); i++){
944	>	Atom** unconsAtoms = unconsMols[i]->getMyAtoms();
945	>
946	>	for (int j = 0; j < unconsMols[i]->getNAtoms(); j++){
947	>	//force[whichDirection] = - totalFZ /totNumOfUnconsAtoms;
948	>	force[whichDirection] = -forcePolicy->getHFOfUnconsMols(unconsAtoms[j],
949	>	totalFZ);
950	>	unconsAtoms[j]->addFrc(force);
951	>	}
952	>	}
953	>
954	>	//cout << "after substracting harmonic force from moving molecuels "
955	>	//      << "total force is " << calcTotalForce()  << endl;
956	>	}
957	>
958	>	/**
959	>	*
960	>	*/
961	>
962	>	template<typename T> bool ZConstraint<T>::checkZConsState(){
963	>	double COM[3];
964	>	double diff;
965	>
966	>	int changed_local;
967	>	int changed;
968	>
969	>	changed_local = 0;
970	>
971	>	for (int i = 0; i < (int) (zconsMols.size()); i++){
972	>	zconsMols[i]->getCOM(COM);
973	>	diff = fabs(COM[whichDirection] - zPos[i]);
974	>	if (diff <= zconsTol && states[i] == zcsMoving){
975	>	states[i] = zcsFixed;
976	>	changed_local = 1;
977	>
978	>	if (hasZConsGap)
979	>	endFixTime[i] = info->getTime() + zconsFixTime;
980	>	}
981	>	else if (diff > zconsTol && states[i] == zcsFixed){
982	>	states[i] = zcsMoving;
983	>	changed_local = 1;
984	>
985	>	if (hasZConsGap)
986	>	endFixTime[i] = INFINITE_TIME;
987	>	}
988	>	}
989	>
990	>	#ifndef IS_MPI
991	>	changed = changed_local;
992	>	#else
993	>	MPI_Allreduce(&changed_local, &changed, 1, MPI_INT, MPI_SUM, MPI_COMM_WORLD);
994	>	#endif
995	>
996	>	return (changed > 0);
997	>	}
998	>
999	>	template<typename T> bool ZConstraint<T>::haveFixedZMols(){
1000	>	int havingFixed_local;
1001	>	int havingFixed;
1002	>
1003	>	havingFixed_local = 0;
1004	>
1005	>	for (int i = 0; i < (int) (zconsMols.size()); i++)
1006	>	if (states[i] == zcsFixed){
1007	>	havingFixed_local = 1;
1008	>	break;
1009	>	}
1010	>
1011	>	#ifndef IS_MPI
1012	>	havingFixed = havingFixed_local;
1013	>	#else
1014	>	MPI_Allreduce(&havingFixed_local, &havingFixed, 1, MPI_INT, MPI_SUM,
1015	>	MPI_COMM_WORLD);
1016	>	#endif
1017	>
1018	>	return (havingFixed > 0);
1019	>	}
1020	>
1021	>
1022	>	/**
1023	>	*
1024	>	*/
1025	>	template<typename T> bool ZConstraint<T>::haveMovingZMols(){
1026	>	int havingMoving_local;
1027	>	int havingMoving;
1028	>
1029	>	havingMoving_local = 0;
1030	>
1031	>	for (int i = 0; i < (int) (zconsMols.size()); i++)
1032	>	if (states[i] == zcsMoving){
1033	>	havingMoving_local = 1;
1034	>	break;
1035	>	}
1036	>
1037	>	#ifndef IS_MPI
1038	>	havingMoving = havingMoving_local;
1039	>	#else
1040	>	MPI_Allreduce(&havingMoving_local, &havingMoving, 1, MPI_INT, MPI_SUM,
1041	>	MPI_COMM_WORLD);
1042	>	#endif
1043	>
1044	>	return (havingMoving > 0);
1045	>	}
1046	>
1047	>	/**
1048	>	*
1049	>	*/
1050	>
1051	>	template<typename T> double ZConstraint<T>::calcMovingMolsCOMVel(){
1052	>	double MVzOfMovingMols_local;
1053	>	double MVzOfMovingMols;
1054	>	double totalMassOfMovingZMols_local;
1055	>	double totalMassOfMovingZMols;
1056	>	double COMvel[3];
1057	>
1058	>	MVzOfMovingMols_local = 0;
1059	>	totalMassOfMovingZMols_local = 0;
1060	>
1061	>	for (int i = 0; i < unconsMols.size(); i++){
1062	>	unconsMols[i]->getCOMvel(COMvel);
1063	>	MVzOfMovingMols_local += massOfUnconsMols[i] * COMvel[whichDirection];
1064	>	}
1065	>
1066	>	for (int i = 0; i < zconsMols.size(); i++){
1067	>	if (states[i] == zcsMoving){
1068	>	zconsMols[i]->getCOMvel(COMvel);
1069	>	MVzOfMovingMols_local += massOfZConsMols[i] * COMvel[whichDirection];
1070	>	totalMassOfMovingZMols_local += massOfZConsMols[i];
1071	>	}
1072	>	}
1073	>
1074	>	#ifndef IS_MPI
1075	>	MVzOfMovingMols = MVzOfMovingMols_local;
1076	>	totalMassOfMovingZMols = totalMassOfMovingZMols_local;
1077	>	#else
1078	>	MPI_Allreduce(&MVzOfMovingMols_local, &MVzOfMovingMols, 1, MPI_DOUBLE,
1079	>	MPI_SUM, MPI_COMM_WORLD);
1080	>	MPI_Allreduce(&totalMassOfMovingZMols_local, &totalMassOfMovingZMols, 1,
1081	>	MPI_DOUBLE, MPI_SUM, MPI_COMM_WORLD);
1082	>	#endif
1083	>
1084	>	double vzOfMovingMols;
1085	>	vzOfMovingMols = MVzOfMovingMols /
1086	>	(totalMassOfUncons + totalMassOfMovingZMols);
1087	>
1088	>	return vzOfMovingMols;
1089	>	}
1090	>
1091	>	/**
1092	>	*
1093	>	*/
1094	>
1095	>	template<typename T> double ZConstraint<T>::calcSysCOMVel(){
1096	>	double COMvel[3];
1097	>	double tempMVz_local;
1098	>	double tempMVz;
1099	>	double massOfZCons_local;
1100	>	double massOfZCons;
1101	>
1102	>
1103	>	tempMVz_local = 0;
1104	>
1105	>	for (int i = 0 ; i < nMols; i++){
1106	>	molecules[i].getCOMvel(COMvel);
1107	>	tempMVz_local += molecules[i].getTotalMass() * COMvel[whichDirection];
1108	>	}
1109	>
1110	>	massOfZCons_local = 0;
1111	>
1112	>	for (int i = 0; i < (int) (massOfZConsMols.size()); i++){
1113	>	massOfZCons_local += massOfZConsMols[i];
1114	>	}
1115	>	#ifndef IS_MPI
1116	>	massOfZCons = massOfZCons_local;
1117	>	tempMVz = tempMVz_local;
1118	>	#else
1119	>	MPI_Allreduce(&massOfZCons_local, &massOfZCons, 1, MPI_DOUBLE, MPI_SUM,
1120	>	MPI_COMM_WORLD);
1121	>	MPI_Allreduce(&tempMVz_local, &tempMVz, 1, MPI_DOUBLE, MPI_SUM, MPI_COMM_WORLD);
1122	>	#endif
1123	>
1124	>	return tempMVz / (totalMassOfUncons + massOfZCons);
1125	>	}
1126	>
1127	>	/**
1128	>	*
1129	>	*/
1130	>
1131	>	template<typename T> double ZConstraint<T>::calcTotalForce(){
1132	>	double force[3];
1133	>	double totalForce_local;
1134	>	double totalForce;
1135	>
1136	>	totalForce_local = 0;
1137	>
1138	>	for (int i = 0; i < nAtoms; i++){
1139	>	atoms[i]->getFrc(force);
1140	>	totalForce_local += force[whichDirection];
1141	>	}
1142	>
1143	>	#ifndef IS_MPI
1144	>	totalForce = totalForce_local;
1145	>	#else
1146	>	MPI_Allreduce(&totalForce_local, &totalForce, 1, MPI_DOUBLE, MPI_SUM,
1147	>	MPI_COMM_WORLD);
1148	>	#endif
1149	>
1150	>	return totalForce;
1151	>	}
1152	>
1153	>	/**
1154	>	*
1155	>	*/
1156	>
1157	>	template<typename T> void ZConstraint<T>::PolicyByNumber::update(){
1158	>	//calculate the number of atoms of moving z-constrained molecules
1159	>	int nMovingZAtoms_local;
1160	>	int nMovingZAtoms;
1161	>
1162	>	nMovingZAtoms_local = 0;
1163	>	for (int i = 0; i < (int) ((zconsIntegrator->zconsMols).size()); i++)
1164	>	if ((zconsIntegrator->states)[i] == (zconsIntegrator->zcsMoving)){
1165	>	nMovingZAtoms_local += (zconsIntegrator->zconsMols)[i]->getNAtoms();
1166	>	}
1167	>
1168	>	#ifdef IS_MPI
1169	>	MPI_Allreduce(&nMovingZAtoms_local, &nMovingZAtoms, 1, MPI_INT, MPI_SUM,
1170	>	MPI_COMM_WORLD);
1171	>	#else
1172	>	nMovingZAtoms = nMovingZAtoms_local;
1173	>	#endif
1174	>	totNumOfMovingAtoms = nMovingZAtoms + zconsIntegrator->totNumOfUnconsAtoms;
1175	>	}
1176	>
1177	>	template<typename T> double ZConstraint<T>::PolicyByNumber::getZFOfFixedZMols(Molecule* mol,
1178	>	Atom* atom,
1179	>	double totalForce){
1180	>	return totalForce / mol->getNAtoms();
1181	>	}
1182	>
1183	>	template<typename T> double ZConstraint<T>::PolicyByNumber::getZFOfMovingMols(Atom* atom,
1184	>	double totalForce){
1185	>	return totalForce / totNumOfMovingAtoms;
1186	>	}
1187	>
1188	>	template<typename T> double ZConstraint<T>::PolicyByNumber::getHFOfFixedZMols(Molecule* mol,
1189	>	Atom* atom,
1190	>	double totalForce){
1191	>	return totalForce / mol->getNAtoms();
1192	>	}
1193	>
1194	>	template<typename T> double ZConstraint<T>::PolicyByNumber::getHFOfUnconsMols(Atom* atom,
1195	>	double totalForce){
1196	>	return totalForce / zconsIntegrator->totNumOfUnconsAtoms;
1197	>	}
1198	>
1199	>	/**
1200	>	*
1201	>	*/
1202	>
1203	>	template<typename T> void ZConstraint<T>::PolicyByMass::update(){
1204	>	//calculate the number of atoms of moving z-constrained molecules
1205	>	double massOfMovingZAtoms_local;
1206	>	double massOfMovingZAtoms;
1207	>
1208	>	massOfMovingZAtoms_local = 0;
1209	>	for (int i = 0; i < (int) ((zconsIntegrator->zconsMols).size()); i++)
1210	>	if ((zconsIntegrator->states)[i] == (zconsIntegrator->zcsMoving)){
1211	>	massOfMovingZAtoms_local += (zconsIntegrator->zconsMols)[i]->getTotalMass();
1212	>	}
1213	>
1214	>	#ifdef IS_MPI
1215	>	MPI_Allreduce(&massOfMovingZAtoms_local, &massOfMovingZAtoms, 1, MPI_DOUBLE,
1216	>	MPI_SUM, MPI_COMM_WORLD);
1217	>	#else
1218	>	massOfMovingZAtoms = massOfMovingZAtoms_local;
1219	>	#endif
1220	>	totMassOfMovingAtoms = massOfMovingZAtoms +
1221	>	zconsIntegrator->totalMassOfUncons;
1222	>	}
1223	>
1224	>	template<typename T> double ZConstraint<T>::PolicyByMass::getZFOfFixedZMols(Molecule* mol,
1225	>	Atom* atom,
1226	>	double totalForce){
1227	>	return totalForce * atom->getMass() / mol->getTotalMass();
1228	>	}
1229	>
1230	>	template<typename T> double ZConstraint<T>::PolicyByMass::getZFOfMovingMols(Atom* atom,
1231	>	double totalForce){
1232	>	return totalForce * atom->getMass() / totMassOfMovingAtoms;
1233	>	}
1234	>
1235	>	template<typename T> double ZConstraint<T>::PolicyByMass::getHFOfFixedZMols(Molecule* mol,
1236	>	Atom* atom,
1237	>	double totalForce){
1238	>	return totalForce * atom->getMass() / mol->getTotalMass();
1239	>	}
1240	>
1241	>	template<typename T> double ZConstraint<T>::PolicyByMass::getHFOfUnconsMols(Atom* atom,
1242	>	double totalForce){
1243	>	return totalForce * atom->getMass() / zconsIntegrator->totalMassOfUncons;
1244	>	}
1245	>
1246	>	template<typename T> void ZConstraint<T>::updateZPos(){
1247	>	double curTime;
1248	>	double COM[3];
1249	>
1250	>	curTime = info->getTime();
1251	>
1252	>	for (size_t i = 0; i < zconsMols.size(); i++){
1253	>
1254	>	if (states[i] == zcsFixed && curTime >= endFixTime[i]){
1255	>	zPos[i] += zconsGap;
1256	>
1257	>	if (usingSMD){
1258	>	zconsMols[i]->getCOM(COM);
1259	>	cantPos[i] = COM[whichDirection];
1260	>	}
1261	>
1262	>	}
1263	>
1264	>	}
1265	>
1266	>	}
1267	>
1268	>	template<typename T> void ZConstraint<T>::updateCantPos(){
1269	>	double curTime;
1270	>	double dt;
1271	>
1272	>	curTime = info->getTime();
1273	>	dt = info->dt;
1274	>
1275	>	for (size_t i = 0; i < zconsMols.size(); i++){
1276	>	if (states[i] == zcsMoving){
1277	>	cantPos[i] += cantVel[i] * dt;
1278	>	}
1279	>	}
1280	>
1281	>	}

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