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root/OpenMD/branches/development/src/brains/SimCreator.cpp

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trunk/src/brains/SimCreator.cpp (file contents), Revision 393 by tim, Wed Mar 2 16:28:20 2005 UTC vs.
branches/development/src/brains/SimCreator.cpp (file contents), Revision 1812 by gezelter, Fri Nov 16 21:18:42 2012 UTC

#	Line 1 | Line 1
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. Acknowledgement of the program authors must be made in any
10	<	*    publication of scientific results based in part on use of the
11	<	*    program.  An acceptable form of acknowledgement is citation of
12	<	*    the article in which the program was described (Matthew
13	<	*    A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
14	<	*    J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
15	<	*    Parallel Simulation Engine for Molecular Dynamics,"
16	<	*    J. Comput. Chem. 26, pp. 252-271 (2005))
17	<	*
18	<	* 2. Redistributions of source code must retain the above copyright
19	<	*    notice, this list of conditions and the following disclaimer.
20	<	*
21	<	* 3. Redistributions in binary form must reproduce the above copyright
22	<	*    notice, this list of conditions and the following disclaimer in the
23	<	*    documentation and/or other materials provided with the
24	<	*    distribution.
25	<	*
26	<	* This software is provided "AS IS," without a warranty of any
27	<	* kind. All express or implied conditions, representations and
28	<	* warranties, including any implied warranty of merchantability,
29	<	* fitness for a particular purpose or non-infringement, are hereby
30	<	* excluded.  The University of Notre Dame and its licensors shall not
31	<	* be liable for any damages suffered by licensee as a result of
32	<	* using, modifying or distributing the software or its
33	<	* derivatives. In no event will the University of Notre Dame or its
34	<	* licensors be liable for any lost revenue, profit or data, or for
35	<	* direct, indirect, special, consequential, incidental or punitive
36	<	* damages, however caused and regardless of the theory of liability,
37	<	* arising out of the use of or inability to use software, even if the
38	<	* University of Notre Dame has been advised of the possibility of
39	<	* such damages.
40	<	*/
41	<
42	<	/**
43	<	* @file SimCreator.cpp
44	<	* @author tlin
45	<	* @date 11/03/2004
46	<	* @time 13:51am
47	<	* @version 1.0
48	<	*/
49	<
50	<	#include <sprng.h>
51	<
52	<	#include "brains/MoleculeCreator.hpp"
53	<	#include "brains/SimCreator.hpp"
54	<	#include "brains/SimSnapshotManager.hpp"
55	<	#include "io/DumpReader.hpp"
56	<	#include "io/parse_me.h"
57	<	#include "UseTheForce/ForceFieldFactory.hpp"
58	<	#include "utils/simError.h"
59	<	#include "utils/StringUtils.hpp"
60	<	#include "math/SeqRandNumGen.hpp"
61	<	#ifdef IS_MPI
62	<	#include "io/mpiBASS.h"
63	<	#include "math/ParallelRandNumGen.hpp"
64	<	#endif
65	<
66	<	namespace oopse {
67	<
68	<	void SimCreator::parseFile(const std::string mdFileName,  MakeStamps* stamps, Globals* simParams){
69	<
70	<	#ifdef IS_MPI
71	<
72	<	if (worldRank == 0) {
73	<	#endif // is_mpi
74	<
75	<	simParams->initalize();
76	<	set_interface_stamps(stamps, simParams);
77	<
78	<	#ifdef IS_MPI
79	<
80	<	mpiEventInit();
81	<
82	<	#endif
83	<
84	<	yacc_BASS(mdFileName.c_str());
85	<
86	<	#ifdef IS_MPI
87	<
88	<	throwMPIEvent(NULL);
89	<	} else {
90	<	set_interface_stamps(stamps, simParams);
91	<	mpiEventInit();
92	<	MPIcheckPoint();
93	<	mpiEventLoop();
94	<	}
95	<
96	<	#endif
97	<
98	<	}
99	<
100	<	SimInfo*  SimCreator::createSim(const std::string & mdFileName, bool loadInitCoords) {
101	<
102	<	MakeStamps * stamps = new MakeStamps();
103	<
104	<	Globals * simParams = new Globals();
105	<
106	<	//parse meta-data file
107	<	parseFile(mdFileName, stamps, simParams);
108	<
109	<	//create the force field
110	<	ForceField * ff = ForceFieldFactory::getInstance()->createForceField(
111	<	simParams->getForceField());
112	<
113	<	if (ff == NULL) {
114	<	sprintf(painCave.errMsg, "ForceField Factory can not create %s force field\n",
115	<	simParams->getForceField());
116	<	painCave.isFatal = 1;
117	<	simError();
118	<	}
119	<
120	<	if (simParams->haveForceFieldFileName()) {
121	<	ff->setForceFieldFileName(simParams->getForceFieldFileName());
122	<	}
123	<
124	<	std::string forcefieldFileName;
125	<	forcefieldFileName = ff->getForceFieldFileName();
126	<
127	<	if (simParams->haveForceFieldVariant()) {
128	<	//If the force field has variant, the variant force field name will be
129	<	//Base.variant.frc. For exampel EAM.u6.frc
130	<
131	<	std::string variant = simParams->getForceFieldVariant();
132	<
133	<	std::string::size_type pos = forcefieldFileName.rfind(".frc");
134	<	variant = "." + variant;
135	<	if (pos != std::string::npos) {
136	<	forcefieldFileName.insert(pos, variant);
137	<	} else {
138	<	//If the default force field file name does not containt .frc suffix, just append the .variant
139	<	forcefieldFileName.append(variant);
140	<	}
141	<	}
142	<
143	<	ff->parse(forcefieldFileName);
144	<
145	<	//extract the molecule stamps
146	<	std::vector < std::pair<MoleculeStamp *, int> > moleculeStampPairs;
147	<	compList(stamps, simParams, moleculeStampPairs);
148	<
149	<	//create SimInfo
150	<	SimInfo * info = new SimInfo(moleculeStampPairs, ff, simParams);
151	<
152	<	//gather parameters (SimCreator only retrieves part of the parameters)
153	<	gatherParameters(info, mdFileName);
154	<
155	<	//divide the molecules and determine the global index of molecules
156	<	#ifdef IS_MPI
157	<	divideMolecules(info);
158	<	#endif
159	<
160	<	//create the molecules
161	<	createMolecules(info);
162	<
163	<
164	<	//allocate memory for DataStorage(circular reference, need to break it)
165	<	info->setSnapshotManager(new SimSnapshotManager(info));
166	<
167	<	//set the global index of atoms, rigidbodies and cutoffgroups (only need to be set once, the
168	<	//global index will never change again). Local indices of atoms and rigidbodies are already set by
169	<	//MoleculeCreator class which actually delegates the responsibility to LocalIndexManager.
170	<	setGlobalIndex(info);
171	<
172	<	//Alought addExculdePairs is called inside SimInfo's addMolecule method, at that point
173	<	//atoms don't have the global index yet  (their global index are all initialized to -1).
174	<	//Therefore we have to call addExcludePairs explicitly here. A way to work around is that
175	<	//we can determine the beginning global indices of atoms before they get created.
176	<	SimInfo::MoleculeIterator mi;
177	<	Molecule* mol;
178	<	for (mol= info->beginMolecule(mi); mol != NULL; mol = info->nextMolecule(mi)) {
179	<	info->addExcludePairs(mol);
180	<	}
181	<
182	<
183	<	//load initial coordinates, some extra information are pushed into SimInfo's property map ( such as
184	<	//eta, chi for NPT integrator)
185	<	if (loadInitCoords)
186	<	loadCoordinates(info);
187	<
188	<	return info;
189	<	}
190	<
191	<	void SimCreator::gatherParameters(SimInfo *info, const std::string& mdfile) {
192	<
193	<	//figure out the ouput file names
194	<	std::string prefix;
195	<
196	<	#ifdef IS_MPI
197	<
198	<	if (worldRank == 0) {
199	<	#endif // is_mpi
200	<	Globals * simParams = info->getSimParams();
201	<	if (simParams->haveFinalConfig()) {
202	<	prefix = getPrefix(simParams->getFinalConfig());
203	<	} else {
204	<	prefix = getPrefix(mdfile);
205	<	}
206	<
207	<	info->setFinalConfigFileName(prefix + ".eor");
208	<	info->setDumpFileName(prefix + ".dump");
209	<	info->setStatFileName(prefix + ".stat");
210	<
211	<	#ifdef IS_MPI
212	<
213	<	}
214	<
215	<	#endif
216	<
217	<	}
218	<
219	<	#ifdef IS_MPI
220	<	void SimCreator::divideMolecules(SimInfo *info) {
221	<	double numerator;
222	<	double denominator;
223	<	double precast;
224	<	double x;
225	<	double y;
226	<	double a;
227	<	int old_atoms;
228	<	int add_atoms;
229	<	int new_atoms;
230	<	int nTarget;
231	<	int done;
232	<	int i;
233	<	int j;
234	<	int loops;
235	<	int which_proc;
236	<	int nProcessors;
237	<	std::vector<int> atomsPerProc;
238	<	int nGlobalMols = info->getNGlobalMolecules();
239	<	std::vector<int> molToProcMap(nGlobalMols, -1); // default to an error condition:
240	<
241	<	MPI_Comm_size(MPI_COMM_WORLD, &nProcessors);
242	<
243	<	if (nProcessors > nGlobalMols) {
244	<	sprintf(painCave.errMsg,
245	<	"nProcessors (%d) > nMol (%d)\n"
246	<	"\tThe number of processors is larger than\n"
247	<	"\tthe number of molecules.  This will not result in a \n"
248	<	"\tusable division of atoms for force decomposition.\n"
249	<	"\tEither try a smaller number of processors, or run the\n"
250	<	"\tsingle-processor version of OOPSE.\n", nProcessors, nGlobalMols);
251	<
252	<	painCave.isFatal = 1;
253	<	simError();
254	<	}
255	<
256	<	int seedValue;
257	<	Globals * simParams = info->getSimParams();
258	<	SeqRandNumGen* myRandom; //divide labor does not need Parallel random number generator
259	<	if (simParams->haveSeed()) {
260	<	seedValue = simParams->getSeed();
261	<	myRandom = new SeqRandNumGen(seedValue);
262	<	}else {
263	<	myRandom = new SeqRandNumGen();
264	<	}
265	<
266	<
267	<	a = 3.0 * nGlobalMols / info->getNGlobalAtoms();
268	<
269	<	//initialize atomsPerProc
270	<	atomsPerProc.insert(atomsPerProc.end(), nProcessors, 0);
271	<
272	<	if (worldRank == 0) {
273	<	numerator = info->getNGlobalAtoms();
274	<	denominator = nProcessors;
275	<	precast = numerator / denominator;
276	<	nTarget = (int)(precast + 0.5);
277	<
278	<	for(i = 0; i < nGlobalMols; i++) {
279	<	done = 0;
280	<	loops = 0;
281	<
282	<	while (!done) {
283	<	loops++;
284	<
285	<	// Pick a processor at random
286	<
287	<	which_proc = (int) (myRandom->rand() * nProcessors);
288	<
289	<	//get the molecule stamp first
290	<	int stampId = info->getMoleculeStampId(i);
291	<	MoleculeStamp * moleculeStamp = info->getMoleculeStamp(stampId);
292	<
293	<	// How many atoms does this processor have so far?
294	<	old_atoms = atomsPerProc[which_proc];
295	<	add_atoms = moleculeStamp->getNAtoms();
296	<	new_atoms = old_atoms + add_atoms;
297	<
298	<	// If we've been through this loop too many times, we need
299	<	// to just give up and assign the molecule to this processor
300	<	// and be done with it.
301	<
302	<	if (loops > 100) {
303	<	sprintf(painCave.errMsg,
304	<	"I've tried 100 times to assign molecule %d to a "
305	<	" processor, but can't find a good spot.\n"
306	<	"I'm assigning it at random to processor %d.\n",
307	<	i, which_proc);
308	<
309	<	painCave.isFatal = 0;
310	<	simError();
311	<
312	<	molToProcMap[i] = which_proc;
313	<	atomsPerProc[which_proc] += add_atoms;
314	<
315	<	done = 1;
316	<	continue;
317	<	}
318	<
319	<	// If we can add this molecule to this processor without sending
320	<	// it above nTarget, then go ahead and do it:
321	<
322	<	if (new_atoms <= nTarget) {
323	<	molToProcMap[i] = which_proc;
324	<	atomsPerProc[which_proc] += add_atoms;
325	<
326	<	done = 1;
327	<	continue;
328	<	}
329	<
330	<	// The only situation left is when new_atoms > nTarget.  We
331	<	// want to accept this with some probability that dies off the
332	<	// farther we are from nTarget
333	<
334	<	// roughly:  x = new_atoms - nTarget
335	<	//           Pacc(x) = exp(- a * x)
336	<	// where a = penalty / (average atoms per molecule)
337	<
338	<	x = (double)(new_atoms - nTarget);
339	<	y = myRandom->rand();
340	<
341	<	if (y < exp(- a * x)) {
342	<	molToProcMap[i] = which_proc;
343	<	atomsPerProc[which_proc] += add_atoms;
344	<
345	<	done = 1;
346	<	continue;
347	<	} else {
348	<	continue;
349	<	}
350	<	}
351	<	}
352	<
353	<	delete myRandom;
354	<
355	<	// Spray out this nonsense to all other processors:
356	<
357	<	MPI_Bcast(&molToProcMap[0], nGlobalMols, MPI_INT, 0, MPI_COMM_WORLD);
358	<	} else {
359	<
360	<	// Listen to your marching orders from processor 0:
361	<
362	<	MPI_Bcast(&molToProcMap[0], nGlobalMols, MPI_INT, 0, MPI_COMM_WORLD);
363	<	}
364	<
365	<	info->setMolToProcMap(molToProcMap);
366	<	sprintf(checkPointMsg,
367	<	"Successfully divided the molecules among the processors.\n");
368	<	MPIcheckPoint();
369	<	}
370	<
371	<	#endif
372	<
373	<	void SimCreator::createMolecules(SimInfo *info) {
374	<	MoleculeCreator molCreator;
375	<	int stampId;
376	<
377	<	for(int i = 0; i < info->getNGlobalMolecules(); i++) {
378	<
379	<	#ifdef IS_MPI
380	<
381	<	if (info->getMolToProc(i) == worldRank) {
382	<	#endif
383	<
384	<	stampId = info->getMoleculeStampId(i);
385	<	Molecule * mol = molCreator.createMolecule(info->getForceField(), info->getMoleculeStamp(stampId),
386	<	stampId, i, info->getLocalIndexManager());
387	<
388	<	info->addMolecule(mol);
389	<
390	<	#ifdef IS_MPI
391	<
392	<	}
393	<
394	<	#endif
395	<
396	<	} //end for(int i=0)
397	<	}
398	<
399	<	void SimCreator::compList(MakeStamps *stamps, Globals* simParams,
400	<	std::vector < std::pair<MoleculeStamp *, int> > &moleculeStampPairs) {
401	<	int i;
402	<	char * id;
403	<	MoleculeStamp * currentStamp;
404	<	Component** the_components = simParams->getComponents();
405	<	int n_components = simParams->getNComponents();
406	<
407	<	if (!simParams->haveNMol()) {
408	<	// we don't have the total number of molecules, so we assume it is
409	<	// given in each component
410	<
411	<	for(i = 0; i < n_components; i++) {
412	<	if (!the_components[i]->haveNMol()) {
413	<	// we have a problem
414	<	sprintf(painCave.errMsg,
415	<	"SimCreator Error. No global NMol or component NMol given.\n"
416	<	"\tCannot calculate the number of atoms.\n");
417	<
418	<	painCave.isFatal = 1;
419	<	simError();
420	<	}
421	<
422	<	id = the_components[i]->getType();
423	<	currentStamp = (stamps->extractMolStamp(id))->getStamp();
424	<
425	<	if (currentStamp == NULL) {
426	<	sprintf(painCave.errMsg,
427	<	"SimCreator error: Component \"%s\" was not found in the "
428	<	"list of declared molecules\n", id);
429	<
430	<	painCave.isFatal = 1;
431	<	simError();
432	<	}
433	<
434	<	moleculeStampPairs.push_back(
435	<	std::make_pair(currentStamp, the_components[i]->getNMol()));
436	<	} //end for (i = 0; i < n_components; i++)
437	<	} else {
438	<	sprintf(painCave.errMsg, "SimSetup error.\n"
439	<	"\tSorry, the ability to specify total"
440	<	" nMols and then give molfractions in the components\n"
441	<	"\tis not currently supported."
442	<	" Please give nMol in the components.\n");
443	<
444	<	painCave.isFatal = 1;
445	<	simError();
446	<	}
447	<
448	<	#ifdef IS_MPI
449	<
450	<	strcpy(checkPointMsg, "Component stamps successfully extracted\n");
451	<	MPIcheckPoint();
452	<
453	<	#endif // is_mpi
454	<
455	<	}
456	<
457	<	void SimCreator::setGlobalIndex(SimInfo *info) {
458	<	SimInfo::MoleculeIterator mi;
459	<	Molecule::AtomIterator ai;
460	<	Molecule::RigidBodyIterator ri;
461	<	Molecule::CutoffGroupIterator ci;
462	<	Molecule * mol;
463	<	Atom * atom;
464	<	RigidBody * rb;
465	<	CutoffGroup * cg;
466	<	int beginAtomIndex;
467	<	int beginRigidBodyIndex;
468	<	int beginCutoffGroupIndex;
469	<	int nGlobalAtoms = info->getNGlobalAtoms();
470	<
471	<	#ifndef IS_MPI
472	<
473	<	beginAtomIndex = 0;
474	<	beginRigidBodyIndex = 0;
475	<	beginCutoffGroupIndex = 0;
476	<
477	<	#else
478	<
479	<	int nproc;
480	<	int myNode;
481	<
482	<	myNode = worldRank;
483	<	MPI_Comm_size(MPI_COMM_WORLD, &nproc);
484	<
485	<	std::vector < int > tmpAtomsInProc(nproc, 0);
486	<	std::vector < int > tmpRigidBodiesInProc(nproc, 0);
487	<	std::vector < int > tmpCutoffGroupsInProc(nproc, 0);
488	<	std::vector < int > NumAtomsInProc(nproc, 0);
489	<	std::vector < int > NumRigidBodiesInProc(nproc, 0);
490	<	std::vector < int > NumCutoffGroupsInProc(nproc, 0);
491	<
492	<	tmpAtomsInProc[myNode] = info->getNAtoms();
493	<	tmpRigidBodiesInProc[myNode] = info->getNRigidBodies();
494	<	tmpCutoffGroupsInProc[myNode] = info->getNCutoffGroups();
495	<
496	<	//do MPI_ALLREDUCE to exchange the total number of atoms, rigidbodies and cutoff groups
497	<	MPI_Allreduce(&tmpAtomsInProc[0], &NumAtomsInProc[0], nproc, MPI_INT,
498	<	MPI_SUM, MPI_COMM_WORLD);
499	<	MPI_Allreduce(&tmpRigidBodiesInProc[0], &NumRigidBodiesInProc[0], nproc,
500	<	MPI_INT, MPI_SUM, MPI_COMM_WORLD);
501	<	MPI_Allreduce(&tmpCutoffGroupsInProc[0], &NumCutoffGroupsInProc[0], nproc,
502	<	MPI_INT, MPI_SUM, MPI_COMM_WORLD);
503	<
504	<	beginAtomIndex = 0;
505	<	beginRigidBodyIndex = 0;
506	<	beginCutoffGroupIndex = 0;
507	<
508	<	for(int i = 0; i < myNode; i++) {
509	<	beginAtomIndex += NumAtomsInProc[i];
510	<	beginRigidBodyIndex += NumRigidBodiesInProc[i];
511	<	beginCutoffGroupIndex += NumCutoffGroupsInProc[i];
512	<	}
513	<
514	<	#endif
515	<
516	<	//rigidbody's index begins right after atom's
517	<	beginRigidBodyIndex += info->getNGlobalAtoms();
518	<
519	<	for(mol = info->beginMolecule(mi); mol != NULL;
520	<	mol = info->nextMolecule(mi)) {
521	<
522	<	//local index(index in DataStorge) of atom is important
523	<	for(atom = mol->beginAtom(ai); atom != NULL; atom = mol->nextAtom(ai)) {
524	<	atom->setGlobalIndex(beginAtomIndex++);
525	<	}
526	<
527	<	for(rb = mol->beginRigidBody(ri); rb != NULL;
528	<	rb = mol->nextRigidBody(ri)) {
529	<	rb->setGlobalIndex(beginRigidBodyIndex++);
530	<	}
531	<
532	<	//local index of cutoff group is trivial, it only depends on the order of travesing
533	<	for(cg = mol->beginCutoffGroup(ci); cg != NULL;
534	<	cg = mol->nextCutoffGroup(ci)) {
535	<	cg->setGlobalIndex(beginCutoffGroupIndex++);
536	<	}
537	<	}
538	<
539	<	//fill globalGroupMembership
540	<	std::vector<int> globalGroupMembership(info->getNGlobalAtoms(), 0);
541	<	for(mol = info->beginMolecule(mi); mol != NULL; mol = info->nextMolecule(mi)) {
542	<	for (cg = mol->beginCutoffGroup(ci); cg != NULL; cg = mol->nextCutoffGroup(ci)) {
543	<
544	<	for(atom = cg->beginAtom(ai); atom != NULL; atom = cg->nextAtom(ai)) {
545	<	globalGroupMembership[atom->getGlobalIndex()] = cg->getGlobalIndex();
546	<	}
547	<
548	<	}
549	<	}
550	<
551	<	#ifdef IS_MPI
552	<	// Since the globalGroupMembership has been zero filled and we've only
553	<	// poked values into the atoms we know, we can do an Allreduce
554	<	// to get the full globalGroupMembership array (We think).
555	<	// This would be prettier if we could use MPI_IN_PLACE like the MPI-2
556	<	// docs said we could.
557	<	std::vector<int> tmpGroupMembership(nGlobalAtoms, 0);
558	<	MPI_Allreduce(&globalGroupMembership[0], &tmpGroupMembership[0], nGlobalAtoms,
559	<	MPI_INT, MPI_SUM, MPI_COMM_WORLD);
560	<	info->setGlobalGroupMembership(tmpGroupMembership);
561	<	#else
562	<	info->setGlobalGroupMembership(globalGroupMembership);
563	<	#endif
564	<
565	<	//fill molMembership
566	<	std::vector<int> globalMolMembership(info->getNGlobalAtoms(), 0);
567	<
568	<	for(mol = info->beginMolecule(mi); mol != NULL; mol = info->nextMolecule(mi)) {
569	<
570	<	for(atom = mol->beginAtom(ai); atom != NULL; atom = mol->nextAtom(ai)) {
571	<	globalMolMembership[atom->getGlobalIndex()] = mol->getGlobalIndex();
572	<	}
573	<	}
574	<
575	<	#ifdef IS_MPI
576	<	std::vector<int> tmpMolMembership(nGlobalAtoms, 0);
577	<
578	<	MPI_Allreduce(&globalMolMembership[0], &tmpMolMembership[0], nGlobalAtoms,
579	<	MPI_INT, MPI_SUM, MPI_COMM_WORLD);
580	<
581	<	info->setGlobalMolMembership(tmpMolMembership);
582	<	#else
583	<	info->setGlobalMolMembership(globalMolMembership);
584	<	#endif
585	<
586	<	}
587	<
588	<	void SimCreator::loadCoordinates(SimInfo* info) {
589	<	Globals* simParams;
590	<	simParams = info->getSimParams();
591	<
592	<	if (!simParams->haveInitialConfig()) {
593	<	sprintf(painCave.errMsg,
594	<	"Cannot intialize a simulation without an initial configuration file.\n");
595	<	painCave.isFatal = 1;;
596	<	simError();
597	<	}
598	<
599	<	DumpReader reader(info, simParams->getInitialConfig());
600	<	int nframes = reader.getNFrames();
601	<
602	<	if (nframes > 0) {
603	<	reader.readFrame(nframes - 1);
604	<	} else {
605	<	//invalid initial coordinate file
606	<	sprintf(painCave.errMsg, "Initial configuration file %s should at least contain one frame\n",
607	<	simParams->getInitialConfig());
608	<	painCave.isFatal = 1;
609	<	simError();
610	<	}
611	<
612	<	//copy the current snapshot to previous snapshot
613	<	info->getSnapshotManager()->advance();
614	<	}
615	<
616	<	} //end namespace oopse
617	<
618	<
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	>	/**
44	>	* @file SimCreator.cpp
45	>	* @author tlin
46	>	* @date 11/03/2004
47	>	* @version 1.0
48	>	*/
49	>	#include <exception>
50	>	#include <iostream>
51	>	#include <sstream>
52	>	#include <string>
53	>
54	>	#include "brains/MoleculeCreator.hpp"
55	>	#include "brains/SimCreator.hpp"
56	>	#include "brains/SimSnapshotManager.hpp"
57	>	#include "io/DumpReader.hpp"
58	>	#include "brains/ForceField.hpp"
59	>	#include "utils/simError.h"
60	>	#include "utils/StringUtils.hpp"
61	>	#include "math/SeqRandNumGen.hpp"
62	>	#include "mdParser/MDLexer.hpp"
63	>	#include "mdParser/MDParser.hpp"
64	>	#include "mdParser/MDTreeParser.hpp"
65	>	#include "mdParser/SimplePreprocessor.hpp"
66	>	#include "antlr/ANTLRException.hpp"
67	>	#include "antlr/TokenStreamRecognitionException.hpp"
68	>	#include "antlr/TokenStreamIOException.hpp"
69	>	#include "antlr/TokenStreamException.hpp"
70	>	#include "antlr/RecognitionException.hpp"
71	>	#include "antlr/CharStreamException.hpp"
72	>
73	>	#include "antlr/MismatchedCharException.hpp"
74	>	#include "antlr/MismatchedTokenException.hpp"
75	>	#include "antlr/NoViableAltForCharException.hpp"
76	>	#include "antlr/NoViableAltException.hpp"
77	>
78	>	#include "types/DirectionalAdapter.hpp"
79	>	#include "types/MultipoleAdapter.hpp"
80	>	#include "types/EAMAdapter.hpp"
81	>	#include "types/SuttonChenAdapter.hpp"
82	>	#include "types/PolarizableAdapter.hpp"
83	>	#include "types/FixedChargeAdapter.hpp"
84	>	#include "types/FluctuatingChargeAdapter.hpp"
85	>
86	>	#ifdef IS_MPI
87	>	#include "mpi.h"
88	>	#include "math/ParallelRandNumGen.hpp"
89	>	#endif
90	>
91	>	namespace OpenMD {
92	>
93	>	Globals* SimCreator::parseFile(std::istream& rawMetaDataStream, const std::string& filename, int mdFileVersion, int startOfMetaDataBlock ){
94	>	Globals* simParams = NULL;
95	>	try {
96	>
97	>	// Create a preprocessor that preprocesses md file into an ostringstream
98	>	std::stringstream ppStream;
99	>	#ifdef IS_MPI
100	>	int streamSize;
101	>	const int masterNode = 0;
102	>	int commStatus;
103	>	if (worldRank == masterNode) {
104	>	commStatus = MPI_Bcast(&mdFileVersion, 1, MPI_INT, masterNode, MPI_COMM_WORLD);
105	>	#endif
106	>	SimplePreprocessor preprocessor;
107	>	preprocessor.preprocess(rawMetaDataStream, filename, startOfMetaDataBlock, ppStream);
108	>
109	>	#ifdef IS_MPI
110	>	//brocasting the stream size
111	>	streamSize = ppStream.str().size() +1;
112	>	commStatus = MPI_Bcast(&streamSize, 1, MPI_LONG, masterNode, MPI_COMM_WORLD);
113	>
114	>	commStatus = MPI_Bcast(static_cast<void*>(const_cast<char*>(ppStream.str().c_str())), streamSize, MPI_CHAR, masterNode, MPI_COMM_WORLD);
115	>
116	>
117	>	} else {
118	>
119	>	commStatus = MPI_Bcast(&mdFileVersion, 1, MPI_INT, masterNode, MPI_COMM_WORLD);
120	>
121	>	//get stream size
122	>	commStatus = MPI_Bcast(&streamSize, 1, MPI_LONG, masterNode, MPI_COMM_WORLD);
123	>
124	>	char* buf = new char[streamSize];
125	>	assert(buf);
126	>
127	>	//receive file content
128	>	commStatus = MPI_Bcast(buf, streamSize, MPI_CHAR, masterNode, MPI_COMM_WORLD);
129	>
130	>	ppStream.str(buf);
131	>	delete [] buf;
132	>
133	>	}
134	>	#endif
135	>	// Create a scanner that reads from the input stream
136	>	MDLexer lexer(ppStream);
137	>	lexer.setFilename(filename);
138	>	lexer.initDeferredLineCount();
139	>
140	>	// Create a parser that reads from the scanner
141	>	MDParser parser(lexer);
142	>	parser.setFilename(filename);
143	>
144	>	// Create an observer that synchorizes file name change
145	>	FilenameObserver observer;
146	>	observer.setLexer(&lexer);
147	>	observer.setParser(&parser);
148	>	lexer.setObserver(&observer);
149	>
150	>	antlr::ASTFactory factory;
151	>	parser.initializeASTFactory(factory);
152	>	parser.setASTFactory(&factory);
153	>	parser.mdfile();
154	>
155	>	// Create a tree parser that reads information into Globals
156	>	MDTreeParser treeParser;
157	>	treeParser.initializeASTFactory(factory);
158	>	treeParser.setASTFactory(&factory);
159	>	simParams = treeParser.walkTree(parser.getAST());
160	>	}
161	>
162	>
163	>	catch(antlr::MismatchedCharException& e) {
164	>	sprintf(painCave.errMsg,
165	>	"parser exception: %s %s:%d:%d\n",
166	>	e.getMessage().c_str(),e.getFilename().c_str(), e.getLine(), e.getColumn());
167	>	painCave.isFatal = 1;
168	>	simError();
169	>	}
170	>	catch(antlr::MismatchedTokenException &e) {
171	>	sprintf(painCave.errMsg,
172	>	"parser exception: %s %s:%d:%d\n",
173	>	e.getMessage().c_str(),e.getFilename().c_str(), e.getLine(), e.getColumn());
174	>	painCave.isFatal = 1;
175	>	simError();
176	>	}
177	>	catch(antlr::NoViableAltForCharException &e) {
178	>	sprintf(painCave.errMsg,
179	>	"parser exception: %s %s:%d:%d\n",
180	>	e.getMessage().c_str(),e.getFilename().c_str(), e.getLine(), e.getColumn());
181	>	painCave.isFatal = 1;
182	>	simError();
183	>	}
184	>	catch(antlr::NoViableAltException &e) {
185	>	sprintf(painCave.errMsg,
186	>	"parser exception: %s %s:%d:%d\n",
187	>	e.getMessage().c_str(),e.getFilename().c_str(), e.getLine(), e.getColumn());
188	>	painCave.isFatal = 1;
189	>	simError();
190	>	}
191	>
192	>	catch(antlr::TokenStreamRecognitionException& e) {
193	>	sprintf(painCave.errMsg,
194	>	"parser exception: %s %s:%d:%d\n",
195	>	e.getMessage().c_str(),e.getFilename().c_str(), e.getLine(), e.getColumn());
196	>	painCave.isFatal = 1;
197	>	simError();
198	>	}
199	>
200	>	catch(antlr::TokenStreamIOException& e) {
201	>	sprintf(painCave.errMsg,
202	>	"parser exception: %s\n",
203	>	e.getMessage().c_str());
204	>	painCave.isFatal = 1;
205	>	simError();
206	>	}
207	>
208	>	catch(antlr::TokenStreamException& e) {
209	>	sprintf(painCave.errMsg,
210	>	"parser exception: %s\n",
211	>	e.getMessage().c_str());
212	>	painCave.isFatal = 1;
213	>	simError();
214	>	}
215	>	catch (antlr::RecognitionException& e) {
216	>	sprintf(painCave.errMsg,
217	>	"parser exception: %s %s:%d:%d\n",
218	>	e.getMessage().c_str(),e.getFilename().c_str(), e.getLine(), e.getColumn());
219	>	painCave.isFatal = 1;
220	>	simError();
221	>	}
222	>	catch (antlr::CharStreamException& e) {
223	>	sprintf(painCave.errMsg,
224	>	"parser exception: %s\n",
225	>	e.getMessage().c_str());
226	>	painCave.isFatal = 1;
227	>	simError();
228	>	}
229	>	catch (OpenMDException& e) {
230	>	sprintf(painCave.errMsg,
231	>	"%s\n",
232	>	e.getMessage().c_str());
233	>	painCave.isFatal = 1;
234	>	simError();
235	>	}
236	>	catch (std::exception& e) {
237	>	sprintf(painCave.errMsg,
238	>	"parser exception: %s\n",
239	>	e.what());
240	>	painCave.isFatal = 1;
241	>	simError();
242	>	}
243	>
244	>	simParams->setMDfileVersion(mdFileVersion);
245	>	return simParams;
246	>	}
247	>
248	>	SimInfo*  SimCreator::createSim(const std::string & mdFileName,
249	>	bool loadInitCoords) {
250	>
251	>	const int bufferSize = 65535;
252	>	char buffer[bufferSize];
253	>	int lineNo = 0;
254	>	std::string mdRawData;
255	>	int metaDataBlockStart = -1;
256	>	int metaDataBlockEnd = -1;
257	>	int i, j;
258	>	streamoff mdOffset;
259	>	int mdFileVersion;
260	>
261	>	// Create a string for embedding the version information in the MetaData
262	>	std::string version;
263	>	version.assign("## Last run using OpenMD Version: ");
264	>	version.append(OPENMD_VERSION_MAJOR);
265	>	version.append(".");
266	>	version.append(OPENMD_VERSION_MINOR);
267	>
268	>	std::string svnrev;
269	>	//convert a macro from compiler to a string in c++
270	>	STR_DEFINE(svnrev, SVN_REV );
271	>	version.append(" Revision: ");
272	>	// If there's no SVN revision, just call this the RELEASE revision.
273	>	if (!svnrev.empty()) {
274	>	version.append(svnrev);
275	>	} else {
276	>	version.append("RELEASE");
277	>	}
278	>
279	>	#ifdef IS_MPI
280	>	const int masterNode = 0;
281	>	if (worldRank == masterNode) {
282	>	#endif
283	>
284	>	std::ifstream mdFile_;
285	>	mdFile_.open(mdFileName.c_str(), ifstream::in | ifstream::binary);
286	>
287	>	if (mdFile_.fail()) {
288	>	sprintf(painCave.errMsg,
289	>	"SimCreator: Cannot open file: %s\n",
290	>	mdFileName.c_str());
291	>	painCave.isFatal = 1;
292	>	simError();
293	>	}
294	>
295	>	mdFile_.getline(buffer, bufferSize);
296	>	++lineNo;
297	>	std::string line = trimLeftCopy(buffer);
298	>	i = CaseInsensitiveFind(line, "<OpenMD");
299	>	if (static_cast<size_t>(i) == string::npos) {
300	>	// try the older file strings to see if that works:
301	>	i = CaseInsensitiveFind(line, "<OOPSE");
302	>	}
303	>
304	>	if (static_cast<size_t>(i) == string::npos) {
305	>	// still no luck!
306	>	sprintf(painCave.errMsg,
307	>	"SimCreator: File: %s is not a valid OpenMD file!\n",
308	>	mdFileName.c_str());
309	>	painCave.isFatal = 1;
310	>	simError();
311	>	}
312	>
313	>	// found the correct opening string, now try to get the file
314	>	// format version number.
315	>
316	>	StringTokenizer tokenizer(line, "=<> \t\n\r");
317	>	std::string fileType = tokenizer.nextToken();
318	>	toUpper(fileType);
319	>
320	>	mdFileVersion = 0;
321	>
322	>	if (fileType == "OPENMD") {
323	>	while (tokenizer.hasMoreTokens()) {
324	>	std::string token(tokenizer.nextToken());
325	>	toUpper(token);
326	>	if (token == "VERSION") {
327	>	mdFileVersion = tokenizer.nextTokenAsInt();
328	>	break;
329	>	}
330	>	}
331	>	}
332	>
333	>	//scan through the input stream and find MetaData tag
334	>	while(mdFile_.getline(buffer, bufferSize)) {
335	>	++lineNo;
336	>
337	>	std::string line = trimLeftCopy(buffer);
338	>	if (metaDataBlockStart == -1) {
339	>	i = CaseInsensitiveFind(line, "<MetaData>");
340	>	if (i != string::npos) {
341	>	metaDataBlockStart = lineNo;
342	>	mdOffset = mdFile_.tellg();
343	>	}
344	>	} else {
345	>	i = CaseInsensitiveFind(line, "</MetaData>");
346	>	if (i != string::npos) {
347	>	metaDataBlockEnd = lineNo;
348	>	}
349	>	}
350	>	}
351	>
352	>	if (metaDataBlockStart == -1) {
353	>	sprintf(painCave.errMsg,
354	>	"SimCreator: File: %s did not contain a <MetaData> tag!\n",
355	>	mdFileName.c_str());
356	>	painCave.isFatal = 1;
357	>	simError();
358	>	}
359	>	if (metaDataBlockEnd == -1) {
360	>	sprintf(painCave.errMsg,
361	>	"SimCreator: File: %s did not contain a closed MetaData block!\n",
362	>	mdFileName.c_str());
363	>	painCave.isFatal = 1;
364	>	simError();
365	>	}
366	>
367	>	mdFile_.clear();
368	>	mdFile_.seekg(0);
369	>	mdFile_.seekg(mdOffset);
370	>
371	>	mdRawData.clear();
372	>
373	>	bool foundVersion = false;
374	>
375	>	for (int i = 0; i < metaDataBlockEnd - metaDataBlockStart - 1; ++i) {
376	>	mdFile_.getline(buffer, bufferSize);
377	>	std::string line = trimLeftCopy(buffer);
378	>	j = CaseInsensitiveFind(line, "## Last run using OpenMD Version");
379	>	if (static_cast<size_t>(j) != string::npos) {
380	>	foundVersion = true;
381	>	mdRawData += version;
382	>	} else {
383	>	mdRawData += buffer;
384	>	}
385	>	mdRawData += "\n";
386	>	}
387	>
388	>	if (!foundVersion) mdRawData += version + "\n";
389	>
390	>	mdFile_.close();
391	>
392	>	#ifdef IS_MPI
393	>	}
394	>	#endif
395	>
396	>	std::stringstream rawMetaDataStream(mdRawData);
397	>
398	>	//parse meta-data file
399	>	Globals* simParams = parseFile(rawMetaDataStream, mdFileName, mdFileVersion,
400	>	metaDataBlockStart + 1);
401	>
402	>	//create the force field
403	>	ForceField * ff = new ForceField(simParams->getForceField());
404	>
405	>	if (ff == NULL) {
406	>	sprintf(painCave.errMsg,
407	>	"ForceField Factory can not create %s force field\n",
408	>	simParams->getForceField().c_str());
409	>	painCave.isFatal = 1;
410	>	simError();
411	>	}
412	>
413	>	if (simParams->haveForceFieldFileName()) {
414	>	ff->setForceFieldFileName(simParams->getForceFieldFileName());
415	>	}
416	>
417	>	std::string forcefieldFileName;
418	>	forcefieldFileName = ff->getForceFieldFileName();
419	>
420	>	if (simParams->haveForceFieldVariant()) {
421	>	//If the force field has variant, the variant force field name will be
422	>	//Base.variant.frc. For exampel EAM.u6.frc
423	>
424	>	std::string variant = simParams->getForceFieldVariant();
425	>
426	>	std::string::size_type pos = forcefieldFileName.rfind(".frc");
427	>	variant = "." + variant;
428	>	if (pos != std::string::npos) {
429	>	forcefieldFileName.insert(pos, variant);
430	>	} else {
431	>	//If the default force field file name does not containt .frc suffix, just append the .variant
432	>	forcefieldFileName.append(variant);
433	>	}
434	>	}
435	>
436	>	ff->parse(forcefieldFileName);
437	>	//create SimInfo
438	>	SimInfo * info = new SimInfo(ff, simParams);
439	>
440	>	info->setRawMetaData(mdRawData);
441	>
442	>	//gather parameters (SimCreator only retrieves part of the
443	>	//parameters)
444	>	gatherParameters(info, mdFileName);
445	>
446	>	//divide the molecules and determine the global index of molecules
447	>	#ifdef IS_MPI
448	>	divideMolecules(info);
449	>	#endif
450	>
451	>	//create the molecules
452	>	createMolecules(info);
453	>
454	>	//find the storage layout
455	>
456	>	int storageLayout = computeStorageLayout(info);
457	>
458	>	//allocate memory for DataStorage(circular reference, need to
459	>	//break it)
460	>	info->setSnapshotManager(new SimSnapshotManager(info, storageLayout));
461	>
462	>	//set the global index of atoms, rigidbodies and cutoffgroups
463	>	//(only need to be set once, the global index will never change
464	>	//again). Local indices of atoms and rigidbodies are already set
465	>	//by MoleculeCreator class which actually delegates the
466	>	//responsibility to LocalIndexManager.
467	>	setGlobalIndex(info);
468	>
469	>	//Although addInteractionPairs is called inside SimInfo's addMolecule
470	>	//method, at that point atoms don't have the global index yet
471	>	//(their global index are all initialized to -1).  Therefore we
472	>	//have to call addInteractionPairs explicitly here. A way to work
473	>	//around is that we can determine the beginning global indices of
474	>	//atoms before they get created.
475	>	SimInfo::MoleculeIterator mi;
476	>	Molecule* mol;
477	>	for (mol= info->beginMolecule(mi); mol != NULL; mol = info->nextMolecule(mi)) {
478	>	info->addInteractionPairs(mol);
479	>	}
480	>
481	>	if (loadInitCoords)
482	>	loadCoordinates(info, mdFileName);
483	>	return info;
484	>	}
485	>
486	>	void SimCreator::gatherParameters(SimInfo *info, const std::string& mdfile) {
487	>
488	>	//figure out the output file names
489	>	std::string prefix;
490	>
491	>	#ifdef IS_MPI
492	>
493	>	if (worldRank == 0) {
494	>	#endif // is_mpi
495	>	Globals * simParams = info->getSimParams();
496	>	if (simParams->haveFinalConfig()) {
497	>	prefix = getPrefix(simParams->getFinalConfig());
498	>	} else {
499	>	prefix = getPrefix(mdfile);
500	>	}
501	>
502	>	info->setFinalConfigFileName(prefix + ".eor");
503	>	info->setDumpFileName(prefix + ".dump");
504	>	info->setStatFileName(prefix + ".stat");
505	>	info->setRestFileName(prefix + ".zang");
506	>
507	>	#ifdef IS_MPI
508	>
509	>	}
510	>
511	>	#endif
512	>
513	>	}
514	>
515	>	#ifdef IS_MPI
516	>	void SimCreator::divideMolecules(SimInfo *info) {
517	>	RealType numerator;
518	>	RealType denominator;
519	>	RealType precast;
520	>	RealType x;
521	>	RealType y;
522	>	RealType a;
523	>	int old_atoms;
524	>	int add_atoms;
525	>	int new_atoms;
526	>	int nTarget;
527	>	int done;
528	>	int i;
529	>	int j;
530	>	int loops;
531	>	int which_proc;
532	>	int nProcessors;
533	>	std::vector<int> atomsPerProc;
534	>	int nGlobalMols = info->getNGlobalMolecules();
535	>	std::vector<int> molToProcMap(nGlobalMols, -1); // default to an error condition:
536	>
537	>	nProcessors = MPI::COMM_WORLD.Get_size();
538	>
539	>	if (nProcessors > nGlobalMols) {
540	>	sprintf(painCave.errMsg,
541	>	"nProcessors (%d) > nMol (%d)\n"
542	>	"\tThe number of processors is larger than\n"
543	>	"\tthe number of molecules.  This will not result in a \n"
544	>	"\tusable division of atoms for force decomposition.\n"
545	>	"\tEither try a smaller number of processors, or run the\n"
546	>	"\tsingle-processor version of OpenMD.\n", nProcessors, nGlobalMols);
547	>
548	>	painCave.isFatal = 1;
549	>	simError();
550	>	}
551	>
552	>	int seedValue;
553	>	Globals * simParams = info->getSimParams();
554	>	SeqRandNumGen* myRandom; //divide labor does not need Parallel random number generator
555	>	if (simParams->haveSeed()) {
556	>	seedValue = simParams->getSeed();
557	>	myRandom = new SeqRandNumGen(seedValue);
558	>	}else {
559	>	myRandom = new SeqRandNumGen();
560	>	}
561	>
562	>
563	>	a = 3.0 * nGlobalMols / info->getNGlobalAtoms();
564	>
565	>	//initialize atomsPerProc
566	>	atomsPerProc.insert(atomsPerProc.end(), nProcessors, 0);
567	>
568	>	if (worldRank == 0) {
569	>	numerator = info->getNGlobalAtoms();
570	>	denominator = nProcessors;
571	>	precast = numerator / denominator;
572	>	nTarget = (int)(precast + 0.5);
573	>
574	>	for(i = 0; i < nGlobalMols; i++) {
575	>
576	>	done = 0;
577	>	loops = 0;
578	>
579	>	while (!done) {
580	>	loops++;
581	>
582	>	// Pick a processor at random
583	>
584	>	which_proc = (int) (myRandom->rand() * nProcessors);
585	>
586	>	//get the molecule stamp first
587	>	int stampId = info->getMoleculeStampId(i);
588	>	MoleculeStamp * moleculeStamp = info->getMoleculeStamp(stampId);
589	>
590	>	// How many atoms does this processor have so far?
591	>	old_atoms = atomsPerProc[which_proc];
592	>	add_atoms = moleculeStamp->getNAtoms();
593	>	new_atoms = old_atoms + add_atoms;
594	>
595	>	// If we've been through this loop too many times, we need
596	>	// to just give up and assign the molecule to this processor
597	>	// and be done with it.
598	>
599	>	if (loops > 100) {
600	>
601	>	sprintf(painCave.errMsg,
602	>	"There have been 100 attempts to assign molecule %d to an\n"
603	>	"\tunderworked processor, but there's no good place to\n"
604	>	"\tleave it.  OpenMD is assigning it at random to processor %d.\n",
605	>	i, which_proc);
606	>
607	>	painCave.isFatal = 0;
608	>	painCave.severity = OPENMD_INFO;
609	>	simError();
610	>
611	>	molToProcMap[i] = which_proc;
612	>	atomsPerProc[which_proc] += add_atoms;
613	>
614	>	done = 1;
615	>	continue;
616	>	}
617	>
618	>	// If we can add this molecule to this processor without sending
619	>	// it above nTarget, then go ahead and do it:
620	>
621	>	if (new_atoms <= nTarget) {
622	>	molToProcMap[i] = which_proc;
623	>	atomsPerProc[which_proc] += add_atoms;
624	>
625	>	done = 1;
626	>	continue;
627	>	}
628	>
629	>	// The only situation left is when new_atoms > nTarget.  We
630	>	// want to accept this with some probability that dies off the
631	>	// farther we are from nTarget
632	>
633	>	// roughly:  x = new_atoms - nTarget
634	>	//           Pacc(x) = exp(- a * x)
635	>	// where a = penalty / (average atoms per molecule)
636	>
637	>	x = (RealType)(new_atoms - nTarget);
638	>	y = myRandom->rand();
639	>
640	>	if (y < exp(- a * x)) {
641	>	molToProcMap[i] = which_proc;
642	>	atomsPerProc[which_proc] += add_atoms;
643	>
644	>	done = 1;
645	>	continue;
646	>	} else {
647	>	continue;
648	>	}
649	>	}
650	>	}
651	>
652	>	delete myRandom;
653	>
654	>	// Spray out this nonsense to all other processors:
655	>	MPI::COMM_WORLD.Bcast(&molToProcMap[0], nGlobalMols, MPI::INT, 0);
656	>	} else {
657	>
658	>	// Listen to your marching orders from processor 0:
659	>	MPI::COMM_WORLD.Bcast(&molToProcMap[0], nGlobalMols, MPI::INT, 0);
660	>
661	>	}
662	>
663	>	info->setMolToProcMap(molToProcMap);
664	>	sprintf(checkPointMsg,
665	>	"Successfully divided the molecules among the processors.\n");
666	>	errorCheckPoint();
667	>	}
668	>
669	>	#endif
670	>
671	>	void SimCreator::createMolecules(SimInfo *info) {
672	>	MoleculeCreator molCreator;
673	>	int stampId;
674	>
675	>	for(int i = 0; i < info->getNGlobalMolecules(); i++) {
676	>
677	>	#ifdef IS_MPI
678	>
679	>	if (info->getMolToProc(i) == worldRank) {
680	>	#endif
681	>
682	>	stampId = info->getMoleculeStampId(i);
683	>	Molecule * mol = molCreator.createMolecule(info->getForceField(),
684	>	info->getMoleculeStamp(stampId),
685	>	stampId, i,
686	>	info->getLocalIndexManager());
687	>
688	>	info->addMolecule(mol);
689	>
690	>	#ifdef IS_MPI
691	>
692	>	}
693	>
694	>	#endif
695	>
696	>	} //end for(int i=0)
697	>	}
698	>
699	>	int SimCreator::computeStorageLayout(SimInfo* info) {
700	>
701	>	Globals* simParams = info->getSimParams();
702	>	int nRigidBodies = info->getNGlobalRigidBodies();
703	>	set<AtomType*> atomTypes = info->getSimulatedAtomTypes();
704	>	set<AtomType*>::iterator i;
705	>	bool hasDirectionalAtoms = false;
706	>	bool hasFixedCharge = false;
707	>	bool hasDipoles = false;
708	>	bool hasQuadrupoles = false;
709	>	bool hasPolarizable = false;
710	>	bool hasFluctuatingCharge = false;
711	>	bool hasMetallic = false;
712	>	int storageLayout = 0;
713	>	storageLayout |= DataStorage::dslPosition;
714	>	storageLayout |= DataStorage::dslVelocity;
715	>	storageLayout |= DataStorage::dslForce;
716	>
717	>	for (i = atomTypes.begin(); i != atomTypes.end(); ++i) {
718	>
719	>	DirectionalAdapter da = DirectionalAdapter( (*i) );
720	>	MultipoleAdapter ma = MultipoleAdapter( (*i) );
721	>	EAMAdapter ea = EAMAdapter( (*i) );
722	>	SuttonChenAdapter sca = SuttonChenAdapter( (*i) );
723	>	PolarizableAdapter pa = PolarizableAdapter( (*i) );
724	>	FixedChargeAdapter fca = FixedChargeAdapter( (*i) );
725	>	FluctuatingChargeAdapter fqa = FluctuatingChargeAdapter( (*i) );
726	>
727	>	if (da.isDirectional()){
728	>	hasDirectionalAtoms = true;
729	>	}
730	>	if (ma.isDipole()){
731	>	hasDipoles = true;
732	>	}
733	>	if (ma.isQuadrupole()){
734	>	hasQuadrupoles = true;
735	>	}
736	>	if (ea.isEAM() || sca.isSuttonChen()){
737	>	hasMetallic = true;
738	>	}
739	>	if ( fca.isFixedCharge() ){
740	>	hasFixedCharge = true;
741	>	}
742	>	if ( fqa.isFluctuatingCharge() ){
743	>	hasFluctuatingCharge = true;
744	>	}
745	>	if ( pa.isPolarizable() ){
746	>	hasPolarizable = true;
747	>	}
748	>	}
749	>
750	>	if (nRigidBodies > 0 || hasDirectionalAtoms) {
751	>	storageLayout |= DataStorage::dslAmat;
752	>	if(storageLayout & DataStorage::dslVelocity) {
753	>	storageLayout |= DataStorage::dslAngularMomentum;
754	>	}
755	>	if (storageLayout & DataStorage::dslForce) {
756	>	storageLayout |= DataStorage::dslTorque;
757	>	}
758	>	}
759	>	if (hasDipoles) {
760	>	storageLayout |= DataStorage::dslDipole;
761	>	}
762	>	if (hasQuadrupoles) {
763	>	storageLayout |= DataStorage::dslQuadrupole;
764	>	}
765	>	if (hasFixedCharge || hasFluctuatingCharge) {
766	>	storageLayout |= DataStorage::dslSkippedCharge;
767	>	}
768	>	if (hasMetallic) {
769	>	storageLayout |= DataStorage::dslDensity;
770	>	storageLayout |= DataStorage::dslFunctional;
771	>	storageLayout |= DataStorage::dslFunctionalDerivative;
772	>	}
773	>	if (hasPolarizable) {
774	>	storageLayout |= DataStorage::dslElectricField;
775	>	}
776	>	if (hasFluctuatingCharge){
777	>	storageLayout |= DataStorage::dslFlucQPosition;
778	>	if(storageLayout & DataStorage::dslVelocity) {
779	>	storageLayout |= DataStorage::dslFlucQVelocity;
780	>	}
781	>	if (storageLayout & DataStorage::dslForce) {
782	>	storageLayout |= DataStorage::dslFlucQForce;
783	>	}
784	>	}
785	>
786	>	// if the user has asked for them, make sure we've got the memory for the
787	>	// objects defined.
788	>
789	>	if (simParams->getOutputParticlePotential()) {
790	>	storageLayout |= DataStorage::dslParticlePot;
791	>	}
792	>
793	>	if (simParams->havePrintHeatFlux()) {
794	>	if (simParams->getPrintHeatFlux()) {
795	>	storageLayout |= DataStorage::dslParticlePot;
796	>	}
797	>	}
798	>
799	>	if (simParams->getOutputElectricField()) {
800	>	storageLayout |= DataStorage::dslElectricField;
801	>	}
802	>
803	>	if (simParams->getOutputFluctuatingCharges()) {
804	>	storageLayout |= DataStorage::dslFlucQPosition;
805	>	storageLayout |= DataStorage::dslFlucQVelocity;
806	>	storageLayout |= DataStorage::dslFlucQForce;
807	>	}
808	>
809	>	return storageLayout;
810	>	}
811	>
812	>	void SimCreator::setGlobalIndex(SimInfo *info) {
813	>	SimInfo::MoleculeIterator mi;
814	>	Molecule::AtomIterator ai;
815	>	Molecule::RigidBodyIterator ri;
816	>	Molecule::CutoffGroupIterator ci;
817	>	Molecule::IntegrableObjectIterator  ioi;
818	>	Molecule * mol;
819	>	Atom * atom;
820	>	RigidBody * rb;
821	>	CutoffGroup * cg;
822	>	int beginAtomIndex;
823	>	int beginRigidBodyIndex;
824	>	int beginCutoffGroupIndex;
825	>	int nGlobalAtoms = info->getNGlobalAtoms();
826	>	int nGlobalRigidBodies = info->getNGlobalRigidBodies();
827	>
828	>	beginAtomIndex = 0;
829	>	//rigidbody's index begins right after atom's
830	>	beginRigidBodyIndex = info->getNGlobalAtoms();
831	>	beginCutoffGroupIndex = 0;
832	>
833	>	for(int i = 0; i < info->getNGlobalMolecules(); i++) {
834	>
835	>	#ifdef IS_MPI
836	>	if (info->getMolToProc(i) == worldRank) {
837	>	#endif
838	>	// stuff to do if I own this molecule
839	>	mol = info->getMoleculeByGlobalIndex(i);
840	>
841	>	//local index(index in DataStorge) of atom is important
842	>	for(atom = mol->beginAtom(ai); atom != NULL; atom = mol->nextAtom(ai)) {
843	>	atom->setGlobalIndex(beginAtomIndex++);
844	>	}
845	>
846	>	for(rb = mol->beginRigidBody(ri); rb != NULL;
847	>	rb = mol->nextRigidBody(ri)) {
848	>	rb->setGlobalIndex(beginRigidBodyIndex++);
849	>	}
850	>
851	>	//local index of cutoff group is trivial, it only depends on
852	>	//the order of travesing
853	>	for(cg = mol->beginCutoffGroup(ci); cg != NULL;
854	>	cg = mol->nextCutoffGroup(ci)) {
855	>	cg->setGlobalIndex(beginCutoffGroupIndex++);
856	>	}
857	>
858	>	#ifdef IS_MPI
859	>	}  else {
860	>
861	>	// stuff to do if I don't own this molecule
862	>
863	>	int stampId = info->getMoleculeStampId(i);
864	>	MoleculeStamp* stamp = info->getMoleculeStamp(stampId);
865	>
866	>	beginAtomIndex += stamp->getNAtoms();
867	>	beginRigidBodyIndex += stamp->getNRigidBodies();
868	>	beginCutoffGroupIndex += stamp->getNCutoffGroups() + stamp->getNFreeAtoms();
869	>	}
870	>	#endif
871	>
872	>	} //end for(int i=0)
873	>
874	>	//fill globalGroupMembership
875	>	std::vector<int> globalGroupMembership(info->getNGlobalAtoms(), 0);
876	>	for(mol = info->beginMolecule(mi); mol != NULL; mol = info->nextMolecule(mi)) {
877	>	for (cg = mol->beginCutoffGroup(ci); cg != NULL; cg = mol->nextCutoffGroup(ci)) {
878	>
879	>	for(atom = cg->beginAtom(ai); atom != NULL; atom = cg->nextAtom(ai)) {
880	>	globalGroupMembership[atom->getGlobalIndex()] = cg->getGlobalIndex();
881	>	}
882	>
883	>	}
884	>	}
885	>
886	>	#ifdef IS_MPI
887	>	// Since the globalGroupMembership has been zero filled and we've only
888	>	// poked values into the atoms we know, we can do an Allreduce
889	>	// to get the full globalGroupMembership array (We think).
890	>	// This would be prettier if we could use MPI_IN_PLACE like the MPI-2
891	>	// docs said we could.
892	>	std::vector<int> tmpGroupMembership(info->getNGlobalAtoms(), 0);
893	>	MPI::COMM_WORLD.Allreduce(&globalGroupMembership[0],
894	>	&tmpGroupMembership[0], nGlobalAtoms,
895	>	MPI::INT, MPI::SUM);
896	>	info->setGlobalGroupMembership(tmpGroupMembership);
897	>	#else
898	>	info->setGlobalGroupMembership(globalGroupMembership);
899	>	#endif
900	>
901	>	//fill molMembership
902	>	std::vector<int> globalMolMembership(info->getNGlobalAtoms() +
903	>	info->getNGlobalRigidBodies(), 0);
904	>
905	>	for(mol = info->beginMolecule(mi); mol != NULL;
906	>	mol = info->nextMolecule(mi)) {
907	>	for(atom = mol->beginAtom(ai); atom != NULL; atom = mol->nextAtom(ai)) {
908	>	globalMolMembership[atom->getGlobalIndex()] = mol->getGlobalIndex();
909	>	}
910	>	for (rb = mol->beginRigidBody(ri); rb != NULL;
911	>	rb = mol->nextRigidBody(ri)) {
912	>	globalMolMembership[rb->getGlobalIndex()] = mol->getGlobalIndex();
913	>	}
914	>	}
915	>
916	>	#ifdef IS_MPI
917	>	std::vector<int> tmpMolMembership(info->getNGlobalAtoms() +
918	>	info->getNGlobalRigidBodies(), 0);
919	>	MPI::COMM_WORLD.Allreduce(&globalMolMembership[0], &tmpMolMembership[0],
920	>	nGlobalAtoms + nGlobalRigidBodies,
921	>	MPI::INT, MPI::SUM);
922	>
923	>	info->setGlobalMolMembership(tmpMolMembership);
924	>	#else
925	>	info->setGlobalMolMembership(globalMolMembership);
926	>	#endif
927	>
928	>	// nIOPerMol holds the number of integrable objects per molecule
929	>	// here the molecules are listed by their global indices.
930	>
931	>	std::vector<int> nIOPerMol(info->getNGlobalMolecules(), 0);
932	>	for (mol = info->beginMolecule(mi); mol != NULL;
933	>	mol = info->nextMolecule(mi)) {
934	>	nIOPerMol[mol->getGlobalIndex()] = mol->getNIntegrableObjects();
935	>	}
936	>
937	>	#ifdef IS_MPI
938	>	std::vector<int> numIntegrableObjectsPerMol(info->getNGlobalMolecules(), 0);
939	>	MPI::COMM_WORLD.Allreduce(&nIOPerMol[0], &numIntegrableObjectsPerMol[0],
940	>	info->getNGlobalMolecules(), MPI::INT, MPI::SUM);
941	>	#else
942	>	std::vector<int> numIntegrableObjectsPerMol = nIOPerMol;
943	>	#endif
944	>
945	>	std::vector<int> startingIOIndexForMol(info->getNGlobalMolecules());
946	>
947	>	int startingIndex = 0;
948	>	for (int i = 0; i < info->getNGlobalMolecules(); i++) {
949	>	startingIOIndexForMol[i] = startingIndex;
950	>	startingIndex += numIntegrableObjectsPerMol[i];
951	>	}
952	>
953	>	std::vector<StuntDouble*> IOIndexToIntegrableObject(info->getNGlobalIntegrableObjects(), (StuntDouble*)NULL);
954	>	for (mol = info->beginMolecule(mi); mol != NULL;
955	>	mol = info->nextMolecule(mi)) {
956	>	int myGlobalIndex = mol->getGlobalIndex();
957	>	int globalIO = startingIOIndexForMol[myGlobalIndex];
958	>	for (StuntDouble* sd = mol->beginIntegrableObject(ioi); sd != NULL;
959	>	sd = mol->nextIntegrableObject(ioi)) {
960	>	sd->setGlobalIntegrableObjectIndex(globalIO);
961	>	IOIndexToIntegrableObject[globalIO] = sd;
962	>	globalIO++;
963	>	}
964	>	}
965	>
966	>	info->setIOIndexToIntegrableObject(IOIndexToIntegrableObject);
967	>
968	>	}
969	>
970	>	void SimCreator::loadCoordinates(SimInfo* info, const std::string& mdFileName) {
971	>	Globals* simParams;
972	>
973	>	simParams = info->getSimParams();
974	>
975	>	DumpReader reader(info, mdFileName);
976	>	int nframes = reader.getNFrames();
977	>
978	>	if (nframes > 0) {
979	>	reader.readFrame(nframes - 1);
980	>	} else {
981	>	//invalid initial coordinate file
982	>	sprintf(painCave.errMsg,
983	>	"Initial configuration file %s should at least contain one frame\n",
984	>	mdFileName.c_str());
985	>	painCave.isFatal = 1;
986	>	simError();
987	>	}
988	>	//copy the current snapshot to previous snapshot
989	>	info->getSnapshotManager()->advance();
990	>	}
991	>
992	>	} //end namespace OpenMD
993	>
994	>

Comparing:
trunk/src/brains/SimCreator.cpp (property svn:keywords), Revision 393 by tim, Wed Mar 2 16:28:20 2005 UTC vs.
branches/development/src/brains/SimCreator.cpp (property svn:keywords), Revision 1812 by gezelter, Fri Nov 16 21:18:42 2012 UTC

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