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Comparing trunk/OOPSE-2.0/src/brains/SimCreator.cpp (file contents):
Revision 2077 by tim, Wed Mar 2 16:28:20 2005 UTC vs.
Revision 2531 by tim, Fri Dec 30 15:32:55 2005 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. 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 <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 "UseTheForce/ForceFieldFactory.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 > #ifdef IS_MPI
79 > #include "math/ParallelRandNumGen.hpp"
80 > #endif
81 >
82 > namespace oopse {
83 >  
84 > Globals* SimCreator::parseFile(const std::string mdFileName){
85 >        Globals* simParams = NULL;
86 >        try {
87 >
88 >            // Create a preprocessor that preprocesses md file into an ostringstream
89 >            std::stringstream ppStream;
90 > #ifdef IS_MPI            
91 >            int streamSize;
92 >            const int masterNode = 0;
93 >            int commStatus;
94 >            if (worldRank == masterNode) {
95 > #endif
96 >                
97 >                SimplePreprocessor preprocessor;
98 >                preprocessor.preprocess(mdFileName, ppStream);
99 >                
100 > #ifdef IS_MPI            
101 >                //brocasting the stream size
102 >                streamSize = ppStream.str().size() +1;
103 >                commStatus = MPI_Bcast(&streamSize, 1, MPI_LONG, masterNode, MPI_COMM_WORLD);                  
104 >
105 >                commStatus = MPI_Bcast(static_cast<void*>(const_cast<char*>(ppStream.str().c_str())), streamSize, MPI_CHAR, masterNode, MPI_COMM_WORLD);
106 >            
107 >                
108 >            } else {
109 >                //get stream size
110 >                commStatus = MPI_Bcast(&streamSize, 1, MPI_LONG, masterNode, MPI_COMM_WORLD);  
111 >                
112 >                  char* buf = new char[streamSize];
113 >                  assert(buf);
114 >                
115 >                  //receive file content
116 >                  commStatus = MPI_Bcast(buf, streamSize, MPI_CHAR, masterNode, MPI_COMM_WORLD);
117 >                
118 >                  ppStream.str(buf);
119 >                  delete buf;
120 >
121 >            }
122 > #endif            
123 >            // Create a scanner that reads from the input stream
124 >            MDLexer lexer(ppStream);
125 >            lexer.setFilename(mdFileName);
126 >            lexer.initDeferredLineCount();
127 >    
128 >            // Create a parser that reads from the scanner
129 >            MDParser parser(lexer);
130 >            parser.setFilename(mdFileName);
131 >
132 >            // Create an observer that synchorizes file name change
133 >            FilenameObserver observer;
134 >            observer.setLexer(&lexer);
135 >            observer.setParser(&parser);
136 >            lexer.setObserver(&observer);
137 >    
138 >            antlr::ASTFactory factory;
139 >            parser.initializeASTFactory(factory);
140 >            parser.setASTFactory(&factory);
141 >            parser.mdfile();
142 >
143 >            // Create a tree parser that reads information into Globals
144 >            MDTreeParser treeParser;
145 >            treeParser.initializeASTFactory(factory);
146 >            treeParser.setASTFactory(&factory);
147 >             simParams = treeParser.walkTree(parser.getAST());
148 >
149 >        }
150 >      
151 >      catch(antlr::MismatchedCharException& e) {
152 >          cerr<< "parser exception: " << e.getMessage() << " " <<  e.getFilename() << ":" << e.getLine() << " " << e.getColumn() << endl;
153 >      }
154 >      catch(antlr::MismatchedTokenException &e) {
155 >          cerr<< "parser exception: " << e.getMessage() << " " <<  e.getFilename() << ":" << e.getLine() << " " << e.getColumn() << endl;
156 >      }
157 >      catch(antlr::NoViableAltForCharException &e) {
158 >          cerr<< "parser exception: " << e.getMessage() << " " <<  e.getFilename() << ":" << e.getLine() << " " << e.getColumn() << endl;
159 >      }
160 >      catch(antlr::NoViableAltException &e) {
161 >          cerr<< "parser exception: " << e.getMessage() << " " <<  e.getFilename() << ":" << e.getLine() << " " << e.getColumn() << endl;
162 >      }
163 >        catch(antlr::TokenStreamRecognitionException& e) {
164 >          cerr<< "parser exception: " << e.getMessage() << " " <<  e.getFilename() << ":" << e.getLine() << " " << e.getColumn() << endl;
165 >        }
166 >        catch(antlr::TokenStreamIOException& e) {
167 >          cerr<< "parser exception: " << e.getMessage() << endl;
168 >        }
169 >        catch(antlr::TokenStreamException& e) {
170 >          cerr<< "parser exception: " << e.getMessage() << endl;
171 >        }        
172 >       catch (antlr::RecognitionException& e) {
173 >          cerr<< "parser exception: " << e.getMessage() << " " <<  e.getFilename() << ":" << e.getLine() << " " << e.getColumn() << endl;
174 >       }
175 >       catch (antlr::CharStreamException& e) {
176 >            cerr << "parser exception: " << e.getMessage() << endl;
177 >       }
178 >        catch (exception& e) {
179 >            cerr << "parser exception: " << e.what() << endl;
180 >        }
181 >
182 >        return simParams;
183 >  }
184 >  
185 >  SimInfo*  SimCreator::createSim(const std::string & mdFileName,
186 >                                  bool loadInitCoords) {
187 >
188 >    //parse meta-data file
189 >    Globals* simParams = parseFile(mdFileName);
190 >    
191 >    //create the force field
192 >    ForceField * ff = ForceFieldFactory::getInstance()
193 >      ->createForceField(simParams->getForceField());
194 >    
195 >    if (ff == NULL) {
196 >      sprintf(painCave.errMsg,
197 >              "ForceField Factory can not create %s force field\n",
198 >              simParams->getForceField().c_str());
199 >      painCave.isFatal = 1;
200 >      simError();
201 >    }
202 >    
203 >    if (simParams->haveForceFieldFileName()) {
204 >      ff->setForceFieldFileName(simParams->getForceFieldFileName());
205 >    }
206 >    
207 >    std::string forcefieldFileName;
208 >    forcefieldFileName = ff->getForceFieldFileName();
209 >    
210 >    if (simParams->haveForceFieldVariant()) {
211 >      //If the force field has variant, the variant force field name will be
212 >      //Base.variant.frc. For exampel EAM.u6.frc
213 >      
214 >      std::string variant = simParams->getForceFieldVariant();
215 >      
216 >      std::string::size_type pos = forcefieldFileName.rfind(".frc");
217 >      variant = "." + variant;
218 >      if (pos != std::string::npos) {
219 >        forcefieldFileName.insert(pos, variant);
220 >      } else {
221 >        //If the default force field file name does not containt .frc suffix, just append the .variant
222 >        forcefieldFileName.append(variant);
223 >      }
224 >    }
225 >    
226 >    ff->parse(forcefieldFileName);
227 >    ff->setFortranForceOptions();
228 >    //create SimInfo
229 >    SimInfo * info = new SimInfo(ff, simParams);
230 >    
231 >    //gather parameters (SimCreator only retrieves part of the parameters)
232 >    gatherParameters(info, mdFileName);
233 >    
234 >    //divide the molecules and determine the global index of molecules
235 > #ifdef IS_MPI
236 >    divideMolecules(info);
237 > #endif
238 >    
239 >    //create the molecules
240 >    createMolecules(info);
241 >    
242 >    
243 >    //allocate memory for DataStorage(circular reference, need to break it)
244 >    info->setSnapshotManager(new SimSnapshotManager(info));
245 >    
246 >    //set the global index of atoms, rigidbodies and cutoffgroups (only need to be set once, the
247 >    //global index will never change again). Local indices of atoms and rigidbodies are already set by
248 >    //MoleculeCreator class which actually delegates the responsibility to LocalIndexManager.
249 >    setGlobalIndex(info);
250 >    
251 >    //Alought addExculdePairs is called inside SimInfo's addMolecule method, at that point
252 >    //atoms don't have the global index yet  (their global index are all initialized to -1).
253 >    //Therefore we have to call addExcludePairs explicitly here. A way to work around is that
254 >    //we can determine the beginning global indices of atoms before they get created.
255 >    SimInfo::MoleculeIterator mi;
256 >    Molecule* mol;
257 >    for (mol= info->beginMolecule(mi); mol != NULL; mol = info->nextMolecule(mi)) {
258 >      info->addExcludePairs(mol);
259 >    }
260 >    
261 >    if (loadInitCoords)
262 >      loadCoordinates(info);    
263 >    
264 >    return info;
265 >  }
266 >  
267 >  void SimCreator::gatherParameters(SimInfo *info, const std::string& mdfile) {
268 >    
269 >    //figure out the output file names
270 >    std::string prefix;
271 >    
272 > #ifdef IS_MPI
273 >    
274 >    if (worldRank == 0) {
275 > #endif // is_mpi
276 >      Globals * simParams = info->getSimParams();
277 >      if (simParams->haveFinalConfig()) {
278 >        prefix = getPrefix(simParams->getFinalConfig());
279 >      } else {
280 >        prefix = getPrefix(mdfile);
281 >      }
282 >      
283 >      info->setFinalConfigFileName(prefix + ".eor");
284 >      info->setDumpFileName(prefix + ".dump");
285 >      info->setStatFileName(prefix + ".stat");
286 >      info->setRestFileName(prefix + ".zang");
287 >      
288 > #ifdef IS_MPI
289 >      
290 >    }
291 >    
292 > #endif
293 >    
294 >  }
295 >  
296 > #ifdef IS_MPI
297 >  void SimCreator::divideMolecules(SimInfo *info) {
298 >    double numerator;
299 >    double denominator;
300 >    double precast;
301 >    double x;
302 >    double y;
303 >    double a;
304 >    int old_atoms;
305 >    int add_atoms;
306 >    int new_atoms;
307 >    int nTarget;
308 >    int done;
309 >    int i;
310 >    int j;
311 >    int loops;
312 >    int which_proc;
313 >    int nProcessors;
314 >    std::vector<int> atomsPerProc;
315 >    int nGlobalMols = info->getNGlobalMolecules();
316 >    std::vector<int> molToProcMap(nGlobalMols, -1); // default to an error condition:
317 >    
318 >    MPI_Comm_size(MPI_COMM_WORLD, &nProcessors);
319 >    
320 >    if (nProcessors > nGlobalMols) {
321 >      sprintf(painCave.errMsg,
322 >              "nProcessors (%d) > nMol (%d)\n"
323 >              "\tThe number of processors is larger than\n"
324 >              "\tthe number of molecules.  This will not result in a \n"
325 >              "\tusable division of atoms for force decomposition.\n"
326 >              "\tEither try a smaller number of processors, or run the\n"
327 >              "\tsingle-processor version of OOPSE.\n", nProcessors, nGlobalMols);
328 >      
329 >      painCave.isFatal = 1;
330 >      simError();
331 >    }
332 >    
333 >    int seedValue;
334 >    Globals * simParams = info->getSimParams();
335 >    SeqRandNumGen* myRandom; //divide labor does not need Parallel random number generator
336 >    if (simParams->haveSeed()) {
337 >      seedValue = simParams->getSeed();
338 >      myRandom = new SeqRandNumGen(seedValue);
339 >    }else {
340 >      myRandom = new SeqRandNumGen();
341 >    }  
342 >    
343 >    
344 >    a = 3.0 * nGlobalMols / info->getNGlobalAtoms();
345 >    
346 >    //initialize atomsPerProc
347 >    atomsPerProc.insert(atomsPerProc.end(), nProcessors, 0);
348 >    
349 >    if (worldRank == 0) {
350 >      numerator = info->getNGlobalAtoms();
351 >      denominator = nProcessors;
352 >      precast = numerator / denominator;
353 >      nTarget = (int)(precast + 0.5);
354 >      
355 >      for(i = 0; i < nGlobalMols; i++) {
356 >        done = 0;
357 >        loops = 0;
358 >        
359 >        while (!done) {
360 >          loops++;
361 >          
362 >          // Pick a processor at random
363 >          
364 >          which_proc = (int) (myRandom->rand() * nProcessors);
365 >          
366 >          //get the molecule stamp first
367 >          int stampId = info->getMoleculeStampId(i);
368 >          MoleculeStamp * moleculeStamp = info->getMoleculeStamp(stampId);
369 >          
370 >          // How many atoms does this processor have so far?
371 >          old_atoms = atomsPerProc[which_proc];
372 >          add_atoms = moleculeStamp->getNAtoms();
373 >          new_atoms = old_atoms + add_atoms;
374 >          
375 >          // If we've been through this loop too many times, we need
376 >          // to just give up and assign the molecule to this processor
377 >          // and be done with it.
378 >          
379 >          if (loops > 100) {
380 >            sprintf(painCave.errMsg,
381 >                    "I've tried 100 times to assign molecule %d to a "
382 >                    " processor, but can't find a good spot.\n"
383 >                    "I'm assigning it at random to processor %d.\n",
384 >                    i, which_proc);
385 >            
386 >            painCave.isFatal = 0;
387 >            simError();
388 >            
389 >            molToProcMap[i] = which_proc;
390 >            atomsPerProc[which_proc] += add_atoms;
391 >            
392 >            done = 1;
393 >            continue;
394 >          }
395 >          
396 >          // If we can add this molecule to this processor without sending
397 >          // it above nTarget, then go ahead and do it:
398 >          
399 >          if (new_atoms <= nTarget) {
400 >            molToProcMap[i] = which_proc;
401 >            atomsPerProc[which_proc] += add_atoms;
402 >            
403 >            done = 1;
404 >            continue;
405 >          }
406 >          
407 >          // The only situation left is when new_atoms > nTarget.  We
408 >          // want to accept this with some probability that dies off the
409 >          // farther we are from nTarget
410 >          
411 >          // roughly:  x = new_atoms - nTarget
412 >          //           Pacc(x) = exp(- a * x)
413 >          // where a = penalty / (average atoms per molecule)
414 >          
415 >          x = (double)(new_atoms - nTarget);
416 >          y = myRandom->rand();
417 >          
418 >          if (y < exp(- a * x)) {
419 >            molToProcMap[i] = which_proc;
420 >            atomsPerProc[which_proc] += add_atoms;
421 >            
422 >            done = 1;
423 >            continue;
424 >          } else {
425 >            continue;
426 >          }
427 >        }
428 >      }
429 >      
430 >      delete myRandom;
431 >      
432 >      // Spray out this nonsense to all other processors:
433 >      
434 >      MPI_Bcast(&molToProcMap[0], nGlobalMols, MPI_INT, 0, MPI_COMM_WORLD);
435 >    } else {
436 >      
437 >      // Listen to your marching orders from processor 0:
438 >      
439 >      MPI_Bcast(&molToProcMap[0], nGlobalMols, MPI_INT, 0, MPI_COMM_WORLD);
440 >    }
441 >    
442 >    info->setMolToProcMap(molToProcMap);
443 >    sprintf(checkPointMsg,
444 >            "Successfully divided the molecules among the processors.\n");
445 >    MPIcheckPoint();
446 >  }
447 >  
448 > #endif
449 >  
450 >  void SimCreator::createMolecules(SimInfo *info) {
451 >    MoleculeCreator molCreator;
452 >    int stampId;
453 >    
454 >    for(int i = 0; i < info->getNGlobalMolecules(); i++) {
455 >      
456 > #ifdef IS_MPI
457 >      
458 >      if (info->getMolToProc(i) == worldRank) {
459 > #endif
460 >        
461 >        stampId = info->getMoleculeStampId(i);
462 >        Molecule * mol = molCreator.createMolecule(info->getForceField(), info->getMoleculeStamp(stampId),
463 >                                                   stampId, i, info->getLocalIndexManager());
464 >        
465 >        info->addMolecule(mol);
466 >        
467 > #ifdef IS_MPI
468 >        
469 >      }
470 >      
471 > #endif
472 >      
473 >    } //end for(int i=0)  
474 >  }
475 >    
476 >  void SimCreator::setGlobalIndex(SimInfo *info) {
477 >    SimInfo::MoleculeIterator mi;
478 >    Molecule::AtomIterator ai;
479 >    Molecule::RigidBodyIterator ri;
480 >    Molecule::CutoffGroupIterator ci;
481 >    Molecule * mol;
482 >    Atom * atom;
483 >    RigidBody * rb;
484 >    CutoffGroup * cg;
485 >    int beginAtomIndex;
486 >    int beginRigidBodyIndex;
487 >    int beginCutoffGroupIndex;
488 >    int nGlobalAtoms = info->getNGlobalAtoms();
489 >    
490 > #ifndef IS_MPI
491 >    
492 >    beginAtomIndex = 0;
493 >    beginRigidBodyIndex = 0;
494 >    beginCutoffGroupIndex = 0;
495 >    
496 > #else
497 >    
498 >    int nproc;
499 >    int myNode;
500 >    
501 >    myNode = worldRank;
502 >    MPI_Comm_size(MPI_COMM_WORLD, &nproc);
503 >    
504 >    std::vector < int > tmpAtomsInProc(nproc, 0);
505 >    std::vector < int > tmpRigidBodiesInProc(nproc, 0);
506 >    std::vector < int > tmpCutoffGroupsInProc(nproc, 0);
507 >    std::vector < int > NumAtomsInProc(nproc, 0);
508 >    std::vector < int > NumRigidBodiesInProc(nproc, 0);
509 >    std::vector < int > NumCutoffGroupsInProc(nproc, 0);
510 >    
511 >    tmpAtomsInProc[myNode] = info->getNAtoms();
512 >    tmpRigidBodiesInProc[myNode] = info->getNRigidBodies();
513 >    tmpCutoffGroupsInProc[myNode] = info->getNCutoffGroups();
514 >    
515 >    //do MPI_ALLREDUCE to exchange the total number of atoms, rigidbodies and cutoff groups
516 >    MPI_Allreduce(&tmpAtomsInProc[0], &NumAtomsInProc[0], nproc, MPI_INT,
517 >                  MPI_SUM, MPI_COMM_WORLD);
518 >    MPI_Allreduce(&tmpRigidBodiesInProc[0], &NumRigidBodiesInProc[0], nproc,
519 >                  MPI_INT, MPI_SUM, MPI_COMM_WORLD);
520 >    MPI_Allreduce(&tmpCutoffGroupsInProc[0], &NumCutoffGroupsInProc[0], nproc,
521 >                  MPI_INT, MPI_SUM, MPI_COMM_WORLD);
522 >    
523 >    beginAtomIndex = 0;
524 >    beginRigidBodyIndex = 0;
525 >    beginCutoffGroupIndex = 0;
526 >    
527 >    for(int i = 0; i < myNode; i++) {
528 >      beginAtomIndex += NumAtomsInProc[i];
529 >      beginRigidBodyIndex += NumRigidBodiesInProc[i];
530 >      beginCutoffGroupIndex += NumCutoffGroupsInProc[i];
531 >    }
532 >    
533 > #endif
534 >    
535 >    //rigidbody's index begins right after atom's
536 >    beginRigidBodyIndex += info->getNGlobalAtoms();
537 >    
538 >    for(mol = info->beginMolecule(mi); mol != NULL;
539 >        mol = info->nextMolecule(mi)) {
540 >      
541 >      //local index(index in DataStorge) of atom is important
542 >      for(atom = mol->beginAtom(ai); atom != NULL; atom = mol->nextAtom(ai)) {
543 >        atom->setGlobalIndex(beginAtomIndex++);
544 >      }
545 >      
546 >      for(rb = mol->beginRigidBody(ri); rb != NULL;
547 >          rb = mol->nextRigidBody(ri)) {
548 >        rb->setGlobalIndex(beginRigidBodyIndex++);
549 >      }
550 >      
551 >      //local index of cutoff group is trivial, it only depends on the order of travesing
552 >      for(cg = mol->beginCutoffGroup(ci); cg != NULL;
553 >          cg = mol->nextCutoffGroup(ci)) {
554 >        cg->setGlobalIndex(beginCutoffGroupIndex++);
555 >      }
556 >    }
557 >    
558 >    //fill globalGroupMembership
559 >    std::vector<int> globalGroupMembership(info->getNGlobalAtoms(), 0);
560 >    for(mol = info->beginMolecule(mi); mol != NULL; mol = info->nextMolecule(mi)) {        
561 >      for (cg = mol->beginCutoffGroup(ci); cg != NULL; cg = mol->nextCutoffGroup(ci)) {
562 >        
563 >        for(atom = cg->beginAtom(ai); atom != NULL; atom = cg->nextAtom(ai)) {
564 >          globalGroupMembership[atom->getGlobalIndex()] = cg->getGlobalIndex();
565 >        }
566 >        
567 >      }      
568 >    }
569 >    
570 > #ifdef IS_MPI    
571 >    // Since the globalGroupMembership has been zero filled and we've only
572 >    // poked values into the atoms we know, we can do an Allreduce
573 >    // to get the full globalGroupMembership array (We think).
574 >    // This would be prettier if we could use MPI_IN_PLACE like the MPI-2
575 >    // docs said we could.
576 >    std::vector<int> tmpGroupMembership(nGlobalAtoms, 0);
577 >    MPI_Allreduce(&globalGroupMembership[0], &tmpGroupMembership[0], nGlobalAtoms,
578 >                  MPI_INT, MPI_SUM, MPI_COMM_WORLD);
579 >    info->setGlobalGroupMembership(tmpGroupMembership);
580 > #else
581 >    info->setGlobalGroupMembership(globalGroupMembership);
582 > #endif
583 >    
584 >    //fill molMembership
585 >    std::vector<int> globalMolMembership(info->getNGlobalAtoms(), 0);
586 >    
587 >    for(mol = info->beginMolecule(mi); mol != NULL; mol = info->nextMolecule(mi)) {
588 >      
589 >      for(atom = mol->beginAtom(ai); atom != NULL; atom = mol->nextAtom(ai)) {
590 >        globalMolMembership[atom->getGlobalIndex()] = mol->getGlobalIndex();
591 >      }
592 >    }
593 >    
594 > #ifdef IS_MPI
595 >    std::vector<int> tmpMolMembership(nGlobalAtoms, 0);
596 >    
597 >    MPI_Allreduce(&globalMolMembership[0], &tmpMolMembership[0], nGlobalAtoms,
598 >                  MPI_INT, MPI_SUM, MPI_COMM_WORLD);
599 >    
600 >    info->setGlobalMolMembership(tmpMolMembership);
601 > #else
602 >    info->setGlobalMolMembership(globalMolMembership);
603 > #endif
604 >    
605 >  }
606 >  
607 >  void SimCreator::loadCoordinates(SimInfo* info) {
608 >    Globals* simParams;
609 >    simParams = info->getSimParams();
610 >    
611 >    if (!simParams->haveInitialConfig()) {
612 >      sprintf(painCave.errMsg,
613 >              "Cannot intialize a simulation without an initial configuration file.\n");
614 >      painCave.isFatal = 1;;
615 >      simError();
616 >    }
617 >    
618 >    DumpReader reader(info, simParams->getInitialConfig());
619 >    int nframes = reader.getNFrames();
620 >    
621 >    if (nframes > 0) {
622 >      reader.readFrame(nframes - 1);
623 >    } else {
624 >      //invalid initial coordinate file
625 >      sprintf(painCave.errMsg,
626 >              "Initial configuration file %s should at least contain one frame\n",
627 >              simParams->getInitialConfig().c_str());
628 >      painCave.isFatal = 1;
629 >      simError();
630 >    }
631 >    
632 >    //copy the current snapshot to previous snapshot
633 >    info->getSnapshotManager()->advance();
634 >  }
635 >  
636 > } //end namespace oopse
637 >
638 >

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