[ViewVC] Diff of: OpenMD/trunk/src/parallel/ForceMatrixDecomposition.cpp

Comparing branches/development/src/parallel/ForceMatrixDecomposition.cpp (file contents):
Revision 1587 by gezelter, Fri Jul 8 20:25:32 2011 UTC vs.
Revision 1713 by gezelter, Sat May 19 14:21:02 2012 UTC

#	Line 36 \| Line 36
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] Vardeman & Gezelter, in progress (2009).
39	>	* [4] Kuang & Gezelter, J. Chem. Phys. 133, 164101 (2010).
40	>	* [5] Vardeman, Stocker & Gezelter, J. Chem. Theory Comput. 7, 834 (2011).
41		*/
42		#include "parallel/ForceMatrixDecomposition.hpp"
43		#include "math/SquareMatrix3.hpp"
#	Line 47 \| Line 48 \| namespace OpenMD {
48		using namespace std;
49		namespace OpenMD {
50
51	+	ForceMatrixDecomposition::ForceMatrixDecomposition(SimInfo* info, InteractionManager* iMan) : ForceDecomposition(info, iMan) {
52	+
53	+	// In a parallel computation, row and colum scans must visit all
54	+	// surrounding cells (not just the 14 upper triangular blocks that
55	+	// are used when the processor can see all pairs)
56	+	#ifdef IS_MPI
57	+	cellOffsets_.clear();
58	+	cellOffsets_.push_back( Vector3i(-1,-1,-1) );
59	+	cellOffsets_.push_back( Vector3i( 0,-1,-1) );
60	+	cellOffsets_.push_back( Vector3i( 1,-1,-1) );
61	+	cellOffsets_.push_back( Vector3i(-1, 0,-1) );
62	+	cellOffsets_.push_back( Vector3i( 0, 0,-1) );
63	+	cellOffsets_.push_back( Vector3i( 1, 0,-1) );
64	+	cellOffsets_.push_back( Vector3i(-1, 1,-1) );
65	+	cellOffsets_.push_back( Vector3i( 0, 1,-1) );
66	+	cellOffsets_.push_back( Vector3i( 1, 1,-1) );
67	+	cellOffsets_.push_back( Vector3i(-1,-1, 0) );
68	+	cellOffsets_.push_back( Vector3i( 0,-1, 0) );
69	+	cellOffsets_.push_back( Vector3i( 1,-1, 0) );
70	+	cellOffsets_.push_back( Vector3i(-1, 0, 0) );
71	+	cellOffsets_.push_back( Vector3i( 0, 0, 0) );
72	+	cellOffsets_.push_back( Vector3i( 1, 0, 0) );
73	+	cellOffsets_.push_back( Vector3i(-1, 1, 0) );
74	+	cellOffsets_.push_back( Vector3i( 0, 1, 0) );
75	+	cellOffsets_.push_back( Vector3i( 1, 1, 0) );
76	+	cellOffsets_.push_back( Vector3i(-1,-1, 1) );
77	+	cellOffsets_.push_back( Vector3i( 0,-1, 1) );
78	+	cellOffsets_.push_back( Vector3i( 1,-1, 1) );
79	+	cellOffsets_.push_back( Vector3i(-1, 0, 1) );
80	+	cellOffsets_.push_back( Vector3i( 0, 0, 1) );
81	+	cellOffsets_.push_back( Vector3i( 1, 0, 1) );
82	+	cellOffsets_.push_back( Vector3i(-1, 1, 1) );
83	+	cellOffsets_.push_back( Vector3i( 0, 1, 1) );
84	+	cellOffsets_.push_back( Vector3i( 1, 1, 1) );
85	+	#endif
86	+	}
87	+
88	+
89		/**
90		* distributeInitialData is essentially a copy of the older fortran
91		* SimulationSetup
92		*/
54	–
93		void ForceMatrixDecomposition::distributeInitialData() {
94		snap_ = sman_->getCurrentSnapshot();
95		storageLayout_ = sman_->getStorageLayout();
#	Line 74 \| Line 112 \| namespace OpenMD {
112
113		#ifdef IS_MPI
114
115	<	AtomCommIntRow = new Communicator<Row,int>(nLocal_);
116	<	AtomCommRealRow = new Communicator<Row,RealType>(nLocal_);
79	<	AtomCommVectorRow = new Communicator<Row,Vector3d>(nLocal_);
80	<	AtomCommMatrixRow = new Communicator<Row,Mat3x3d>(nLocal_);
81	<	AtomCommPotRow = new Communicator<Row,potVec>(nLocal_);
115	>	MPI::Intracomm row = rowComm.getComm();
116	>	MPI::Intracomm col = colComm.getComm();
117
118	<	AtomCommIntColumn = new Communicator<Column,int>(nLocal_);
119	<	AtomCommRealColumn = new Communicator<Column,RealType>(nLocal_);
120	<	AtomCommVectorColumn = new Communicator<Column,Vector3d>(nLocal_);
121	<	AtomCommMatrixColumn = new Communicator<Column,Mat3x3d>(nLocal_);
122	<	AtomCommPotColumn = new Communicator<Column,potVec>(nLocal_);
118	>	AtomPlanIntRow = new Plan<int>(row, nLocal_);
119	>	AtomPlanRealRow = new Plan<RealType>(row, nLocal_);
120	>	AtomPlanVectorRow = new Plan<Vector3d>(row, nLocal_);
121	>	AtomPlanMatrixRow = new Plan<Mat3x3d>(row, nLocal_);
122	>	AtomPlanPotRow = new Plan<potVec>(row, nLocal_);
123
124	<	cgCommIntRow = new Communicator<Row,int>(nGroups_);
125	<	cgCommVectorRow = new Communicator<Row,Vector3d>(nGroups_);
126	<	cgCommIntColumn = new Communicator<Column,int>(nGroups_);
127	<	cgCommVectorColumn = new Communicator<Column,Vector3d>(nGroups_);
124	>	AtomPlanIntColumn = new Plan<int>(col, nLocal_);
125	>	AtomPlanRealColumn = new Plan<RealType>(col, nLocal_);
126	>	AtomPlanVectorColumn = new Plan<Vector3d>(col, nLocal_);
127	>	AtomPlanMatrixColumn = new Plan<Mat3x3d>(col, nLocal_);
128	>	AtomPlanPotColumn = new Plan<potVec>(col, nLocal_);
129
130	<	nAtomsInRow_ = AtomCommIntRow->getSize();
131	<	nAtomsInCol_ = AtomCommIntColumn->getSize();
132	<	nGroupsInRow_ = cgCommIntRow->getSize();
133	<	nGroupsInCol_ = cgCommIntColumn->getSize();
130	>	cgPlanIntRow = new Plan<int>(row, nGroups_);
131	>	cgPlanVectorRow = new Plan<Vector3d>(row, nGroups_);
132	>	cgPlanIntColumn = new Plan<int>(col, nGroups_);
133	>	cgPlanVectorColumn = new Plan<Vector3d>(col, nGroups_);
134
135	+	nAtomsInRow_ = AtomPlanIntRow->getSize();
136	+	nAtomsInCol_ = AtomPlanIntColumn->getSize();
137	+	nGroupsInRow_ = cgPlanIntRow->getSize();
138	+	nGroupsInCol_ = cgPlanIntColumn->getSize();
139	+
140		// Modify the data storage objects with the correct layouts and sizes:
141		atomRowData.resize(nAtomsInRow_);
142		atomRowData.setStorageLayout(storageLayout_);
#	Line 109 \| Line 150 \| namespace OpenMD {
150		identsRow.resize(nAtomsInRow_);
151		identsCol.resize(nAtomsInCol_);
152
153	<	AtomCommIntRow->gather(idents, identsRow);
154	<	AtomCommIntColumn->gather(idents, identsCol);
153	>	AtomPlanIntRow->gather(idents, identsRow);
154	>	AtomPlanIntColumn->gather(idents, identsCol);
155
156	<	AtomCommIntRow->gather(AtomLocalToGlobal, AtomRowToGlobal);
157	<	AtomCommIntColumn->gather(AtomLocalToGlobal, AtomColToGlobal);
158	<
118	<	cgCommIntRow->gather(cgLocalToGlobal, cgRowToGlobal);
119	<	cgCommIntColumn->gather(cgLocalToGlobal, cgColToGlobal);
156	>	// allocate memory for the parallel objects
157	>	atypesRow.resize(nAtomsInRow_);
158	>	atypesCol.resize(nAtomsInCol_);
159
160	<	AtomCommRealRow->gather(massFactors, massFactorsRow);
161	<	AtomCommRealColumn->gather(massFactors, massFactorsCol);
160	>	for (int i = 0; i < nAtomsInRow_; i++)
161	>	atypesRow[i] = ff_->getAtomType(identsRow[i]);
162	>	for (int i = 0; i < nAtomsInCol_; i++)
163	>	atypesCol[i] = ff_->getAtomType(identsCol[i]);
164
165	+	pot_row.resize(nAtomsInRow_);
166	+	pot_col.resize(nAtomsInCol_);
167	+
168	+	AtomRowToGlobal.resize(nAtomsInRow_);
169	+	AtomColToGlobal.resize(nAtomsInCol_);
170	+	AtomPlanIntRow->gather(AtomLocalToGlobal, AtomRowToGlobal);
171	+	AtomPlanIntColumn->gather(AtomLocalToGlobal, AtomColToGlobal);
172	+
173	+	cgRowToGlobal.resize(nGroupsInRow_);
174	+	cgColToGlobal.resize(nGroupsInCol_);
175	+	cgPlanIntRow->gather(cgLocalToGlobal, cgRowToGlobal);
176	+	cgPlanIntColumn->gather(cgLocalToGlobal, cgColToGlobal);
177	+
178	+	massFactorsRow.resize(nAtomsInRow_);
179	+	massFactorsCol.resize(nAtomsInCol_);
180	+	AtomPlanRealRow->gather(massFactors, massFactorsRow);
181	+	AtomPlanRealColumn->gather(massFactors, massFactorsCol);
182	+
183		groupListRow_.clear();
184		groupListRow_.resize(nGroupsInRow_);
185		for (int i = 0; i < nGroupsInRow_; i++) {
#	Line 171 \| Line 230 \| namespace OpenMD {
230		topoDist[i].push_back(3);
231		}
232		}
174	–	}
175	–	}
176	–	}
177	–
178	–	#endif
179	–
180	–	groupList_.clear();
181	–	groupList_.resize(nGroups_);
182	–	for (int i = 0; i < nGroups_; i++) {
183	–	int gid = cgLocalToGlobal[i];
184	–	for (int j = 0; j < nLocal_; j++) {
185	–	int aid = AtomLocalToGlobal[j];
186	–	if (globalGroupMembership[aid] == gid) {
187	–	groupList_[i].push_back(j);
233		}
234		}
235		}
236
237	+	#else
238		excludesForAtom.clear();
239		excludesForAtom.resize(nLocal_);
240		toposForAtom.clear();
#	Line 221 \| Line 267 \| namespace OpenMD {
267		}
268		}
269		}
270	<
270	>	#endif
271	>
272	>	// allocate memory for the parallel objects
273	>	atypesLocal.resize(nLocal_);
274	>
275	>	for (int i = 0; i < nLocal_; i++)
276	>	atypesLocal[i] = ff_->getAtomType(idents[i]);
277	>
278	>	groupList_.clear();
279	>	groupList_.resize(nGroups_);
280	>	for (int i = 0; i < nGroups_; i++) {
281	>	int gid = cgLocalToGlobal[i];
282	>	for (int j = 0; j < nLocal_; j++) {
283	>	int aid = AtomLocalToGlobal[j];
284	>	if (globalGroupMembership[aid] == gid) {
285	>	groupList_[i].push_back(j);
286	>	}
287	>	}
288	>	}
289	>
290	>
291		createGtypeCutoffMap();
292
293		}
#	Line 229 \| Line 295 \| namespace OpenMD {
295		void ForceMatrixDecomposition::createGtypeCutoffMap() {
296
297		RealType tol = 1e-6;
298	+	largestRcut_ = 0.0;
299		RealType rc;
300		int atid;
301		set<AtomType*> atypes = info_->getSimulatedAtomTypes();
302	+
303		map<int, RealType> atypeCutoff;
304
305		for (set<AtomType*>::iterator at = atypes.begin();
#	Line 239 \| Line 307 \| namespace OpenMD {
307		atid = (*at)->getIdent();
308		if (userChoseCutoff_)
309		atypeCutoff[atid] = userCutoff_;
310	<	else
310	>	else
311		atypeCutoff[atid] = interactionMan_->getSuggestedCutoffRadius(*at);
312		}
313	<
313	>
314		vector<RealType> gTypeCutoffs;
315		// first we do a single loop over the cutoff groups to find the
316		// largest cutoff for any atypes present in this group.
#	Line 302 \| Line 370 \| namespace OpenMD {
370		vector<RealType> groupCutoff(nGroups_, 0.0);
371		groupToGtype.resize(nGroups_);
372		for (int cg1 = 0; cg1 < nGroups_; cg1++) {
305	–
373		groupCutoff[cg1] = 0.0;
374		vector<int> atomList = getAtomsInGroupRow(cg1);
308	–
375		for (vector<int>::iterator ia = atomList.begin();
376		ia != atomList.end(); ++ia) {
377		int atom1 = (*ia);
378		atid = idents[atom1];
379	<	if (atypeCutoff[atid] > groupCutoff[cg1]) {
379	>	if (atypeCutoff[atid] > groupCutoff[cg1])
380		groupCutoff[cg1] = atypeCutoff[atid];
315	–	}
381		}
382	<
382	>
383		bool gTypeFound = false;
384		for (int gt = 0; gt < gTypeCutoffs.size(); gt++) {
385		if (abs(groupCutoff[cg1] - gTypeCutoffs[gt]) < tol) {
#	Line 322 \| Line 387 \| namespace OpenMD {
387		gTypeFound = true;
388		}
389		}
390	<	if (!gTypeFound) {
390	>	if (!gTypeFound) {
391		gTypeCutoffs.push_back( groupCutoff[cg1] );
392		groupToGtype[cg1] = gTypeCutoffs.size() - 1;
393		}
#	Line 331 \| Line 396 \| namespace OpenMD {
396
397		// Now we find the maximum group cutoff value present in the simulation
398
399	<	RealType groupMax = *max_element(gTypeCutoffs.begin(), gTypeCutoffs.end());
399	>	RealType groupMax = *max_element(gTypeCutoffs.begin(),
400	>	gTypeCutoffs.end());
401
402		#ifdef IS_MPI
403	<	MPI::COMM_WORLD.Allreduce(&groupMax, &groupMax, 1, MPI::REALTYPE, MPI::MAX);
403	>	MPI::COMM_WORLD.Allreduce(&groupMax, &groupMax, 1, MPI::REALTYPE,
404	>	MPI::MAX);
405		#endif
406
407		RealType tradRcut = groupMax;
#	Line 364 \| Line 431 \| namespace OpenMD {
431
432		pair<int,int> key = make_pair(i,j);
433		gTypeCutoffMap[key].first = thisRcut;
367	–
434		if (thisRcut > largestRcut_) largestRcut_ = thisRcut;
369	–
435		gTypeCutoffMap[key].second = thisRcut*thisRcut;
371	–
436		gTypeCutoffMap[key].third = pow(thisRcut + skinThickness_, 2);
373	–
437		// sanity check
438
439		if (userChoseCutoff_) {
#	Line 430 \| Line 493 \| namespace OpenMD {
493		Vector<RealType, N_INTERACTION_FAMILIES> (0.0));
494
495		if (storageLayout_ & DataStorage::dslParticlePot) {
496	<	fill(atomRowData.particlePot.begin(), atomRowData.particlePot.end(), 0.0);
497	<	fill(atomColData.particlePot.begin(), atomColData.particlePot.end(), 0.0);
496	>	fill(atomRowData.particlePot.begin(), atomRowData.particlePot.end(),
497	>	0.0);
498	>	fill(atomColData.particlePot.begin(), atomColData.particlePot.end(),
499	>	0.0);
500		}
501
502		if (storageLayout_ & DataStorage::dslDensity) {
#	Line 440 \| Line 505 \| namespace OpenMD {
505		}
506
507		if (storageLayout_ & DataStorage::dslFunctional) {
508	<	fill(atomRowData.functional.begin(), atomRowData.functional.end(), 0.0);
509	<	fill(atomColData.functional.begin(), atomColData.functional.end(), 0.0);
508	>	fill(atomRowData.functional.begin(), atomRowData.functional.end(),
509	>	0.0);
510	>	fill(atomColData.functional.begin(), atomColData.functional.end(),
511	>	0.0);
512		}
513
514		if (storageLayout_ & DataStorage::dslFunctionalDerivative) {
#	Line 458 \| Line 525 \| namespace OpenMD {
525		atomColData.skippedCharge.end(), 0.0);
526		}
527
528	<	#else
529	<
528	>	if (storageLayout_ & DataStorage::dslElectricField) {
529	>	fill(atomRowData.electricField.begin(),
530	>	atomRowData.electricField.end(), V3Zero);
531	>	fill(atomColData.electricField.begin(),
532	>	atomColData.electricField.end(), V3Zero);
533	>	}
534	>	if (storageLayout_ & DataStorage::dslFlucQForce) {
535	>	fill(atomRowData.flucQFrc.begin(), atomRowData.flucQFrc.end(),
536	>	0.0);
537	>	fill(atomColData.flucQFrc.begin(), atomColData.flucQFrc.end(),
538	>	0.0);
539	>	}
540	>
541	>	#endif
542	>	// even in parallel, we need to zero out the local arrays:
543	>
544		if (storageLayout_ & DataStorage::dslParticlePot) {
545		fill(snap_->atomData.particlePot.begin(),
546		snap_->atomData.particlePot.end(), 0.0);
#	Line 469 \| Line 550 \| namespace OpenMD {
550		fill(snap_->atomData.density.begin(),
551		snap_->atomData.density.end(), 0.0);
552		}
553	+
554		if (storageLayout_ & DataStorage::dslFunctional) {
555		fill(snap_->atomData.functional.begin(),
556		snap_->atomData.functional.end(), 0.0);
557		}
558	+
559		if (storageLayout_ & DataStorage::dslFunctionalDerivative) {
560		fill(snap_->atomData.functionalDerivative.begin(),
561		snap_->atomData.functionalDerivative.end(), 0.0);
562		}
563	+
564		if (storageLayout_ & DataStorage::dslSkippedCharge) {
565		fill(snap_->atomData.skippedCharge.begin(),
566		snap_->atomData.skippedCharge.end(), 0.0);
567		}
568	<	#endif
569	<
568	>
569	>	if (storageLayout_ & DataStorage::dslElectricField) {
570	>	fill(snap_->atomData.electricField.begin(),
571	>	snap_->atomData.electricField.end(), V3Zero);
572	>	}
573		}
574
575
#	Line 492 \| Line 579 \| namespace OpenMD {
579		#ifdef IS_MPI
580
581		// gather up the atomic positions
582	<	AtomCommVectorRow->gather(snap_->atomData.position,
582	>	AtomPlanVectorRow->gather(snap_->atomData.position,
583		atomRowData.position);
584	<	AtomCommVectorColumn->gather(snap_->atomData.position,
584	>	AtomPlanVectorColumn->gather(snap_->atomData.position,
585		atomColData.position);
586
587		// gather up the cutoff group positions
588	<	cgCommVectorRow->gather(snap_->cgData.position,
588	>
589	>	cgPlanVectorRow->gather(snap_->cgData.position,
590		cgRowData.position);
591	<	cgCommVectorColumn->gather(snap_->cgData.position,
591	>
592	>	cgPlanVectorColumn->gather(snap_->cgData.position,
593		cgColData.position);
594	+
595
596		// if needed, gather the atomic rotation matrices
597		if (storageLayout_ & DataStorage::dslAmat) {
598	<	AtomCommMatrixRow->gather(snap_->atomData.aMat,
598	>	AtomPlanMatrixRow->gather(snap_->atomData.aMat,
599		atomRowData.aMat);
600	<	AtomCommMatrixColumn->gather(snap_->atomData.aMat,
600	>	AtomPlanMatrixColumn->gather(snap_->atomData.aMat,
601		atomColData.aMat);
602		}
603
604		// if needed, gather the atomic eletrostatic frames
605		if (storageLayout_ & DataStorage::dslElectroFrame) {
606	<	AtomCommMatrixRow->gather(snap_->atomData.electroFrame,
606	>	AtomPlanMatrixRow->gather(snap_->atomData.electroFrame,
607		atomRowData.electroFrame);
608	<	AtomCommMatrixColumn->gather(snap_->atomData.electroFrame,
608	>	AtomPlanMatrixColumn->gather(snap_->atomData.electroFrame,
609		atomColData.electroFrame);
610		}
611	+
612	+	// if needed, gather the atomic fluctuating charge values
613	+	if (storageLayout_ & DataStorage::dslFlucQPosition) {
614	+	AtomPlanRealRow->gather(snap_->atomData.flucQPos,
615	+	atomRowData.flucQPos);
616	+	AtomPlanRealColumn->gather(snap_->atomData.flucQPos,
617	+	atomColData.flucQPos);
618	+	}
619	+
620		#endif
621		}
622
#	Line 531 \| Line 630 \| namespace OpenMD {
630
631		if (storageLayout_ & DataStorage::dslDensity) {
632
633	<	AtomCommRealRow->scatter(atomRowData.density,
633	>	AtomPlanRealRow->scatter(atomRowData.density,
634		snap_->atomData.density);
635
636		int n = snap_->atomData.density.size();
637		vector<RealType> rho_tmp(n, 0.0);
638	<	AtomCommRealColumn->scatter(atomColData.density, rho_tmp);
638	>	AtomPlanRealColumn->scatter(atomColData.density, rho_tmp);
639		for (int i = 0; i < n; i++)
640		snap_->atomData.density[i] += rho_tmp[i];
641		}
642	+
643	+	if (storageLayout_ & DataStorage::dslElectricField) {
644	+
645	+	AtomPlanVectorRow->scatter(atomRowData.electricField,
646	+	snap_->atomData.electricField);
647	+
648	+	int n = snap_->atomData.electricField.size();
649	+	vector<Vector3d> field_tmp(n, V3Zero);
650	+	AtomPlanVectorColumn->scatter(atomColData.electricField, field_tmp);
651	+	for (int i = 0; i < n; i++)
652	+	snap_->atomData.electricField[i] += field_tmp[i];
653	+	}
654		#endif
655		}
656
#	Line 552 \| Line 663 \| namespace OpenMD {
663		storageLayout_ = sman_->getStorageLayout();
664		#ifdef IS_MPI
665		if (storageLayout_ & DataStorage::dslFunctional) {
666	<	AtomCommRealRow->gather(snap_->atomData.functional,
666	>	AtomPlanRealRow->gather(snap_->atomData.functional,
667		atomRowData.functional);
668	<	AtomCommRealColumn->gather(snap_->atomData.functional,
668	>	AtomPlanRealColumn->gather(snap_->atomData.functional,
669		atomColData.functional);
670		}
671
672		if (storageLayout_ & DataStorage::dslFunctionalDerivative) {
673	<	AtomCommRealRow->gather(snap_->atomData.functionalDerivative,
673	>	AtomPlanRealRow->gather(snap_->atomData.functionalDerivative,
674		atomRowData.functionalDerivative);
675	<	AtomCommRealColumn->gather(snap_->atomData.functionalDerivative,
675	>	AtomPlanRealColumn->gather(snap_->atomData.functionalDerivative,
676		atomColData.functionalDerivative);
677		}
678		#endif
#	Line 575 \| Line 686 \| namespace OpenMD {
686		int n = snap_->atomData.force.size();
687		vector<Vector3d> frc_tmp(n, V3Zero);
688
689	<	AtomCommVectorRow->scatter(atomRowData.force, frc_tmp);
689	>	AtomPlanVectorRow->scatter(atomRowData.force, frc_tmp);
690		for (int i = 0; i < n; i++) {
691		snap_->atomData.force[i] += frc_tmp[i];
692		frc_tmp[i] = 0.0;
693		}
694
695	<	AtomCommVectorColumn->scatter(atomColData.force, frc_tmp);
696	<	for (int i = 0; i < n; i++)
695	>	AtomPlanVectorColumn->scatter(atomColData.force, frc_tmp);
696	>	for (int i = 0; i < n; i++) {
697		snap_->atomData.force[i] += frc_tmp[i];
698	<
699	<
698	>	}
699	>
700		if (storageLayout_ & DataStorage::dslTorque) {
701
702		int nt = snap_->atomData.torque.size();
703		vector<Vector3d> trq_tmp(nt, V3Zero);
704
705	<	AtomCommVectorRow->scatter(atomRowData.torque, trq_tmp);
705	>	AtomPlanVectorRow->scatter(atomRowData.torque, trq_tmp);
706		for (int i = 0; i < nt; i++) {
707		snap_->atomData.torque[i] += trq_tmp[i];
708		trq_tmp[i] = 0.0;
709		}
710
711	<	AtomCommVectorColumn->scatter(atomColData.torque, trq_tmp);
711	>	AtomPlanVectorColumn->scatter(atomColData.torque, trq_tmp);
712		for (int i = 0; i < nt; i++)
713		snap_->atomData.torque[i] += trq_tmp[i];
714		}
#	Line 607 \| Line 718 \| namespace OpenMD {
718		int ns = snap_->atomData.skippedCharge.size();
719		vector<RealType> skch_tmp(ns, 0.0);
720
721	<	AtomCommRealRow->scatter(atomRowData.skippedCharge, skch_tmp);
721	>	AtomPlanRealRow->scatter(atomRowData.skippedCharge, skch_tmp);
722		for (int i = 0; i < ns; i++) {
723	<	snap_->atomData.skippedCharge[i] = skch_tmp[i];
723	>	snap_->atomData.skippedCharge[i] += skch_tmp[i];
724		skch_tmp[i] = 0.0;
725		}
726
727	<	AtomCommRealColumn->scatter(atomColData.skippedCharge, skch_tmp);
728	<	for (int i = 0; i < ns; i++)
727	>	AtomPlanRealColumn->scatter(atomColData.skippedCharge, skch_tmp);
728	>	for (int i = 0; i < ns; i++)
729		snap_->atomData.skippedCharge[i] += skch_tmp[i];
730	+
731		}
732
733	+	if (storageLayout_ & DataStorage::dslFlucQForce) {
734	+
735	+	int nq = snap_->atomData.flucQFrc.size();
736	+	vector<RealType> fqfrc_tmp(nq, 0.0);
737	+
738	+	AtomPlanRealRow->scatter(atomRowData.flucQFrc, fqfrc_tmp);
739	+	for (int i = 0; i < nq; i++) {
740	+	snap_->atomData.flucQFrc[i] += fqfrc_tmp[i];
741	+	fqfrc_tmp[i] = 0.0;
742	+	}
743	+
744	+	AtomPlanRealColumn->scatter(atomColData.flucQFrc, fqfrc_tmp);
745	+	for (int i = 0; i < nq; i++)
746	+	snap_->atomData.flucQFrc[i] += fqfrc_tmp[i];
747	+
748	+	}
749	+
750		nLocal_ = snap_->getNumberOfAtoms();
751
752		vector<potVec> pot_temp(nLocal_,
#	Line 625 \| Line 754 \| namespace OpenMD {
754
755		// scatter/gather pot_row into the members of my column
756
757	<	AtomCommPotRow->scatter(pot_row, pot_temp);
757	>	AtomPlanPotRow->scatter(pot_row, pot_temp);
758
759		for (int ii = 0; ii < pot_temp.size(); ii++ )
760		pairwisePot += pot_temp[ii];
#	Line 633 \| Line 762 \| namespace OpenMD {
762		fill(pot_temp.begin(), pot_temp.end(),
763		Vector<RealType, N_INTERACTION_FAMILIES> (0.0));
764
765	<	AtomCommPotColumn->scatter(pot_col, pot_temp);
765	>	AtomPlanPotColumn->scatter(pot_col, pot_temp);
766
767		for (int ii = 0; ii < pot_temp.size(); ii++ )
768		pairwisePot += pot_temp[ii];
769	+
770	+	for (int ii = 0; ii < N_INTERACTION_FAMILIES; ii++) {
771	+	RealType ploc1 = pairwisePot[ii];
772	+	RealType ploc2 = 0.0;
773	+	MPI::COMM_WORLD.Allreduce(&ploc1, &ploc2, 1, MPI::REALTYPE, MPI::SUM);
774	+	pairwisePot[ii] = ploc2;
775	+	}
776	+
777	+	for (int ii = 0; ii < N_INTERACTION_FAMILIES; ii++) {
778	+	RealType ploc1 = embeddingPot[ii];
779	+	RealType ploc2 = 0.0;
780	+	MPI::COMM_WORLD.Allreduce(&ploc1, &ploc2, 1, MPI::REALTYPE, MPI::SUM);
781	+	embeddingPot[ii] = ploc2;
782	+	}
783	+
784		#endif
785
786		}
#	Line 749 \| Line 893 \| namespace OpenMD {
893		*/
894		bool ForceMatrixDecomposition::skipAtomPair(int atom1, int atom2) {
895		int unique_id_1, unique_id_2;
896	<
896	>
897		#ifdef IS_MPI
898		// in MPI, we have to look up the unique IDs for each atom
899		unique_id_1 = AtomRowToGlobal[atom1];
900		unique_id_2 = AtomColToGlobal[atom2];
901	+	#else
902	+	unique_id_1 = AtomLocalToGlobal[atom1];
903	+	unique_id_2 = AtomLocalToGlobal[atom2];
904	+	#endif
905
758	–	// this situation should only arise in MPI simulations
906		if (unique_id_1 == unique_id_2) return true;
907	<
907	>
908	>	#ifdef IS_MPI
909		// this prevents us from doing the pair on multiple processors
910		if (unique_id_1 < unique_id_2) {
911		if ((unique_id_1 + unique_id_2) % 2 == 0) return true;
912		} else {
913	<	if ((unique_id_1 + unique_id_2) % 2 == 1) return true;
913	>	if ((unique_id_1 + unique_id_2) % 2 == 1) return true;
914		}
915		#endif
916	+
917		return false;
918		}
919
#	Line 778 \| Line 927 \| namespace OpenMD {
927		* field) must still be handled for these pairs.
928		*/
929		bool ForceMatrixDecomposition::excludeAtomPair(int atom1, int atom2) {
930	<	int unique_id_2;
930	>
931	>	// excludesForAtom was constructed to use row/column indices in the MPI
932	>	// version, and to use local IDs in the non-MPI version:
933
783	–	#ifdef IS_MPI
784	–	// in MPI, we have to look up the unique IDs for the row atom.
785	–	unique_id_2 = AtomColToGlobal[atom2];
786	–	#else
787	–	// in the normal loop, the atom numbers are unique
788	–	unique_id_2 = atom2;
789	–	#endif
790	–
934		for (vector<int>::iterator i = excludesForAtom[atom1].begin();
935		i != excludesForAtom[atom1].end(); ++i) {
936	<	if ( (*i) == unique_id_2 ) return true;
936	>	if ( (*i) == atom2 ) return true;
937		}
938
939		return false;
#	Line 820 \| Line 963 \| namespace OpenMD {
963		idat.excluded = excludeAtomPair(atom1, atom2);
964
965		#ifdef IS_MPI
966	+	idat.atypes = make_pair( atypesRow[atom1], atypesCol[atom2]);
967	+	//idat.atypes = make_pair( ff_->getAtomType(identsRow[atom1]),
968	+	// ff_->getAtomType(identsCol[atom2]) );
969
824	–	idat.atypes = make_pair( ff_->getAtomType(identsRow[atom1]),
825	–	ff_->getAtomType(identsCol[atom2]) );
826	–
970		if (storageLayout_ & DataStorage::dslAmat) {
971		idat.A1 = &(atomRowData.aMat[atom1]);
972		idat.A2 = &(atomColData.aMat[atom2]);
#	Line 865 \| Line 1008 \| namespace OpenMD {
1008		}
1009
1010		#else
1011	+
1012
1013	<	idat.atypes = make_pair( ff_->getAtomType(idents[atom1]),
1014	<	ff_->getAtomType(idents[atom2]) );
1013	>	// cerr << "atoms = " << atom1 << " " << atom2 << "\n";
1014	>	// cerr << "pos1 = " << snap_->atomData.position[atom1] << "\n";
1015	>	// cerr << "pos2 = " << snap_->atomData.position[atom2] << "\n";
1016	>
1017	>	idat.atypes = make_pair( atypesLocal[atom1], atypesLocal[atom2]);
1018	>	//idat.atypes = make_pair( ff_->getAtomType(idents[atom1]),
1019	>	// ff_->getAtomType(idents[atom2]) );
1020
1021		if (storageLayout_ & DataStorage::dslAmat) {
1022		idat.A1 = &(snap_->atomData.aMat[atom1]);
#	Line 914 \| Line 1063 \| namespace OpenMD {
1063
1064		void ForceMatrixDecomposition::unpackInteractionData(InteractionData &idat, int atom1, int atom2) {
1065		#ifdef IS_MPI
1066	<	pot_row[atom1] += 0.5 * *(idat.pot);
1067	<	pot_col[atom2] += 0.5 * *(idat.pot);
1066	>	pot_row[atom1] += RealType(0.5) * *(idat.pot);
1067	>	pot_col[atom2] += RealType(0.5) * *(idat.pot);
1068
1069		atomRowData.force[atom1] += *(idat.f1);
1070		atomColData.force[atom2] -= *(idat.f1);
1071	+
1072	+	// should particle pot be done here also?
1073		#else
1074		pairwisePot += *(idat.pot);
1075
1076		snap_->atomData.force[atom1] += *(idat.f1);
1077		snap_->atomData.force[atom2] -= *(idat.f1);
1078	+
1079	+	if (idat.doParticlePot) {
1080	+	snap_->atomData.particlePot[atom1] += (idat.vpair) *(idat.sw);
1081	+	snap_->atomData.particlePot[atom2] -= (idat.vpair) *(idat.sw);
1082	+	}
1083	+
1084		#endif
1085
1086		}
#	Line 1005 \| Line 1162 \| namespace OpenMD {
1162		// add this cutoff group to the list of groups in this cell;
1163		cellListRow_[cellIndex].push_back(i);
1164		}
1008	–
1165		for (int i = 0; i < nGroupsInCol_; i++) {
1166		rs = cgColData.position[i];
1167
#	Line 1030 \| Line 1186 \| namespace OpenMD {
1186		// add this cutoff group to the list of groups in this cell;
1187		cellListCol_[cellIndex].push_back(i);
1188		}
1189	+
1190		#else
1191		for (int i = 0; i < nGroups_; i++) {
1192		rs = snap_->cgData.position[i];
#	Line 1050 \| Line 1207 \| namespace OpenMD {
1207		whichCell.z() = nCells_.z() * scaled.z();
1208
1209		// find single index of this cell:
1210	<	cellIndex = Vlinear(whichCell, nCells_);
1210	>	cellIndex = Vlinear(whichCell, nCells_);
1211
1212		// add this cutoff group to the list of groups in this cell;
1213		cellList_[cellIndex].push_back(i);
1214		}
1215	+
1216		#endif
1217
1218		for (int m1z = 0; m1z < nCells_.z(); m1z++) {
#	Line 1067 \| Line 1225 \| namespace OpenMD {
1225		os != cellOffsets_.end(); ++os) {
1226
1227		Vector3i m2v = m1v + (*os);
1228	<
1228	>
1229	>
1230		if (m2v.x() >= nCells_.x()) {
1231		m2v.x() = 0;
1232		} else if (m2v.x() < 0) {
#	Line 1085 \| Line 1244 \| namespace OpenMD {
1244		} else if (m2v.z() < 0) {
1245		m2v.z() = nCells_.z() - 1;
1246		}
1247	<
1247	>
1248		int m2 = Vlinear (m2v, nCells_);
1249
1250		#ifdef IS_MPI
#	Line 1093 \| Line 1252 \| namespace OpenMD {
1252		j1 != cellListRow_[m1].end(); ++j1) {
1253		for (vector<int>::iterator j2 = cellListCol_[m2].begin();
1254		j2 != cellListCol_[m2].end(); ++j2) {
1096	–
1097	–	// Always do this if we're in different cells or if
1098	–	// we're in the same cell and the global index of the
1099	–	// j2 cutoff group is less than the j1 cutoff group
1255
1256	<	if (m2 != m1 \|\| cgColToGlobal[(j2)] < cgRowToGlobal[(j1)]) {
1257	<	dr = cgColData.position[(j2)] - cgRowData.position[(j1)];
1258	<	snap_->wrapVector(dr);
1259	<	cuts = getGroupCutoffs( (j1), (j2) );
1260	<	if (dr.lengthSquare() < cuts.third) {
1261	<	neighborList.push_back(make_pair((j1), (j2)));
1262	<	}
1263	<	}
1256	>	// In parallel, we need to visit all pairs of row
1257	>	// & column indicies and will divide labor in the
1258	>	// force evaluation later.
1259	>	dr = cgColData.position[(j2)] - cgRowData.position[(j1)];
1260	>	snap_->wrapVector(dr);
1261	>	cuts = getGroupCutoffs( (j1), (j2) );
1262	>	if (dr.lengthSquare() < cuts.third) {
1263	>	neighborList.push_back(make_pair((j1), (j2)));
1264	>	}
1265		}
1266		}
1267		#else
1112	–
1268		for (vector<int>::iterator j1 = cellList_[m1].begin();
1269		j1 != cellList_[m1].end(); ++j1) {
1270		for (vector<int>::iterator j2 = cellList_[m2].begin();
1271		j2 != cellList_[m2].end(); ++j2) {
1272	<
1272	>
1273		// Always do this if we're in different cells or if
1274	<	// we're in the same cell and the global index of the
1275	<	// j2 cutoff group is less than the j1 cutoff group
1276	<
1277	<	if (m2 != m1 \|\| (j2) < (j1)) {
1274	>	// we're in the same cell and the global index of
1275	>	// the j2 cutoff group is greater than or equal to
1276	>	// the j1 cutoff group. Note that Rappaport's code
1277	>	// has a "less than" conditional here, but that
1278	>	// deals with atom-by-atom computation. OpenMD
1279	>	// allows atoms within a single cutoff group to
1280	>	// interact with each other.
1281	>
1282	>
1283	>
1284	>	if (m2 != m1 \|\| (j2) >= (j1) ) {
1285	>
1286		dr = snap_->cgData.position[(j2)] - snap_->cgData.position[(j1)];
1287		snap_->wrapVector(dr);
1288		cuts = getGroupCutoffs( (j1), (j2) );
#	Line 1138 \| Line 1301 \| namespace OpenMD {
1301		// branch to do all cutoff group pairs
1302		#ifdef IS_MPI
1303		for (int j1 = 0; j1 < nGroupsInRow_; j1++) {
1304	<	for (int j2 = 0; j2 < nGroupsInCol_; j2++) {
1304	>	for (int j2 = 0; j2 < nGroupsInCol_; j2++) {
1305		dr = cgColData.position[j2] - cgRowData.position[j1];
1306		snap_->wrapVector(dr);
1307		cuts = getGroupCutoffs( j1, j2 );
#	Line 1146 \| Line 1309 \| namespace OpenMD {
1309		neighborList.push_back(make_pair(j1, j2));
1310		}
1311		}
1312	<	}
1312	>	}
1313		#else
1314	<	for (int j1 = 0; j1 < nGroups_ - 1; j1++) {
1315	<	for (int j2 = j1 + 1; j2 < nGroups_; j2++) {
1314	>	// include all groups here.
1315	>	for (int j1 = 0; j1 < nGroups_; j1++) {
1316	>	// include self group interactions j2 == j1
1317	>	for (int j2 = j1; j2 < nGroups_; j2++) {
1318		dr = snap_->cgData.position[j2] - snap_->cgData.position[j1];
1319		snap_->wrapVector(dr);
1320		cuts = getGroupCutoffs( j1, j2 );
1321		if (dr.lengthSquare() < cuts.third) {
1322		neighborList.push_back(make_pair(j1, j2));
1323		}
1324	<	}
1325	<	}
1324	>	}
1325	>	}
1326		#endif
1327		}
1328

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Comparing branches/development/src/parallel/ForceMatrixDecomposition.cpp (file contents): Revision 1587 by gezelter, Fri Jul 8 20:25:32 2011 UTC vs. Revision 1713 by gezelter, Sat May 19 14:21:02 2012 UTC

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Comparing branches/development/src/parallel/ForceMatrixDecomposition.cpp (file contents):
Revision 1587 by gezelter, Fri Jul 8 20:25:32 2011 UTC vs.
Revision 1713 by gezelter, Sat May 19 14:21:02 2012 UTC