[ViewVC] Diff of: OpenMD/trunk/src/brains/ForceManager.cpp

Comparing trunk/src/brains/ForceManager.cpp (file contents):
Revision 1993 by gezelter, Tue Apr 29 17:32:31 2014 UTC vs.
Revision 2057 by gezelter, Tue Mar 3 15:22:26 2015 UTC

#	Line 57 \| Line 57
57		#include "primitives/Torsion.hpp"
58		#include "primitives/Inversion.hpp"
59		#include "nonbonded/NonBondedInteraction.hpp"
60	<	#include "perturbations/ElectricField.hpp"
60	>	#include "perturbations/UniformField.hpp"
61	>	#include "perturbations/UniformGradient.hpp"
62		#include "parallel/ForceMatrixDecomposition.hpp"
63
64		#include <cstdio>
#	Line 87 \| Line 88 \| namespace OpenMD {
88		/**
89		* setupCutoffs
90		*
91	<	* Sets the values of cutoffRadius, switchingRadius, cutoffMethod,
91	<	* and cutoffPolicy
91	>	* Sets the values of cutoffRadius, switchingRadius, and cutoffMethod
92		*
93		* cutoffRadius : realType
94		* If the cutoffRadius was explicitly set, use that value.
#	Line 102 \| Line 102 \| namespace OpenMD {
102		* SHIFTED_POTENTIAL, or EWALD_FULL)
103		* If cutoffMethod was explicitly set, use that choice.
104		* If cutoffMethod was not explicitly set, use SHIFTED_FORCE
105	–	*
106	–	* cutoffPolicy : (one of MIX, MAX, TRADITIONAL)
107	–	* If cutoffPolicy was explicitly set, use that choice.
108	–	* If cutoffPolicy was not explicitly set, use TRADITIONAL
105		*
106		* switchingRadius : realType
107		* If the cutoffMethod was set to SWITCHED:
#	Line 163 \| Line 159 \| namespace OpenMD {
159		}
160		}
161
162	<	fDecomp_->setUserCutoff(rCut_);
162	>	fDecomp_->setCutoffRadius(rCut_);
163		interactionMan_->setCutoffRadius(rCut_);
164	+	rCutSq_ = rCut_ * rCut_;
165
166		map<string, CutoffMethod> stringToCutoffMethod;
167		stringToCutoffMethod["HARD"] = HARD;
#	Line 273 \| Line 270 \| namespace OpenMD {
270		}
271		}
272		}
276	–	}
277	–
278	–	map<string, CutoffPolicy> stringToCutoffPolicy;
279	–	stringToCutoffPolicy["MIX"] = MIX;
280	–	stringToCutoffPolicy["MAX"] = MAX;
281	–	stringToCutoffPolicy["TRADITIONAL"] = TRADITIONAL;
282	–
283	–	string cutPolicy;
284	–	if (forceFieldOptions_.haveCutoffPolicy()){
285	–	cutPolicy = forceFieldOptions_.getCutoffPolicy();
286	–	}else if (simParams_->haveCutoffPolicy()) {
287	–	cutPolicy = simParams_->getCutoffPolicy();
273		}
289	–
290	–	if (!cutPolicy.empty()){
291	–	toUpper(cutPolicy);
292	–	map<string, CutoffPolicy>::iterator i;
293	–	i = stringToCutoffPolicy.find(cutPolicy);
294	–
295	–	if (i == stringToCutoffPolicy.end()) {
296	–	sprintf(painCave.errMsg,
297	–	"ForceManager::setupCutoffs: Could not find chosen cutoffPolicy %s\n"
298	–	"\tShould be one of: "
299	–	"MIX, MAX, or TRADITIONAL\n",
300	–	cutPolicy.c_str());
301	–	painCave.isFatal = 1;
302	–	painCave.severity = OPENMD_ERROR;
303	–	simError();
304	–	} else {
305	–	cutoffPolicy_ = i->second;
306	–	}
307	–	} else {
308	–	sprintf(painCave.errMsg,
309	–	"ForceManager::setupCutoffs: No value was set for the cutoffPolicy.\n"
310	–	"\tOpenMD will use TRADITIONAL.\n");
311	–	painCave.isFatal = 0;
312	–	painCave.severity = OPENMD_INFO;
313	–	simError();
314	–	cutoffPolicy_ = TRADITIONAL;
315	–	}
316	–
317	–	fDecomp_->setCutoffPolicy(cutoffPolicy_);
274
275		// create the switching function object:
276
#	Line 394 \| Line 350 \| namespace OpenMD {
350		switcher_->setSwitch(rSwitch_, rCut_);
351		}
352
397	–
398	–
399	–
353		void ForceManager::initialize() {
354
355		if (!info_->isTopologyDone()) {
#	Line 405 \| Line 358 \| namespace OpenMD {
358		interactionMan_->setSimInfo(info_);
359		interactionMan_->initialize();
360
361	<	// We want to delay the cutoffs until after the interaction
362	<	// manager has set up the atom-atom interactions so that we can
363	<	// query them for suggested cutoff values
361	>	//! We want to delay the cutoffs until after the interaction
362	>	//! manager has set up the atom-atom interactions so that we can
363	>	//! query them for suggested cutoff values
364		setupCutoffs();
365
366		info_->prepareTopology();
#	Line 423 \| Line 376 \| namespace OpenMD {
376
377		ForceFieldOptions& fopts = forceField_->getForceFieldOptions();
378
379	<	// Force fields can set options on how to scale van der Waals and
380	<	// electrostatic interactions for atoms connected via bonds, bends
381	<	// and torsions in this case the topological distance between
382	<	// atoms is:
383	<	// 0 = topologically unconnected
384	<	// 1 = bonded together
385	<	// 2 = connected via a bend
386	<	// 3 = connected via a torsion
379	>	//! Force fields can set options on how to scale van der Waals and
380	>	//! electrostatic interactions for atoms connected via bonds, bends
381	>	//! and torsions in this case the topological distance between
382	>	//! atoms is:
383	>	//! 0 = topologically unconnected
384	>	//! 1 = bonded together
385	>	//! 2 = connected via a bend
386	>	//! 3 = connected via a torsion
387
388		vdwScale_.reserve(4);
389		fill(vdwScale_.begin(), vdwScale_.end(), 0.0);
#	Line 448 \| Line 401 \| namespace OpenMD {
401		electrostaticScale_[2] = fopts.getelectrostatic13scale();
402		electrostaticScale_[3] = fopts.getelectrostatic14scale();
403
404	<	if (info_->getSimParams()->haveElectricField()) {
405	<	ElectricField* eField = new ElectricField(info_);
404	>	if (info_->getSimParams()->haveUniformField()) {
405	>	UniformField* eField = new UniformField(info_);
406		perturbations_.push_back(eField);
407		}
408	<
408	>	if (info_->getSimParams()->haveUniformGradientStrength() \|\|
409	>	info_->getSimParams()->haveUniformGradientDirection1() \|\|
410	>	info_->getSimParams()->haveUniformGradientDirection2() ) {
411	>	UniformGradient* eGrad = new UniformGradient(info_);
412	>	perturbations_.push_back(eGrad);
413	>	}
414	>
415		usePeriodicBoundaryConditions_ = info_->getSimParams()->getUsePeriodicBoundaryConditions();
416
417		fDecomp_->distributeInitialData();
#	Line 667 \| Line 626 \| namespace OpenMD {
626		Snapshot* curSnapshot = info_->getSnapshotManager()->getCurrentSnapshot();
627		DataStorage* config = &(curSnapshot->atomData);
628		DataStorage* cgConfig = &(curSnapshot->cgData);
629	+	int jstart, jend;
630
671	–
631		//calculate the center of mass of cutoff group
632
633		SimInfo::MoleculeIterator mi;
634		Molecule* mol;
635		Molecule::CutoffGroupIterator ci;
636		CutoffGroup* cg;
637	<
638	<	if(info_->getNCutoffGroups() > 0){
637	>
638	>	if(info_->getNCutoffGroups() != info_->getNAtoms()){
639		for (mol = info_->beginMolecule(mi); mol != NULL;
640		mol = info_->nextMolecule(mi)) {
641		for(cg = mol->beginCutoffGroup(ci); cg != NULL;
#	Line 719 \| Line 678 \| namespace OpenMD {
678		Vector3d eField2(0.0);
679		RealType sPot1(0.0);
680		RealType sPot2(0.0);
681	+	bool newAtom1;
682
683		vector<int>::iterator ia, jb;
684
685		int loopStart, loopEnd;
686
687	<	idat.rcut = &rCut;
687	>	idat.rcut = &rCut_;
688		idat.vdwMult = &vdwMult;
689		idat.electroMult = &electroMult;
690		idat.pot = &workPot;
#	Line 741 \| Line 701 \| namespace OpenMD {
701		idat.f1 = &f1;
702		idat.sw = &sw;
703		idat.shiftedPot = (cutoffMethod_ == SHIFTED_POTENTIAL) ? true : false;
704	<	idat.shiftedForce = (cutoffMethod_ == SHIFTED_FORCE \|\| cutoffMethod_ == TAYLOR_SHIFTED) ? true : false;
704	>	idat.shiftedForce = (cutoffMethod_ == SHIFTED_FORCE \|\|
705	>	cutoffMethod_ == TAYLOR_SHIFTED) ? true : false;
706		idat.doParticlePot = doParticlePot_;
707		idat.doElectricField = doElectricField_;
708		idat.doSitePotential = doSitePotential_;
#	Line 760 \| Line 721 \| namespace OpenMD {
721		if (update_nlist) {
722		if (!usePeriodicBoundaryConditions_)
723		Mat3x3d bbox = thermo->getBoundingBox();
724	<	fDecomp_->buildNeighborList(neighborList_);
724	>	fDecomp_->buildNeighborList(neighborList_, point_);
725		}
726		}
727
728	<	for (vector<pair<int, int> >::iterator it = neighborList_.begin();
768	<	it != neighborList_.end(); ++it) {
769	<
770	<	cg1 = (*it).first;
771	<	cg2 = (*it).second;
728	>	for (unsigned int cg1 = 0; cg1 < point_.size() - 1; cg1++) {
729
730	<	fDecomp_->getGroupCutoffs(cg1, cg2, rCut, rCutSq, rListSq);
730	>	atomListRow = fDecomp_->getAtomsInGroupRow(cg1);
731	>	newAtom1 = true;
732	>
733	>	for (int m2 = point_[cg1]; m2 < point_[cg1+1]; m2++) {
734
735	<	d_grp = fDecomp_->getIntergroupVector(cg1, cg2);
776	<
777	<	// already wrapped in the getIntergroupVector call:
778	<	// curSnapshot->wrapVector(d_grp);
779	<	rgrpsq = d_grp.lengthSquare();
780	<
781	<	if (rgrpsq < rCutSq) {
782	<	if (iLoop == PAIR_LOOP) {
783	<	vij = 0.0;
784	<	fij.zero();
785	<	eField1.zero();
786	<	eField2.zero();
787	<	sPot1 = 0.0;
788	<	sPot2 = 0.0;
789	<	}
735	>	cg2 = neighborList_[m2];
736
737	<	in_switching_region = switcher_->getSwitch(rgrpsq, sw, dswdr,
738	<	rgrp);
739	<
740	<	atomListRow = fDecomp_->getAtomsInGroupRow(cg1);
741	<	atomListColumn = fDecomp_->getAtomsInGroupColumn(cg2);
742	<
743	<	if (doHeatFlux_)
744	<	gvel2 = fDecomp_->getGroupVelocityColumn(cg2);
745	<
746	<	for (ia = atomListRow.begin();
747	<	ia != atomListRow.end(); ++ia) {
748	<	atom1 = (*ia);
749	<
750	<	for (jb = atomListColumn.begin();
751	<	jb != atomListColumn.end(); ++jb) {
752	<	atom2 = (*jb);
753	<
754	<	if (!fDecomp_->skipAtomPair(atom1, atom2, cg1, cg2)) {
755	<
756	<	vpair = 0.0;
757	<	workPot = 0.0;
758	<	exPot = 0.0;
759	<	f1.zero();
760	<	dVdFQ1 = 0.0;
761	<	dVdFQ2 = 0.0;
762	<
763	<	fDecomp_->fillInteractionData(idat, atom1, atom2);
764	<
765	<	topoDist = fDecomp_->getTopologicalDistance(atom1, atom2);
766	<	vdwMult = vdwScale_[topoDist];
767	<	electroMult = electrostaticScale_[topoDist];
768	<
769	<	if (atomListRow.size() == 1 && atomListColumn.size() == 1) {
770	<	idat.d = &d_grp;
771	<	idat.r2 = &rgrpsq;
772	<	if (doHeatFlux_)
773	<	vel2 = gvel2;
774	<	} else {
775	<	d = fDecomp_->getInteratomicVector(atom1, atom2);
776	<	curSnapshot->wrapVector( d );
777	<	r2 = d.lengthSquare();
778	<	idat.d = &d;
779	<	idat.r2 = &r2;
780	<	if (doHeatFlux_)
781	<	vel2 = fDecomp_->getAtomVelocityColumn(atom2);
782	<	}
783	<
784	<	r = sqrt( *(idat.r2) );
785	<	idat.rij = &r;
786	<
787	<	if (iLoop == PREPAIR_LOOP) {
788	<	interactionMan_->doPrePair(idat);
789	<	} else {
790	<	interactionMan_->doPair(idat);
791	<	fDecomp_->unpackInteractionData(idat, atom1, atom2);
792	<	vij += vpair;
793	<	fij += f1;
794	<	stressTensor -= outProduct( *(idat.d), f1);
795	<	if (doHeatFlux_)
796	<	fDecomp_->addToHeatFlux((idat.d) dot(f1, vel2));
737	>	d_grp = fDecomp_->getIntergroupVector(cg1, cg2);
738	>
739	>	// already wrapped in the getIntergroupVector call:
740	>	// curSnapshot->wrapVector(d_grp);
741	>	rgrpsq = d_grp.lengthSquare();
742	>
743	>	if (rgrpsq < rCutSq_) {
744	>	if (iLoop == PAIR_LOOP) {
745	>	vij = 0.0;
746	>	fij.zero();
747	>	eField1.zero();
748	>	eField2.zero();
749	>	sPot1 = 0.0;
750	>	sPot2 = 0.0;
751	>	}
752	>
753	>	in_switching_region = switcher_->getSwitch(rgrpsq, sw, dswdr,
754	>	rgrp);
755	>
756	>	atomListColumn = fDecomp_->getAtomsInGroupColumn(cg2);
757	>
758	>	if (doHeatFlux_)
759	>	gvel2 = fDecomp_->getGroupVelocityColumn(cg2);
760	>
761	>	for (ia = atomListRow.begin();
762	>	ia != atomListRow.end(); ++ia) {
763	>	atom1 = (*ia);
764	>
765	>	for (jb = atomListColumn.begin();
766	>	jb != atomListColumn.end(); ++jb) {
767	>	atom2 = (*jb);
768	>
769	>	if (!fDecomp_->skipAtomPair(atom1, atom2, cg1, cg2)) {
770	>
771	>	vpair = 0.0;
772	>	workPot = 0.0;
773	>	exPot = 0.0;
774	>	f1.zero();
775	>	dVdFQ1 = 0.0;
776	>	dVdFQ2 = 0.0;
777	>
778	>	fDecomp_->fillInteractionData(idat, atom1, atom2, newAtom1);
779	>
780	>	topoDist = fDecomp_->getTopologicalDistance(atom1, atom2);
781	>	vdwMult = vdwScale_[topoDist];
782	>	electroMult = electrostaticScale_[topoDist];
783	>
784	>	if (atomListRow.size() == 1 && atomListColumn.size() == 1) {
785	>	idat.d = &d_grp;
786	>	idat.r2 = &rgrpsq;
787	>	if (doHeatFlux_)
788	>	vel2 = gvel2;
789	>	} else {
790	>	d = fDecomp_->getInteratomicVector(atom1, atom2);
791	>	curSnapshot->wrapVector( d );
792	>	r2 = d.lengthSquare();
793	>	idat.d = &d;
794	>	idat.r2 = &r2;
795	>	if (doHeatFlux_)
796	>	vel2 = fDecomp_->getAtomVelocityColumn(atom2);
797	>	}
798	>
799	>	r = sqrt( *(idat.r2) );
800	>	idat.rij = &r;
801	>
802	>	if (iLoop == PREPAIR_LOOP) {
803	>	interactionMan_->doPrePair(idat);
804	>	} else {
805	>	interactionMan_->doPair(idat);
806	>	fDecomp_->unpackInteractionData(idat, atom1, atom2);
807	>	vij += vpair;
808	>	fij += f1;
809	>	stressTensor -= outProduct( *(idat.d), f1);
810	>	if (doHeatFlux_)
811	>	fDecomp_->addToHeatFlux((idat.d) dot(f1, vel2));
812	>	}
813		}
814		}
815		}
816	<	}
817	<
818	<	if (iLoop == PAIR_LOOP) {
819	<	if (in_switching_region) {
820	<	swderiv = vij * dswdr / rgrp;
821	<	fg = swderiv * d_grp;
822	<	fij += fg;
823	<
824	<	if (atomListRow.size() == 1 && atomListColumn.size() == 1) {
825	<	if (!fDecomp_->skipAtomPair(atomListRow[0],
826	<	atomListColumn[0],
865	<	cg1, cg2)) {
816	>
817	>	if (iLoop == PAIR_LOOP) {
818	>	if (in_switching_region) {
819	>	swderiv = vij * dswdr / rgrp;
820	>	fg = swderiv * d_grp;
821	>	fij += fg;
822	>
823	>	if (atomListRow.size() == 1 && atomListColumn.size() == 1) {
824	>	if (!fDecomp_->skipAtomPair(atomListRow[0],
825	>	atomListColumn[0],
826	>	cg1, cg2)) {
827		stressTensor -= outProduct( *(idat.d), fg);
828		if (doHeatFlux_)
829		fDecomp_->addToHeatFlux((idat.d) dot(fg, vel2));
830	<	}
831	<	}
832	<
833	<	for (ia = atomListRow.begin();
834	<	ia != atomListRow.end(); ++ia) {
835	<	atom1 = (*ia);
836	<	mf = fDecomp_->getMassFactorRow(atom1);
837	<	// fg is the force on atom ia due to cutoff group's
838	<	// presence in switching region
839	<	fg = swderiv * d_grp * mf;
840	<	fDecomp_->addForceToAtomRow(atom1, fg);
841	<	if (atomListRow.size() > 1) {
842	<	if (info_->usesAtomicVirial()) {
843	<	// find the distance between the atom
844	<	// and the center of the cutoff group:
845	<	dag = fDecomp_->getAtomToGroupVectorRow(atom1, cg1);
846	<	stressTensor -= outProduct(dag, fg);
847	<	if (doHeatFlux_)
848	<	fDecomp_->addToHeatFlux( dag * dot(fg, vel2));
830	>	}
831	>	}
832	>
833	>	for (ia = atomListRow.begin();
834	>	ia != atomListRow.end(); ++ia) {
835	>	atom1 = (*ia);
836	>	mf = fDecomp_->getMassFactorRow(atom1);
837	>	// fg is the force on atom ia due to cutoff group's
838	>	// presence in switching region
839	>	fg = swderiv * d_grp * mf;
840	>	fDecomp_->addForceToAtomRow(atom1, fg);
841	>	if (atomListRow.size() > 1) {
842	>	if (info_->usesAtomicVirial()) {
843	>	// find the distance between the atom
844	>	// and the center of the cutoff group:
845	>	dag = fDecomp_->getAtomToGroupVectorRow(atom1, cg1);
846	>	stressTensor -= outProduct(dag, fg);
847	>	if (doHeatFlux_)
848	>	fDecomp_->addToHeatFlux( dag * dot(fg, vel2));
849	>	}
850		}
851		}
852	<	}
853	<	for (jb = atomListColumn.begin();
854	<	jb != atomListColumn.end(); ++jb) {
855	<	atom2 = (*jb);
856	<	mf = fDecomp_->getMassFactorColumn(atom2);
857	<	// fg is the force on atom jb due to cutoff group's
858	<	// presence in switching region
859	<	fg = -swderiv * d_grp * mf;
860	<	fDecomp_->addForceToAtomColumn(atom2, fg);
861	<
862	<	if (atomListColumn.size() > 1) {
863	<	if (info_->usesAtomicVirial()) {
864	<	// find the distance between the atom
865	<	// and the center of the cutoff group:
866	<	dag = fDecomp_->getAtomToGroupVectorColumn(atom2, cg2);
867	<	stressTensor -= outProduct(dag, fg);
868	<	if (doHeatFlux_)
869	<	fDecomp_->addToHeatFlux( dag * dot(fg, vel2));
852	>	for (jb = atomListColumn.begin();
853	>	jb != atomListColumn.end(); ++jb) {
854	>	atom2 = (*jb);
855	>	mf = fDecomp_->getMassFactorColumn(atom2);
856	>	// fg is the force on atom jb due to cutoff group's
857	>	// presence in switching region
858	>	fg = -swderiv * d_grp * mf;
859	>	fDecomp_->addForceToAtomColumn(atom2, fg);
860	>
861	>	if (atomListColumn.size() > 1) {
862	>	if (info_->usesAtomicVirial()) {
863	>	// find the distance between the atom
864	>	// and the center of the cutoff group:
865	>	dag = fDecomp_->getAtomToGroupVectorColumn(atom2, cg2);
866	>	stressTensor -= outProduct(dag, fg);
867	>	if (doHeatFlux_)
868	>	fDecomp_->addToHeatFlux( dag * dot(fg, vel2));
869	>	}
870		}
871		}
872		}
873	+	//if (!info_->usesAtomicVirial()) {
874	+	// stressTensor -= outProduct(d_grp, fij);
875	+	// if (doHeatFlux_)
876	+	// fDecomp_->addToHeatFlux( d_grp * dot(fij, vel2));
877	+	//}
878		}
912	–	//if (!info_->usesAtomicVirial()) {
913	–	// stressTensor -= outProduct(d_grp, fij);
914	–	// if (doHeatFlux_)
915	–	// fDecomp_->addToHeatFlux( d_grp * dot(fij, vel2));
916	–	//}
879		}
880		}
881	+	newAtom1 = false;
882		}
883	<
883	>
884		if (iLoop == PREPAIR_LOOP) {
885		if (info_->requiresPrepair()) {
886	<
886	>
887		fDecomp_->collectIntermediateData();
888	<
888	>
889		for (unsigned int atom1 = 0; atom1 < info_->getNAtoms(); atom1++) {
890		fDecomp_->fillSelfData(sdat, atom1);
891		interactionMan_->doPreForce(sdat);
892		}
893	<
893	>
894		fDecomp_->distributeIntermediateData();
895	<
895	>
896		}
897		}
898		}
#	Line 958 \| Line 921 \| namespace OpenMD {
921		curSnapshot->setLongRangePotential(longRangePotential);
922
923		curSnapshot->setExcludedPotentials(*(fDecomp_->getExcludedSelfPotential()) +
924	<	*(fDecomp_->getExcludedPotential()));
924	>	*(fDecomp_->getExcludedPotential()));
925
926		}
927
#	Line 994 \| Line 957 \| namespace OpenMD {
957
958		if (info_->getSimParams()->getUseLongRangeCorrections()) {
959		/*
960	<	RealType vol = curSnapshot->getVolume();
961	<	RealType Elrc(0.0);
962	<	RealType Wlrc(0.0);
960	>	RealType vol = curSnapshot->getVolume();
961	>	RealType Elrc(0.0);
962	>	RealType Wlrc(0.0);
963
964	<	set<AtomType*>::iterator i;
965	<	set<AtomType*>::iterator j;
964	>	set<AtomType*>::iterator i;
965	>	set<AtomType*>::iterator j;
966
967	<	RealType n_i, n_j;
968	<	RealType rho_i, rho_j;
969	<	pair<RealType, RealType> LRI;
967	>	RealType n_i, n_j;
968	>	RealType rho_i, rho_j;
969	>	pair<RealType, RealType> LRI;
970
971	<	for (i = atomTypes_.begin(); i != atomTypes_.end(); ++i) {
971	>	for (i = atomTypes_.begin(); i != atomTypes_.end(); ++i) {
972		n_i = RealType(info_->getGlobalCountOfType(*i));
973		rho_i = n_i / vol;
974		for (j = atomTypes_.begin(); j != atomTypes_.end(); ++j) {
975	<	n_j = RealType(info_->getGlobalCountOfType(*j));
976	<	rho_j = n_j / vol;
975	>	n_j = RealType(info_->getGlobalCountOfType(*j));
976	>	rho_j = n_j / vol;
977
978	<	LRI = interactionMan_->getLongRangeIntegrals( (i), (j) );
978	>	LRI = interactionMan_->getLongRangeIntegrals( (i), (j) );
979
980	<	Elrc += n_i * rho_j * LRI.first;
981	<	Wlrc -= rho_i * rho_j * LRI.second;
980	>	Elrc += n_i * rho_j * LRI.first;
981	>	Wlrc -= rho_i * rho_j * LRI.second;
982		}
983	<	}
984	<	Elrc = 2.0 NumericConstant::PI;
985	<	Wlrc = 2.0 NumericConstant::PI;
983	>	}
984	>	Elrc = 2.0 NumericConstant::PI;
985	>	Wlrc = 2.0 NumericConstant::PI;
986
987	<	RealType lrp = curSnapshot->getLongRangePotential();
988	<	curSnapshot->setLongRangePotential(lrp + Elrc);
989	<	stressTensor += Wlrc * SquareMatrix3<RealType>::identity();
990	<	curSnapshot->setStressTensor(stressTensor);
987	>	RealType lrp = curSnapshot->getLongRangePotential();
988	>	curSnapshot->setLongRangePotential(lrp + Elrc);
989	>	stressTensor += Wlrc * SquareMatrix3<RealType>::identity();
990	>	curSnapshot->setStressTensor(stressTensor);
991		*/
992
993		}

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Comparing trunk/src/brains/ForceManager.cpp (file contents): Revision 1993 by gezelter, Tue Apr 29 17:32:31 2014 UTC vs. Revision 2057 by gezelter, Tue Mar 3 15:22:26 2015 UTC

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Comparing trunk/src/brains/ForceManager.cpp (file contents):
Revision 1993 by gezelter, Tue Apr 29 17:32:31 2014 UTC vs.
Revision 2057 by gezelter, Tue Mar 3 15:22:26 2015 UTC