[ViewVC] Diff of: OpenMD/branches/development/src/brains/SimInfo.hpp

Comparing branches/development/src/brains/SimInfo.hpp (file contents):
Revision 1503 by gezelter, Sat Oct 2 19:54:41 2010 UTC vs.
Revision 1569 by gezelter, Thu May 26 13:55:04 2011 UTC

#	Line 62 \| Line 62
62		#include "UseTheForce/ForceField.hpp"
63		#include "utils/PropertyMap.hpp"
64		#include "utils/LocalIndexManager.hpp"
65	<	#include "nonbonded/Electrostatic.hpp"
65	>	#include "nonbonded/SwitchingFunction.hpp"
66
67	<	//another nonsense macro declaration
68	<	#define __OPENMD_C
69	<	#include "brains/fSimulation.h"
70	<
67	>	using namespace std;
68		namespace OpenMD{
69	<
73	<	//forward decalration
69	>	//forward declaration
70		class SnapshotManager;
71		class Molecule;
72		class SelectionManager;
73		class StuntDouble;
74	<	class Electrostatic;
74	>
75		/**
76	<	* @class SimInfo SimInfo.hpp "brains/SimInfo.hpp"
77	<	* @brief One of the heavy weight classes of OpenMD, SimInfo maintains a list of molecules.
78	<	* The Molecule class maintains all of the concrete objects
79	<	* (atoms, bond, bend, torsions, inversions, rigid bodies, cutoff groups,
80	<	* constraints). In both the single and parallel versions, atoms and
81	<	* rigid bodies have both global and local indices. The local index is
82	<	* not relevant to molecules or cutoff groups.
83	<	*/
76	>	* @class SimInfo SimInfo.hpp "brains/SimInfo.hpp"
77	>	*
78	>	* @brief One of the heavy-weight classes of OpenMD, SimInfo
79	>	* maintains objects and variables relating to the current
80	>	* simulation. This includes the master list of Molecules. The
81	>	* Molecule class maintains all of the concrete objects (Atoms,
82	>	* Bond, Bend, Torsions, Inversions, RigidBodies, CutoffGroups,
83	>	* Constraints). In both the single and parallel versions, Atoms and
84	>	* RigidBodies have both global and local indices.
85	>	*/
86		class SimInfo {
87		public:
88	<	typedef std::map<int, Molecule*>::iterator MoleculeIterator;
89	<
88	>	typedef map<int, Molecule*>::iterator MoleculeIterator;
89	>
90		/**
91		* Constructor of SimInfo
92	<	* @param molStampPairs MoleculeStamp Array. The first element of the pair is molecule stamp, the
93	<	* second element is the total number of molecules with the same molecule stamp in the system
92	>	*
93	>	* @param molStampPairs MoleculeStamp Array. The first element of
94	>	* the pair is molecule stamp, the second element is the total
95	>	* number of molecules with the same molecule stamp in the system
96	>	*
97		* @param ff pointer of a concrete ForceField instance
98	+	*
99		* @param simParams
98	–	* @note
100		*/
101		SimInfo(ForceField* ff, Globals* simParams);
102		virtual ~SimInfo();
103
104		/**
105		* Adds a molecule
106	<	* @return return true if adding successfully, return false if the molecule is already in SimInfo
106	>	*
107	>	* @return return true if adding successfully, return false if the
108	>	* molecule is already in SimInfo
109	>	*
110		* @param mol molecule to be added
111		*/
112		bool addMolecule(Molecule* mol);
113
114		/**
115		* Removes a molecule from SimInfo
116	<	* @return true if removing successfully, return false if molecule is not in this SimInfo
116	>	*
117	>	* @return true if removing successfully, return false if molecule
118	>	* is not in this SimInfo
119		*/
120		bool removeMolecule(Molecule* mol);
121
#	Line 129 \| Line 135 \| namespace OpenMD{
135		}
136
137		/**
138	<	* Returns the total number of integrable objects (total number of rigid bodies plus the total number
139	<	* of atoms which do not belong to the rigid bodies) in the system
138	>	* Returns the total number of integrable objects (total number of
139	>	* rigid bodies plus the total number of atoms which do not belong
140	>	* to the rigid bodies) in the system
141		*/
142		int getNGlobalIntegrableObjects() {
143		return nGlobalIntegrableObjects_;
144		}
145
146		/**
147	<	* Returns the total number of integrable objects (total number of rigid bodies plus the total number
148	<	* of atoms which do not belong to the rigid bodies) in the system
147	>	* Returns the total number of integrable objects (total number of
148	>	* rigid bodies plus the total number of atoms which do not belong
149	>	* to the rigid bodies) in the system
150		*/
151		int getNGlobalRigidBodies() {
152		return nGlobalRigidBodies_;
#	Line 233 \| Line 241 \| namespace OpenMD{
241
242		int getFdf();
243
244	<	//getNZconstraint and setNZconstraint ruin the coherent of SimInfo class, need refactorying
244	>	//getNZconstraint and setNZconstraint ruin the coherence of
245	>	//SimInfo class, need refactoring
246
247		/** Returns the total number of z-constraint molecules in the system */
248		int getNZconstraint() {
#	Line 269 \| Line 278 \| namespace OpenMD{
278
279		/** Returns the center of the mass of the whole system.*/
280		Vector3d getCom();
281	<	/** Returns the center of the mass and Center of Mass velocity of the whole system.*/
281	>	/** Returns the center of the mass and Center of Mass velocity of
282	>	the whole system.*/
283		void getComAll(Vector3d& com,Vector3d& comVel);
284
285	<	/** Returns intertia tensor for the entire system and system Angular Momentum.*/
285	>	/** Returns intertia tensor for the entire system and system
286	>	Angular Momentum.*/
287		void getInertiaTensor(Mat3x3d &intertiaTensor,Vector3d &angularMomentum);
288
289		/** Returns system angular momentum */
290		Vector3d getAngularMomentum();
291
292	<	/** Returns volume of system as estimated by an ellipsoid defined by the radii of gyration*/
292	>	/** Returns volume of system as estimated by an ellipsoid defined
293	>	by the radii of gyration*/
294		void getGyrationalVolume(RealType &vol);
295	<	/** Overloaded version of gyrational volume that also returns det(I) so dV/dr can be calculated*/
295	>	/** Overloaded version of gyrational volume that also returns
296	>	det(I) so dV/dr can be calculated*/
297		void getGyrationalVolume(RealType &vol, RealType &detI);
298	<	/** main driver function to interact with fortran during the initialization and molecule migration */
298	>
299		void update();
300	+	/**
301	+	* Do final bookkeeping before Force managers need their data.
302	+	*/
303	+	void prepareTopology();
304
305	+
306		/** Returns the local index manager */
307		LocalIndexManager* getLocalIndexManager() {
308		return &localIndexMan_;
#	Line 320 \| Line 338 \| namespace OpenMD{
338		return globalMolMembership_[id];
339		}
340
341	<	RealType getRcut() {
342	<	return rcut_;
343	<	}
341	>	/**
342	>	* returns a vector which maps the local atom index on this
343	>	* processor to the global atom index. With only one processor,
344	>	* these should be identical.
345	>	*/
346	>	vector<int> getGlobalAtomIndices();
347
348	<	RealType getRsw() {
349	<	return rsw_;
350	<	}
351	<
352	<	RealType getList() {
353	<	return rlist_;
354	<	}
348	>	/**
349	>	* returns a vector which maps the local cutoff group index on
350	>	* this processor to the global cutoff group index. With only one
351	>	* processor, these should be identical.
352	>	*/
353	>	vector<int> getGlobalGroupIndices();
354	>
355
356	<	std::string getFinalConfigFileName() {
356	>	string getFinalConfigFileName() {
357		return finalConfigFileName_;
358		}
359
360	<	void setFinalConfigFileName(const std::string& fileName) {
360	>	void setFinalConfigFileName(const string& fileName) {
361		finalConfigFileName_ = fileName;
362		}
363
364	<	std::string getRawMetaData() {
364	>	string getRawMetaData() {
365		return rawMetaData_;
366		}
367	<	void setRawMetaData(const std::string& rawMetaData) {
367	>	void setRawMetaData(const string& rawMetaData) {
368		rawMetaData_ = rawMetaData;
369		}
370
371	<	std::string getDumpFileName() {
371	>	string getDumpFileName() {
372		return dumpFileName_;
373		}
374
375	<	void setDumpFileName(const std::string& fileName) {
375	>	void setDumpFileName(const string& fileName) {
376		dumpFileName_ = fileName;
377		}
378
379	<	std::string getStatFileName() {
379	>	string getStatFileName() {
380		return statFileName_;
381		}
382
383	<	void setStatFileName(const std::string& fileName) {
383	>	void setStatFileName(const string& fileName) {
384		statFileName_ = fileName;
385		}
386
387	<	std::string getRestFileName() {
387	>	string getRestFileName() {
388		return restFileName_;
389		}
390
391	<	void setRestFileName(const std::string& fileName) {
391	>	void setRestFileName(const string& fileName) {
392		restFileName_ = fileName;
393		}
394
#	Line 375 \| Line 396 \| namespace OpenMD{
396		* Sets GlobalGroupMembership
397		* @see #SimCreator::setGlobalIndex
398		*/
399	<	void setGlobalGroupMembership(const std::vector<int>& globalGroupMembership) {
399	>	void setGlobalGroupMembership(const vector<int>& globalGroupMembership) {
400		assert(globalGroupMembership.size() == static_cast<size_t>(nGlobalAtoms_));
401		globalGroupMembership_ = globalGroupMembership;
402		}
#	Line 384 \| Line 405 \| namespace OpenMD{
405		* Sets GlobalMolMembership
406		* @see #SimCreator::setGlobalIndex
407		*/
408	<	void setGlobalMolMembership(const std::vector<int>& globalMolMembership) {
408	>	void setGlobalMolMembership(const vector<int>& globalMolMembership) {
409		assert(globalMolMembership.size() == static_cast<size_t>(nGlobalAtoms_));
410		globalMolMembership_ = globalMolMembership;
411		}
412
413
414	<	bool isFortranInitialized() {
415	<	return fortranInitialized_;
414	>	bool isTopologyDone() {
415	>	return topologyDone_;
416		}
417
418		bool getCalcBoxDipole() {
#	Line 402 \| Line 423 \| namespace OpenMD{
423		return useAtomicVirial_;
424		}
425
405	–	//below functions are just forward functions
406	–	//To compose or to inherit is always a hot debate. In general, is-a relation need subclassing, in the
407	–	//the other hand, has-a relation need composing.
426		/**
427		* Adds property into property map
428		* @param genData GenericData to be added into PropertyMap
#	Line 415 \| Line 433 \| namespace OpenMD{
433		* Removes property from PropertyMap by name
434		* @param propName the name of property to be removed
435		*/
436	<	void removeProperty(const std::string& propName);
436	>	void removeProperty(const string& propName);
437
438		/**
439		* clear all of the properties
#	Line 426 \| Line 444 \| namespace OpenMD{
444		* Returns all names of properties
445		* @return all names of properties
446		*/
447	<	std::vector<std::string> getPropertyNames();
447	>	vector<string> getPropertyNames();
448
449		/**
450		* Returns all of the properties in PropertyMap
451		* @return all of the properties in PropertyMap
452		*/
453	<	std::vector<GenericData*> getProperties();
453	>	vector<GenericData*> getProperties();
454
455		/**
456		* Returns property
#	Line 440 \| Line 458 \| namespace OpenMD{
458		* @return a pointer point to property with propName. If no property named propName
459		* exists, return NULL
460		*/
461	<	GenericData* getPropertyByName(const std::string& propName);
461	>	GenericData* getPropertyByName(const string& propName);
462
463		/**
464		* add all special interaction pairs (including excluded
#	Line 454 \| Line 472 \| namespace OpenMD{
472		*/
473		void removeInteractionPairs(Molecule* mol);
474
475	<
476	<	/** Returns the unique atom types of local processor in an array */
459	<	std::set<AtomType*> getUniqueAtomTypes();
475	>	/** Returns the set of atom types present in this simulation */
476	>	set<AtomType*> getSimulatedAtomTypes();
477
478	<	friend std::ostream& operator <<(std::ostream& o, SimInfo& info);
478	>	friend ostream& operator <<(ostream& o, SimInfo& info);
479
480		void getCutoff(RealType& rcut, RealType& rsw);
481
482		private:
483
484	<	/** fill up the simtype struct*/
485	<	void setupSimType();
484	>	/** fill up the simtype struct and other simulation-related variables */
485	>	void setupSimVariables();
486
470	–	/**
471	–	* Setup Fortran Simulation
472	–	* @see #setupFortranParallel
473	–	*/
474	–	void setupFortranSim();
487
476	–	/** Figure out the radius of cutoff, radius of switching function and pass them to fortran */
477	–	void setupCutoff();
478	–
479	–	/** Figure out which coulombic correction method to use and pass to fortran */
480	–	void setupElectrostaticSummationMethod( int isError );
481	–
482	–	/** Figure out which polynomial type to use for the switching function */
483	–	void setupSwitchingFunction();
484	–
488		/** Determine if we need to accumulate the simulation box dipole */
489		void setupAccumulateBoxDipole();
490
#	Line 490 \| Line 493 \| namespace OpenMD{
493		void calcNdfRaw();
494		void calcNdfTrans();
495
493	–	ForceField* forceField_;
494	–	Globals* simParams_;
495	–
496	–	std::map<int, Molecule> molecules_; /< Molecule array /
497	–
496		/**
497	<	* Adds molecule stamp and the total number of the molecule with same molecule stamp in the whole
498	<	* system.
497	>	* Adds molecule stamp and the total number of the molecule with
498	>	* same molecule stamp in the whole system.
499		*/
500		void addMoleculeStamp(MoleculeStamp* molStamp, int nmol);
503	–
504	–	//degress of freedom
505	–	int ndf_; /*< number of degress of freedom (excludes constraints), ndf_ is local /
506	–	int fdf_local; /*< number of frozen degrees of freedom /
507	–	int fdf_; /*< number of frozen degrees of freedom /
508	–	int ndfRaw_; /*< number of degress of freedom (includes constraints), ndfRaw_ is local /
509	–	int ndfTrans_; /*< number of translation degress of freedom, ndfTrans_ is local /
510	–	int nZconstraint_; /** number of z-constraint molecules, nZconstraint_ is global */
511	–
512	–	//number of global objects
513	–	int nGlobalMols_; /*< number of molecules in the system /
514	–	int nGlobalAtoms_; /*< number of atoms in the system /
515	–	int nGlobalCutoffGroups_; /*< number of cutoff groups in this system /
516	–	int nGlobalIntegrableObjects_; /*< number of integrable objects in this system /
517	–	int nGlobalRigidBodies_; /*< number of rigid bodies in this system /
518	–	/**
519	–	* the size of globalGroupMembership_ is nGlobalAtoms. Its index is global index of an atom, and the
520	–	* corresponding content is the global index of cutoff group this atom belong to.
521	–	* It is filled by SimCreator once and only once, since it never changed during the simulation.
522	–	*/
523	–	std::vector<int> globalGroupMembership_;
501
502	<	/**
503	<	* the size of globalMolMembership_ is nGlobalAtoms. Its index is global index of an atom, and the
504	<	* corresponding content is the global index of molecule this atom belong to.
528	<	* It is filled by SimCreator once and only once, since it is never changed during the simulation.
529	<	*/
530	<	std::vector<int> globalMolMembership_;
502	>	// Other classes holdingn important information
503	>	ForceField* forceField_; /*< provides access to defined atom types, bond types, etc. /
504	>	Globals* simParams_; /*< provides access to simulation parameters set by user /
505
506	<
533	<	std::vector<int> molStampIds_; /*< stamp id array of all molecules in the system /
534	<	std::vector<MoleculeStamp> moleculeStamps_; /< molecule stamps array /
535	<
536	<	//number of local objects
506	>	/// Counts of local objects
507		int nAtoms_; /*< number of atoms in local processor /
508		int nBonds_; /*< number of bonds in local processor /
509		int nBends_; /*< number of bends in local processor /
#	Line 543 \| Line 513 \| namespace OpenMD{
513		int nIntegrableObjects_; /*< number of integrable objects in local processor /
514		int nCutoffGroups_; /*< number of cutoff groups in local processor /
515		int nConstraints_; /*< number of constraints in local processors /
516	+
517	+	/// Counts of global objects
518	+	int nGlobalMols_; /*< number of molecules in the system (GLOBAL) /
519	+	int nGlobalAtoms_; /*< number of atoms in the system (GLOBAL) /
520	+	int nGlobalCutoffGroups_; /*< number of cutoff groups in this system (GLOBAL) /
521	+	int nGlobalIntegrableObjects_; /*< number of integrable objects in this system /
522	+	int nGlobalRigidBodies_; /*< number of rigid bodies in this system (GLOBAL) /
523	+
524	+	/// Degress of freedom
525	+	int ndf_; /*< number of degress of freedom (excludes constraints) (LOCAL) /
526	+	int fdf_local; /*< number of frozen degrees of freedom (LOCAL) /
527	+	int fdf_; /*< number of frozen degrees of freedom (GLOBAL) /
528	+	int ndfRaw_; /*< number of degress of freedom (includes constraints), (LOCAL) /
529	+	int ndfTrans_; /*< number of translation degress of freedom, (LOCAL) /
530	+	int nZconstraint_; /*< number of z-constraint molecules (GLOBAL) /
531
532	<	simtype fInfo_; /*< A dual struct shared by c++/fortran which indicates the atom types in simulation/
533	<	PairList excludedInteractions_;
534	<	PairList oneTwoInteractions_;
535	<	PairList oneThreeInteractions_;
536	<	PairList oneFourInteractions_;
537	<	PropertyMap properties_; /*< Generic Property /
538	<	SnapshotManager* sman_; /*< SnapshotManager /
532	>	/// logicals
533	>	bool usesPeriodicBoundaries_; /*< use periodic boundary conditions? /
534	>	bool usesDirectionalAtoms_; /*< are there atoms with position AND orientation? /
535	>	bool usesMetallicAtoms_; /*< are there transition metal atoms? /
536	>	bool usesElectrostaticAtoms_; /*< are there electrostatic atoms? /
537	>	bool usesAtomicVirial_; /*< are we computing atomic virials? /
538	>	bool requiresPrepair_; /*< does this simulation require a pre-pair loop? /
539	>	bool requiresSkipCorrection_; /*< does this simulation require a skip-correction? /
540	>	bool requiresSelfCorrection_; /*< does this simulation require a self-correction? /
541
542	+	public:
543	+	bool usesElectrostaticAtoms() { return usesElectrostaticAtoms_; }
544	+	bool usesDirectionalAtoms() { return usesDirectionalAtoms_; }
545	+	bool usesMetallicAtoms() { return usesMetallicAtoms_; }
546	+	bool usesAtomicVirial() { return usesAtomicVirial_; }
547	+	bool requiresPrepair() { return requiresPrepair_; }
548	+	bool requiresSkipCorrection() { return requiresSkipCorrection_;}
549	+	bool requiresSelfCorrection() { return requiresSelfCorrection_;}
550	+
551	+	private:
552	+	/// Data structures holding primary simulation objects
553	+	map<int, Molecule> molecules_; /< map holding pointers to LOCAL molecules /
554	+
555	+	/// Stamps are templates for objects that are then used to create
556	+	/// groups of objects. For example, a molecule stamp contains
557	+	/// information on how to build that molecule (i.e. the topology,
558	+	/// the atoms, the bonds, etc.) Once the system is built, the
559	+	/// stamps are no longer useful.
560	+	vector<int> molStampIds_; /*< stamp id for molecules in the system /
561	+	vector<MoleculeStamp> moleculeStamps_; /< molecule stamps array /
562	+
563	+	/**
564	+	* A vector that maps between the global index of an atom, and the
565	+	* global index of cutoff group the atom belong to. It is filled
566	+	* by SimCreator once and only once, since it never changed during
567	+	* the simulation. It should be nGlobalAtoms_ in size.
568	+	*/
569	+	vector<int> globalGroupMembership_;
570	+	public:
571	+	vector<int> getGlobalGroupMembership() { return globalGroupMembership_; }
572	+	private:
573	+
574	+	/**
575	+	* A vector that maps between the global index of an atom and the
576	+	* global index of the molecule the atom belongs to. It is filled
577	+	* by SimCreator once and only once, since it is never changed
578	+	* during the simulation. It shoudl be nGlobalAtoms_ in size.
579	+	*/
580	+	vector<int> globalMolMembership_;
581	+
582		/**
583	<	* The reason to have a local index manager is that when molecule is migrating to other processors,
584	<	* the atoms and the rigid-bodies will release their local indices to LocalIndexManager. Combining the
585	<	* information of molecule migrating to current processor, Migrator class can query the LocalIndexManager
586	<	* to make a efficient data moving plan.
583	>	* A vector that maps between the local index of an atom and the
584	>	* index of the AtomType.
585	>	*/
586	>	vector<int> identArray_;
587	>	public:
588	>	vector<int> getIdentArray() { return identArray_; }
589	>	private:
590	>
591	>	/**
592	>	* A vector which contains the fractional contribution of an
593	>	* atom's mass to the total mass of the cutoffGroup that atom
594	>	* belongs to. In the case of single atom cutoff groups, the mass
595	>	* factor for that atom is 1. For massless atoms, the factor is
596	>	* also 1.
597	>	*/
598	>	vector<RealType> massFactors_;
599	>	public:
600	>	vector<RealType> getMassFactors() { return massFactors_; }
601	>	private:
602	>
603	>
604	>	/// lists to handle atoms needing special treatment in the non-bonded interactions
605	>	PairList excludedInteractions_; /*< atoms excluded from interacting with each other /
606	>	PairList oneTwoInteractions_; /*< atoms that are directly Bonded /
607	>	PairList oneThreeInteractions_; /*< atoms sharing a Bend /
608	>	PairList oneFourInteractions_; /*< atoms sharing a Torsion /
609	>
610	>	PropertyMap properties_; /*< Generic Properties can be added /
611	>	SnapshotManager* sman_; /*< SnapshotManager (handles particle positions, etc.) /
612	>
613	>	/**
614	>	* The reason to have a local index manager is that when molecule
615	>	* is migrating to other processors, the atoms and the
616	>	* rigid-bodies will release their local indices to
617	>	* LocalIndexManager. Combining the information of molecule
618	>	* migrating to current processor, Migrator class can query the
619	>	* LocalIndexManager to make a efficient data moving plan.
620		*/
621		LocalIndexManager localIndexMan_;
622
623		// unparsed MetaData block for storing in Dump and EOR files:
624	<	std::string rawMetaData_;
624	>	string rawMetaData_;
625
626	<	//file names
627	<	std::string finalConfigFileName_;
628	<	std::string dumpFileName_;
629	<	std::string statFileName_;
630	<	std::string restFileName_;
626	>	// file names
627	>	string finalConfigFileName_;
628	>	string dumpFileName_;
629	>	string statFileName_;
630	>	string restFileName_;
631
572	–	RealType rcut_; /*< cutoff radius/
573	–	RealType rsw_; /*< radius of switching function/
574	–	RealType rlist_; /*< neighbor list radius /
632
633	<	int ljsp_; /*< use shifted potential for LJ/
634	<	int ljsf_; /*< use shifted force for LJ/
635	<
579	<	bool fortranInitialized_; /** flag to indicate whether the fortran side is initialized */
633	>	bool topologyDone_; /** flag to indicate whether the topology has
634	>	been scanned and all the relevant
635	>	bookkeeping has been done*/
636
637		bool calcBoxDipole_; /**< flag to indicate whether or not we calculate
638		the simulation box dipole moment */
639
640		bool useAtomicVirial_; /**< flag to indicate whether or not we use
641		Atomic Virials to calculate the pressure */
642	<
643	<	public:
588	<	/**
589	<	* return an integral objects by its global index. In MPI version, if the StuntDouble with specified
590	<	* global index does not belong to local processor, a NULL will be return.
591	<	*/
592	<	StuntDouble* getIOIndexToIntegrableObject(int index);
593	<	void setIOIndexToIntegrableObject(const std::vector<StuntDouble*>& v);
594	<	private:
595	<	std::vector<StuntDouble*> IOIndexToIntegrableObject;
596	<	//public:
597	<	//void setStuntDoubleFromGlobalIndex(std::vector<StuntDouble*> v);
642	>
643	>	public:
644		/**
645	<	* return a StuntDouble by its global index. In MPI version, if the StuntDouble with specified
646	<	* global index does not belong to local processor, a NULL will be return.
647	<	*/
648	<	//StuntDouble* getStuntDoubleFromGlobalIndex(int index);
649	<	//private:
650	<	//std::vector<StuntDouble*> sdByGlobalIndex_;
645	>	* return an integral objects by its global index. In MPI
646	>	* version, if the StuntDouble with specified global index does
647	>	* not belong to local processor, a NULL will be return.
648	>	*/
649	>	StuntDouble* getIOIndexToIntegrableObject(int index);
650	>	void setIOIndexToIntegrableObject(const vector<StuntDouble*>& v);
651
652	<	//in Parallel version, we need MolToProc
652	>	private:
653	>	vector<StuntDouble*> IOIndexToIntegrableObject;
654	>
655		public:
656
657		/**
#	Line 615 \| Line 663 \| namespace OpenMD{
663		//assert(globalIndex < molToProcMap_.size());
664		return molToProcMap_[globalIndex];
665		}
666	<
666	>
667		/**
668		* Set MolToProcMap array
669		* @see #SimCreator::divideMolecules
670		*/
671	<	void setMolToProcMap(const std::vector<int>& molToProcMap) {
671	>	void setMolToProcMap(const vector<int>& molToProcMap) {
672		molToProcMap_ = molToProcMap;
673		}
674
675		private:
628	–
629	–	void setupFortranParallel();
676
677		/**
678		* The size of molToProcMap_ is equal to total number of molecules
679		* in the system. It maps a molecule to the processor on which it
680		* resides. it is filled by SimCreator once and only once.
681		*/
682	<	std::vector<int> molToProcMap_;
682	>	vector<int> molToProcMap_;
683
638	–
684		};
685
686		} //namespace OpenMD

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Comparing branches/development/src/brains/SimInfo.hpp (file contents): Revision 1503 by gezelter, Sat Oct 2 19:54:41 2010 UTC vs. Revision 1569 by gezelter, Thu May 26 13:55:04 2011 UTC

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Comparing branches/development/src/brains/SimInfo.hpp (file contents):
Revision 1503 by gezelter, Sat Oct 2 19:54:41 2010 UTC vs.
Revision 1569 by gezelter, Thu May 26 13:55:04 2011 UTC