[ViewVC] Diff of: group/trunk/OOPSE-2.0/src/brains/SimInfo.hpp

Comparing trunk/OOPSE-2.0/src/brains/SimInfo.hpp (file contents):
Revision 1492 by tim, Fri Sep 24 16:27:58 2004 UTC vs.
Revision 2101 by chrisfen, Thu Mar 10 15:10:24 2005 UTC

-<
+#ifndef __SIMINFO_H__
-<
+#define __SIMINFO_H__
->
+ /*
->
+ * Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
->
+ *
->
+ * The University of Notre Dame grants you ("Licensee") a
->
+ * non-exclusive, royalty free, license to use, modify and
->
+ * redistribute this software in source and binary code form, provided
->
+ * that the following conditions are met:
->
+ *
->
+ * 1. Acknowledgement of the program authors must be made in any
->
+ *    publication of scientific results based in part on use of the
->
+ *    program.  An acceptable form of acknowledgement is citation of
->
+ *    the article in which the program was described (Matthew
->
+ *    A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
->
+ *    J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
->
+ *    Parallel Simulation Engine for Molecular Dynamics,"
->
+ *    J. Comput. Chem. 26, pp. 252-271 (2005))
->
+ *
->
+ * 2. Redistributions of source code must retain the above copyright
->
+ *    notice, this list of conditions and the following disclaimer.
->
+ *
->
+ * 3. Redistributions in binary form must reproduce the above copyright
->
+ *    notice, this list of conditions and the following disclaimer in the
->
+ *    documentation and/or other materials provided with the
->
+ *    distribution.
->
+ *
->
+ * This software is provided "AS IS," without a warranty of any
->
+ * kind. All express or implied conditions, representations and
->
+ * warranties, including any implied warranty of merchantability,
->
+ * fitness for a particular purpose or non-infringement, are hereby
->
+ * excluded.  The University of Notre Dame and its licensors shall not
->
+ * be liable for any damages suffered by licensee as a result of
->
+ * using, modifying or distributing the software or its
->
+ * derivatives. In no event will the University of Notre Dame or its
->
+ * licensors be liable for any lost revenue, profit or data, or for
->
+ * direct, indirect, special, consequential, incidental or punitive
->
+ * damages, however caused and regardless of the theory of liability,
->
+ * arising out of the use of or inability to use software, even if the
->
+ * University of Notre Dame has been advised of the possibility of
->
+ * such damages.
->
+ */
->
->
+/**
->
+ * @file SimInfo.hpp
->
+ * @author    tlin
->
+ * @date  11/02/2004
->
+ * @version 1.0
->
+ */
-<
+#include <map>
-<
+#include <string>
->
+#ifndef BRAINS_SIMMODEL_HPP
->
+#define BRAINS_SIMMODEL_HPP
->
->
+#include <iostream>
->
+#include <set>
->
+#include <utility>
+#include <vector>
-–
+#include "primitives/Atom.hpp"
-–
+#include "primitives/RigidBody.hpp"
-–
+#include "primitives/Molecule.hpp"
+#include "brains/Exclude.hpp"
-<
+#include "brains/SkipList.hpp"
-<
+#include "primitives/AbstractClasses.hpp"
-<
+#include "types/MakeStamps.hpp"
-<
+#include "brains/SimState.hpp"
-<
+#include "restraints/Restraints.hpp"
->
+#include "io/Globals.hpp"
->
+#include "math/Vector3.hpp"
->
+#include "types/MoleculeStamp.hpp"
->
+#include "UseTheForce/ForceField.hpp"
->
+#include "utils/PropertyMap.hpp"
->
+#include "utils/LocalIndexManager.hpp"
-+
+//another nonsense macro declaration
+#define __C
+#include "brains/fSimulation.h"
-–
+#include "UseTheForce/fortranWrapDefines.hpp"
-–
+#include "utils/GenericData.hpp"
-+
+namespace oopse{
-<
+//#include "Minimizer.hpp"
-<
+//#include "minimizers/OOPSEMinimizer.hpp"
->
+//forward decalration
->
+class SnapshotManager;
->
+class Molecule;
->
+class SelectionManager;
->
+/**
->
+ * @class SimInfo SimInfo.hpp "brains/SimInfo.hpp"
->
+ * @brief As one of the heavy weight class of OOPSE, SimInfo
->
+ * One of the major changes in SimInfo class is the data struct. It only maintains a list of molecules.
->
+ * And the Molecule class will maintain all of the concrete objects (atoms, bond, bend, torsions, rigid bodies,
->
+ * cutoff groups, constrains).
->
+ * Another major change is the index. No matter single version or parallel version,  atoms and
->
+ * rigid bodies have both global index and local index. Local index is not important to molecule as well as
->
+ * cutoff group.
->
+ */
->
+class SimInfo {
->
+    public:
->
+        typedef std::map<int, Molecule*>::iterator  MoleculeIterator;
-+
+        /**
-+
+         * Constructor of SimInfo
-+
+         * @param molStampPairs MoleculeStamp Array. The first element of the pair is molecule stamp, the
-+
+         * second element is the total number of molecules with the same molecule stamp in the system
-+
+         * @param ff pointer of a concrete ForceField instance
-+
+         * @param simParams
-+
+         * @note
-+
+         */
-+
+        SimInfo(std::vector<std::pair<MoleculeStamp*, int> >& molStampPairs, ForceField* ff, Globals* simParams);
-+
+        virtual ~SimInfo();
-<
+double roundMe( double x );
-<
+class OOPSEMinimizer;
-<
+class SimInfo{
->
+        /**
->
+         * Adds a molecule
->
+         * @return return true if adding successfully, return false if the molecule is already in SimInfo
->
+         * @param mol molecule to be added
->
+         */
->
+        bool addMolecule(Molecule* mol);
-<
+public:
->
+        /**
->
+         * Removes a molecule from SimInfo
->
+         * @return true if removing successfully, return false if molecule is not in this SimInfo
->
+         */
->
+        bool removeMolecule(Molecule* mol);
-<
+  SimInfo();
-<
+  ~SimInfo();
->
+        /** Returns the total number of molecules in the system. */
->
+        int getNGlobalMolecules() {
->
+            return nGlobalMols_;
->
+        }
-<
+  int n_atoms; // the number of atoms
-<
+  Atom **atoms; // the array of atom objects
->
+        /** Returns the total number of atoms in the system. */
->
+        int getNGlobalAtoms() {
->
+            return nGlobalAtoms_;
->
+        }
-<
+  vector<RigidBody*> rigidBodies;  // A vector of rigid bodies
-<
+  vector<StuntDouble*> integrableObjects;
-<
-<
+  double tau[9]; // the stress tensor
->
+        /** Returns the total number of cutoff groups in the system. */
->
+        int getNGlobalCutoffGroups() {
->
+            return nGlobalCutoffGroups_;
->
+        }
-<
+  int n_bonds;    // number of bends
-<
+  int n_bends;    // number of bends
-<
+  int n_torsions; // number of torsions
-<
+  int n_oriented; // number of of atoms with orientation
-<
+  int ndf;        // number of actual degrees of freedom
-<
+  int ndfRaw;     // number of settable degrees of freedom
-<
+  int ndfTrans;   // number of translational degrees of freedom
-<
+  int nZconstraints; // the number of zConstraints
->
+        /**
->
+         * Returns the total number of integrable objects (total number of rigid bodies plus the total number
->
+         * of atoms which do not belong to the rigid bodies) in the system
->
+         */
->
+        int getNGlobalIntegrableObjects() {
->
+            return nGlobalIntegrableObjects_;
->
+        }
-<
+  int setTemp;   // boolean to set the temperature at each sampleTime
-<
+  int resetIntegrator; // boolean to reset the integrator
->
+        /**
->
+         * Returns the total number of integrable objects (total number of rigid bodies plus the total number
->
+         * of atoms which do not belong to the rigid bodies) in the system
->
+         */
->
+        int getNGlobalRigidBodies() {
->
+            return nGlobalRigidBodies_;
->
+        }
-<
+  int n_dipoles; // number of dipoles
->
+        int getNGlobalConstraints();
->
+        /**
->
+         * Returns the number of local molecules.
->
+         * @return the number of local molecules
->
+         */
->
+        int getNMolecules() {
->
+            return molecules_.size();
->
+        }
-<
+  int n_exclude;
-<
+  Exclude* excludes;  // the exclude list for ignoring pairs in fortran
-<
+  int nGlobalExcludes;
-<
+  int* globalExcludes; // same as above, but these guys participate in
-<
+                       // no long range forces.
->
+        /** Returns the number of local atoms */
->
+        unsigned int getNAtoms() {
->
+            return nAtoms_;
->
+        }
-<
+  int* identArray;     // array of unique identifiers for the atoms
-<
+  int* molMembershipArray;  // map of atom numbers onto molecule numbers
->
+        /** Returns the number of local bonds */
->
+        unsigned int getNBonds(){
->
+            return nBonds_;
->
+        }
-<
+  int n_constraints; // the number of constraints on the system
->
+        /** Returns the number of local bends */
->
+        unsigned int getNBends() {
->
+            return nBends_;
->
+        }
-<
+  int n_SRI;   // the number of short range interactions
->
+        /** Returns the number of local torsions */
->
+        unsigned int getNTorsions() {
->
+            return nTorsions_;
->
+        }
-<
+  double lrPot; // the potential energy from the long range calculations.
->
+        /** Returns the number of local rigid bodies */
->
+        unsigned int getNRigidBodies() {
->
+            return nRigidBodies_;
->
+        }
-<
+  double Hmat[3][3];  // the periodic boundry conditions. The Hmat is the
-<
+                      // column vectors of the x, y, and z box vectors.
-<
+                      //   h1  h2  h3
-<
+                      // [ Xx  Yx  Zx ]
-<
+                      // [ Xy  Yy  Zy ]
-<
+                      // [ Xz  Yz  Zz ]
-<
+                      //
-<
+  double HmatInv[3][3];
->
+        /** Returns the number of local integrable objects */
->
+        unsigned int getNIntegrableObjects() {
->
+            return nIntegrableObjects_;
->
+        }
-<
+  double boxL[3]; // The Lengths of the 3 column vectors of Hmat
-<
+  double boxVol;
-<
+  int orthoRhombic;
-<
->
+        /** Returns the number of local cutoff groups */
->
+        unsigned int getNCutoffGroups() {
->
+            return nCutoffGroups_;
->
+        }
-<
+  double dielectric;      // the dielectric of the medium for reaction field
->
+        /** Returns the total number of constraints in this SimInfo */
->
+        unsigned int getNConstraints() {
->
+            return nConstraints_;
->
+        }
->
->
+        /**
->
+         * Returns the first molecule in this SimInfo and intialize the iterator.
->
+         * @return the first molecule, return NULL if there is not molecule in this SimInfo
->
+         * @param i the iterator of molecule array (user shouldn't change it)
->
+         */
->
+        Molecule* beginMolecule(MoleculeIterator& i);
-<
-<
+  int usePBC; // whether we use periodic boundry conditions.
-<
+  int useLJ;
-<
+  int useSticky;
-<
+  int useCharges;
-<
+  int useDipoles;
-<
+  int useReactionField;
-<
+  int useGB;
-<
+  int useEAM;
-<
+  bool haveCutoffGroups;
-<
+  bool useInitXSstate;
-<
+  double orthoTolerance;
->
+        /**
->
+          * Returns the next avaliable Molecule based on the iterator.
->
+          * @return the next avaliable molecule, return NULL if reaching the end of the array
->
+          * @param i the iterator of molecule array
->
+          */
->
+        Molecule* nextMolecule(MoleculeIterator& i);
-<
+  double dt, run_time;           // the time step and total time
-<
+  double sampleTime, statusTime; // the position and energy dump frequencies
-<
+  double target_temp;            // the target temperature of the system
-<
+  double thermalTime;            // the temp kick interval
-<
+  double currentTime;            // Used primarily for correlation Functions
-<
+  double resetTime;              // Use to reset the integrator periodically
-<
+  short int have_target_temp;
->
+        /** Returns the number of degrees of freedom */
->
+        int getNdf() {
->
+            return ndf_;
->
+        }
-<
+  int n_mol;           // n_molecules;
-<
+  Molecule* molecules; // the array of molecules
-<
-<
+  int nComponents;           // the number of components in the system
-<
+  int* componentsNmol;       // the number of molecules of each component
-<
+  MoleculeStamp** compStamps;// the stamps matching the components
-<
+  LinkedMolStamp* headStamp; // list of stamps used in the simulation
-<
-<
-<
+  char ensemble[100]; // the enesemble of the simulation (NVT, NVE, etc. )
-<
+  char mixingRule[100]; // the mixing rules for Lennard jones/van der walls
-<
+  BaseIntegrator *the_integrator; // the integrator of the simulation
->
+        /** Returns the number of raw degrees of freedom */
->
+        int getNdfRaw() {
->
+            return ndfRaw_;
->
+        }
-<
+  OOPSEMinimizer* the_minimizer; // the energy minimizer
-<
+  Restraints* restraint;
-<
+  bool has_minimizer;
->
+        /** Returns the number of translational degrees of freedom */
->
+        int getNdfTrans() {
->
+            return ndfTrans_;
->
+        }
-<
+  string finalName;  // the name of the eor file to be written
-<
+  string sampleName; // the name of the dump file to be written
-<
+  string statusName; // the name of the stat file to be written
->
+        //getNZconstraint and setNZconstraint ruin the coherent of SimInfo class, need refactorying
->
->
+        /** Returns the total number of z-constraint molecules in the system */
->
+        int getNZconstraint() {
->
+            return nZconstraint_;
->
+        }
-<
+  int seed;                    //seed for random number generator
->
+        /**
->
+         * Sets the number of z-constraint molecules in the system.
->
+         */
->
+        void setNZconstraint(int nZconstraint) {
->
+            nZconstraint_ = nZconstraint;
->
+        }
->
->
+        /** Returns the snapshot manager. */
->
+        SnapshotManager* getSnapshotManager() {
->
+            return sman_;
->
+        }
-<
+  int useSolidThermInt;  // is solid-state thermodynamic integration being used
-<
+  int useLiquidThermInt; // is liquid thermodynamic integration being used
-<
+  double thermIntLambda; // lambda for TI
-<
+  double thermIntK;      // power of lambda for TI
-<
+  double vRaw;           // unperturbed potential for TI
-<
+  double vHarm;          // harmonic potential for TI
-<
+  int i;                 // just an int
->
+        /** Sets the snapshot manager. */
->
+        void setSnapshotManager(SnapshotManager* sman);
->
->
+        /** Returns the force field */
->
+        ForceField* getForceField() {
->
+            return forceField_;
->
+        }
-<
+  vector<double> mfact;
-<
+  vector<int> FglobalGroupMembership;
-<
+  int ngroup;
-<
+  int* globalGroupMembership;
->
+        Globals* getSimParams() {
->
+            return simParams_;
->
+        }
-<
+  // refreshes the sim if things get changed (load balanceing, volume
-<
+  // adjustment, etc.)
->
+        /** Returns the velocity of center of mass of the whole system.*/
->
+        Vector3d getComVel();
-<
+  void refreshSim( void );
-<
->
+        /** Returns the center of the mass of the whole system.*/
->
+        Vector3d getCom();
-<
+  // sets the internal function pointer to fortran.
->
+        /** main driver function to interact with fortran during the initialization and molecule migration */
->
+        void update();
-<
+  void setInternal( setFortranSim_TD fSetup,
-<
+                    setFortranBox_TD fBox,
-<
+                    notifyFortranCutOff_TD fCut){
-<
+    setFsimulation = fSetup;
-<
+    setFortranBoxSize = fBox;
-<
+    notifyFortranCutOffs = fCut;
-<
+  }
->
+        /** Returns the local index manager */
->
+        LocalIndexManager* getLocalIndexManager() {
->
+            return &localIndexMan_;
->
+        }
-<
+  int getNDF();
-<
+  int getNDFraw();
-<
+  int getNDFtranslational();
-<
+  int getTotIntegrableObjects();
-<
+  void setBox( double newBox[3] );
-<
+  void setBoxM( double newBox[3][3] );
-<
+  void getBoxM( double theBox[3][3] );
-<
+  void scaleBox( double scale );
-<
-<
+  void setDefaultRcut( double theRcut );
-<
+  void setDefaultRcut( double theRcut, double theRsw );
-<
+  void checkCutOffs( void );
->
+        int getMoleculeStampId(int globalIndex) {
->
+            //assert(globalIndex < molStampIds_.size())
->
+            return molStampIds_[globalIndex];
->
+        }
-<
+  double getRcut( void )  { return rCut; }
-<
+  double getRlist( void ) { return rList; }
-<
+  double getRsw( void )   { return rSw; }
-<
+  double getMaxCutoff( void ) { return maxCutoff; }
-<
-<
+  void setTime( double theTime ) { currentTime = theTime; }
-<
+  void incrTime( double the_dt ) { currentTime += the_dt; }
-<
+  void decrTime( double the_dt ) { currentTime -= the_dt; }
-<
+  double getTime( void ) { return currentTime; }
->
+        /** Returns the molecule stamp */
->
+        MoleculeStamp* getMoleculeStamp(int id) {
->
+            return moleculeStamps_[id];
->
+        }
-<
+  void wrapVector( double thePos[3] );
->
+        /** Return the total number of the molecule stamps */
->
+        int getNMoleculeStamp() {
->
+            return moleculeStamps_.size();
->
+        }
->
+        /**
->
+         * Finds a molecule with a specified global index
->
+         * @return a pointer point to found molecule
->
+         * @param index
->
+         */
->
+        Molecule* getMoleculeByGlobalIndex(int index) {
->
+            MoleculeIterator i;
->
+            i = molecules_.find(index);
-<
+  SimState* getConfiguration( void ) { return myConfiguration; }
-<
-<
+  void addProperty(GenericData* prop);
-<
+  GenericData* getProperty(const string& propName);
-<
+  //vector<GenericData*>& getProperties()  {return properties;}
->
+            return i != molecules_.end() ? i->second : NULL;
->
+        }
-<
+  int getSeed(void) {  return seed; }
-<
+  void setSeed(int theSeed) {  seed = theSeed;}
->
+        /** Calculate the maximum cutoff radius based on the atom types */
->
+        double calcMaxCutoffRadius();
-<
+private:
->
+        double getRcut() {
->
+            return rcut_;
->
+        }
-<
+  SimState* myConfiguration;
->
+        double getRsw() {
->
+            return rsw_;
->
+        }
->
->
+        std::string getFinalConfigFileName() {
->
+            return finalConfigFileName_;
->
+        }
->
->
+        void setFinalConfigFileName(const std::string& fileName) {
->
+            finalConfigFileName_ = fileName;
->
+        }
-<
+  int boxIsInit, haveRcut, haveRsw;
->
+        std::string getDumpFileName() {
->
+            return dumpFileName_;
->
+        }
->
->
+        void setDumpFileName(const std::string& fileName) {
->
+            dumpFileName_ = fileName;
->
+        }
-<
+  double rList, rCut; // variables for the neighborlist
-<
+  double rSw;         // the switching radius
->
+        std::string getStatFileName() {
->
+            return statFileName_;
->
+        }
->
->
+        void setStatFileName(const std::string& fileName) {
->
+            statFileName_ = fileName;
->
+        }
->
->
+        std::string getRestFileName() {
->
+          return restFileName_;
->
+        }
->
->
+        void setRestFileName(const std::string& fileName) {
->
+          restFileName_ = fileName;
->
+        }
-<
+  double maxCutoff;
->
+        /**
->
+         * Sets GlobalGroupMembership
->
+         * @see #SimCreator::setGlobalIndex
->
+         */
->
+        void setGlobalGroupMembership(const std::vector<int>& globalGroupMembership) {
->
+            assert(globalGroupMembership.size() == nGlobalAtoms_);
->
+            globalGroupMembership_ = globalGroupMembership;
->
+        }
-<
+  double distXY;
-<
+  double distYZ;
-<
+  double distZX;
-<
-<
+  void calcHmatInv( void );
-<
+  void calcBoxL();
-<
+  double calcMaxCutOff();
->
+        /**
->
+         * Sets GlobalMolMembership
->
+         * @see #SimCreator::setGlobalIndex
->
+         */
->
+        void setGlobalMolMembership(const std::vector<int>& globalMolMembership) {
->
+            assert(globalMolMembership.size() == nGlobalAtoms_);
->
+            globalMolMembership_ = globalMolMembership;
->
+        }
-–
+  // private function to initialize the fortran side of the simulation
-–
+  setFortranSim_TD setFsimulation;
-<
+  setFortranBox_TD setFortranBoxSize;
-<
-<
+  notifyFortranCutOff_TD notifyFortranCutOffs;
-<
-<
+  //Addtional Properties of SimInfo
-<
+  map<string, GenericData*> properties;
-<
+  void getFortranGroupArrays(SimInfo* info,
-<
+                             vector<int>& FglobalGroupMembership,
-<
+                             vector<double>& mfact);
->
+        bool isFortranInitialized() {
->
+            return fortranInitialized_;
->
+        }
->
->
+        //below functions are just forward functions
->
+        //To compose or to inherit is always a hot debate. In general, is-a relation need subclassing, in the
->
+        //the other hand, has-a relation need composing.
->
+        /**
->
+         * Adds property into property map
->
+         * @param genData GenericData to be added into PropertyMap
->
+         */
->
+        void addProperty(GenericData* genData);
-+
+        /**
-+
+         * Removes property from PropertyMap by name
-+
+         * @param propName the name of property to be removed
-+
+         */
-+
+        void removeProperty(const std::string& propName);
-<
+};
->
+        /**
->
+         * clear all of the properties
->
+         */
->
+        void clearProperties();
-+
+        /**
-+
+         * Returns all names of properties
-+
+         * @return all names of properties
-+
+         */
-+
+        std::vector<std::string> getPropertyNames();
-+
+        /**
-+
+         * Returns all of the properties in PropertyMap
-+
+         * @return all of the properties in PropertyMap
-+
+         */
-+
+        std::vector<GenericData*> getProperties();
-+
-+
+        /**
-+
+         * Returns property
-+
+         * @param propName name of property
-+
+         * @return a pointer point to property with propName. If no property named propName
-+
+         * exists, return NULL
-+
+         */
-+
+        GenericData* getPropertyByName(const std::string& propName);
-+
-+
+        /**
-+
+         * add all exclude pairs of a molecule into exclude list.
-+
+         */
-+
+        void addExcludePairs(Molecule* mol);
-+
-+
+        /**
-+
+         * remove all exclude pairs which belong to a molecule from exclude list
-+
+         */
-+
-+
+        void removeExcludePairs(Molecule* mol);
-+
-+
-+
+        /** Returns the unique atom types of local processor in an array */
-+
+        std::set<AtomType*> getUniqueAtomTypes();
-+
-+
+        friend std::ostream& operator <<(std::ostream& o, SimInfo& info);
-+
-+
+        void getCutoff(double& rcut, double& rsw);
-+
-+
+    private:
-+
-+
+        /** fill up the simtype struct*/
-+
+        void setupSimType();
-+
-+
+        /**
-+
+         * Setup Fortran Simulation
-+
+         * @see #setupFortranParallel
-+
+         */
-+
+        void setupFortranSim();
-+
-+
+        /** Figure out the radius of cutoff, radius of switching function and pass them to fortran */
-+
+        void setupCutoff();
-+
-+
+        /** Calculates the number of degress of freedom in the whole system */
-+
+        void calcNdf();
-+
+        void calcNdfRaw();
-+
+        void calcNdfTrans();
-+
-+
+        /**
-+
+         * Adds molecule stamp and the total number of the molecule with same molecule stamp in the whole
-+
+         * system.
-+
+         */
-+
+        void addMoleculeStamp(MoleculeStamp* molStamp, int nmol);
-+
-+
+        ForceField* forceField_;
-+
+        Globals* simParams_;
-+
-+
+        std::map<int, Molecule*>  molecules_; /**< Molecule array */
-+
-+
+        //degress of freedom
-+
+        int ndf_;           /**< number of degress of freedom (excludes constraints),  ndf_ is local */
-+
+        int ndfRaw_;    /**< number of degress of freedom (includes constraints),  ndfRaw_ is local */
-+
+        int ndfTrans_; /**< number of translation degress of freedom, ndfTrans_ is local */
-+
+        int nZconstraint_; /** number of  z-constraint molecules, nZconstraint_ is global */
-+
-+
+        //number of global objects
-+
+        int nGlobalMols_;       /**< number of molecules in the system */
-+
+        int nGlobalAtoms_;   /**< number of atoms in the system */
-+
+        int nGlobalCutoffGroups_; /**< number of cutoff groups in this system */
-+
+        int nGlobalIntegrableObjects_; /**< number of integrable objects in this system */
-+
+        int nGlobalRigidBodies_; /**< number of rigid bodies in this system */
-+
+        /**
-+
+         * the size of globalGroupMembership_  is nGlobalAtoms. Its index is  global index of an atom, and the
-+
+         * corresponding content is the global index of cutoff group this atom belong to.
-+
+         * It is filled by SimCreator once and only once, since it never changed during the simulation.
-+
+         */
-+
+        std::vector<int> globalGroupMembership_;
-+
-+
+        /**
-+
+         * the size of globalGroupMembership_  is nGlobalAtoms. Its index is  global index of an atom, and the
-+
+         * corresponding content is the global index of molecule this atom belong to.
-+
+         * It is filled by SimCreator once and only once, since it is never changed during the simulation.
-+
+         */
-+
+        std::vector<int> globalMolMembership_;
-+
-+
-+
+        std::vector<int> molStampIds_;                                /**< stamp id array of all molecules in the system */
-+
+        std::vector<MoleculeStamp*> moleculeStamps_;      /**< molecule stamps array */
-+
-+
+        //number of local objects
-+
+        int nAtoms_;                        /**< number of atoms in local processor */
-+
+        int nBonds_;                        /**< number of bonds in local processor */
-+
+        int nBends_;                        /**< number of bends in local processor */
-+
+        int nTorsions_;                    /**< number of torsions in local processor */
-+
+        int nRigidBodies_;              /**< number of rigid bodies in local processor */
-+
+        int nIntegrableObjects_;    /**< number of integrable objects in local processor */
-+
+        int nCutoffGroups_;             /**< number of cutoff groups in local processor */
-+
+        int nConstraints_;              /**< number of constraints in local processors */
-+
-+
+        simtype fInfo_; /**< A dual struct shared by c++/fortran which indicates the atom types in simulation*/
-+
+        Exclude exclude_;
-+
+        PropertyMap properties_;                  /**< Generic Property */
-+
+        SnapshotManager* sman_;               /**< SnapshotManager */
-+
-+
+        /**
-+
+         * The reason to have a local index manager is that when molecule is migrating to other processors,
-+
+         * the atoms and the rigid-bodies will release their local indices to LocalIndexManager. Combining the
-+
+         * information of molecule migrating to current processor, Migrator class can query  the LocalIndexManager
-+
+         * to make a efficient data moving plan.
-+
+         */
-+
+        LocalIndexManager localIndexMan_;
-+
-+
+        //file names
-+
+        std::string finalConfigFileName_;
-+
+        std::string dumpFileName_;
-+
+        std::string statFileName_;
-+
+        std::string restFileName_;
-+
-+
+        double rcut_;       /**< cutoff radius*/
-+
+        double rsw_;        /**< radius of switching function*/
-+
-+
+        bool fortranInitialized_; /**< flag indicate whether fortran side is initialized */
-+
-+
+#ifdef IS_MPI
-+
+    //in Parallel version, we need MolToProc
-+
+    public:
-+
-+
+        /**
-+
+         * Finds the processor where a molecule resides
-+
+         * @return the id of the processor which contains the molecule
-+
+         * @param globalIndex global Index of the molecule
-+
+         */
-+
+        int getMolToProc(int globalIndex) {
-+
+            //assert(globalIndex < molToProcMap_.size());
-+
+            return molToProcMap_[globalIndex];
-+
+        }
-+
-+
+        /**
-+
+         * Set MolToProcMap array
-+
+         * @see #SimCreator::divideMolecules
-+
+         */
-+
+        void setMolToProcMap(const std::vector<int>& molToProcMap) {
-+
+            molToProcMap_ = molToProcMap;
-+
+        }
-+
-+
+    private:
-+
-+
+        void setupFortranParallel();
-+
-+
+        /**
-+
+         * The size of molToProcMap_ is equal to total number of molecules in the system.
-+
+         *  It maps a molecule to the processor on which it resides. it is filled by SimCreator once and only
-+
+         * once.
-+
+         */
-+
+        std::vector<int> molToProcMap_;
-+
+#endif
-+
-+
+};
-+
-+
+} //namespace oopse
-+
+#endif //BRAINS_SIMMODEL_HPP
-+

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+Removed lines
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-<
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Comparing trunk/OOPSE-2.0/src/brains/SimInfo.hpp (file contents): Revision 1492 by tim, Fri Sep 24 16:27:58 2004 UTC vs. Revision 2101 by chrisfen, Thu Mar 10 15:10:24 2005 UTC

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Comparing trunk/OOPSE-2.0/src/brains/SimInfo.hpp (file contents):
Revision 1492 by tim, Fri Sep 24 16:27:58 2004 UTC vs.
Revision 2101 by chrisfen, Thu Mar 10 15:10:24 2005 UTC