OOPSE/libmdtools/SimInfo.hpp

#ifndef __SIMINFO_H__
#define __SIMINFO_H__

#include <map>
#include <string>
#include <vector>

#include "Atom.hpp"
#include "Molecule.hpp"
#include "AbstractClasses.hpp"
#include "MakeStamps.hpp"
#include "SimState.hpp"

#define __C
#include "fSimulation.h"
#include "fortranWrapDefines.hpp"
#include "GenericData.hpp"


class SimInfo{

public:

  SimInfo();
  ~SimInfo();

  int n_atoms; // the number of atoms
  Atom **atoms; // the array of atom objects
  
  double tau[9]; // the stress tensor

  unsigned int n_bonds;    // number of bends
  unsigned int n_bends;    // number of bends
  unsigned int n_torsions; // number of torsions
  unsigned int n_oriented; // number of of atoms with orientation
  unsigned int ndf;        // number of actual degrees of freedom
  unsigned int ndfRaw;     // number of settable degrees of freedom

  unsigned int setTemp;   // boolean to set the temperature at each sampleTime

  unsigned int n_dipoles; // number of dipoles


  int n_exclude;  // the # of pairs excluded from long range forces
  Exclude** excludes;       // the pairs themselves

  int nGlobalExcludes;
  int* globalExcludes; // same as above, but these guys participate in
                       // no long range forces.

  int* identArray;     // array of unique identifiers for the atoms
  int* molMembershipArray;  // map of atom numbers onto molecule numbers

  int n_constraints; // the number of constraints on the system

  unsigned int n_SRI;   // the number of short range interactions

  double lrPot; // the potential energy from the long range calculations.

  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];

  double boxL[3]; // The Lengths of the 3 column vectors of Hmat
  double boxVol;
  int orthoRhombic;
  

  double dielectric;      // the dielectric of the medium for reaction field

  
  int usePBC; // whether we use periodic boundry conditions.
  int useLJ; 
  int useSticky;
  int useDipole;
  int useReactionField;
  int useGB;
  int useEAM;
  

  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

  int n_mol;           // n_molecules;
  Molecule* molecules; // the array of molecules
  
  int nComponents;           // the number of componentsin 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

  char finalName[300];  // the name of the eor file to be written
  char sampleName[300]; // the name of the dump file to be written
  char statusName[300]; // the name of the stat file to be written


  // refreshes the sim if things get changed (load balanceing, volume
  // adjustment, etc.)

  void refreshSim( void );
  

  // sets the internal function pointer to fortran.

  void setInternal( void (*fSetup) setFortranSimList, 
                    void (*fBox) setFortranBoxList, 
                    void (*fCut) notifyFortranCutOffList ){
    setFsimulation = fSetup;
    setFortranBoxSize = fBox;
    notifyFortranCutOffs = fCut;
  }

  int getNDF();
  int getNDFraw();

  void setBox( double newBox[3] );
  void setBoxM( double newBox[3][3] );
  void getBoxM( double theBox[3][3] );
  void scaleBox( double scale );
  
  void setRcut( double theRcut );
  void setEcr( double theEcr );
  void setEcr( double theEcr, double theEst );

  double getRcut( void )  { return rCut; }
  double getRlist( void ) { return rList; }
  double getEcr( void )   { return ecr; }
  double getEst( void )   { return est; }

  void setTime( double theTime ) { currentTime = theTime; }
  void incrTime( double dt ) { currentTime += dt; }
  void decrTime( double dt ) { currentTime -= dt; }
  double getTime( void ) { return currentTime; }

  void wrapVector( double thePos[3] );

  void matMul3(double a[3][3], double b[3][3], double out[3][3]);
  void matVecMul3(double m[3][3], double inVec[3], double outVec[3]);
  void invertMat3(double in[3][3], double out[3][3]);
  void transposeMat3(double in[3][3], double out[3][3]);
  void printMat3(double A[3][3]);
  void printMat9(double A[9]);
  double matDet3(double m[3][3]);

  SimState* getConfiguration( void ) { return myConfiguration; }
  
  void addProperty(GenericData* prop); 
  GenericData* getProperty(const string& propName);
  vector<GenericData*> getProperties();       

private:

  SimState* myConfiguration;

  double origRcut, origEcr;
  int boxIsInit, haveOrigRcut, haveOrigEcr;

  double oldEcr;
  double oldRcut;

  double rList, rCut; // variables for the neighborlist
  double ecr;             // the electrostatic cutoff radius
  double est;             // the electrostatic skin thickness
  double maxCutoff;
  
  void calcHmatInv( void );
  void calcBoxL();
  void checkCutOffs( void );

  // private function to initialize the fortran side of the simulation
  void (*setFsimulation) setFortranSimList;

  void (*setFortranBoxSize) setFortranBoxList;
  
  void (*notifyFortranCutOffs) notifyFortranCutOffList;
  
  //Addtional Properties of SimInfo
  map<string, GenericData*> properties;

};


#endif
Revision:	670
Committed:	Thu Aug 7 21:47:18 2003 UTC (20 years, 11 months ago) by mmeineke
File size:	5873 byte(s)
Log Message:	switched SimInfo to use a system configuration from SimState rather than arrays from Atom
#	Content
1	#ifndef __SIMINFO_H__
2	#define __SIMINFO_H__
3
4	#include <map>
5	#include <string>
6	#include <vector>
7
8	#include "Atom.hpp"
9	#include "Molecule.hpp"
10	#include "AbstractClasses.hpp"
11	#include "MakeStamps.hpp"
12	#include "SimState.hpp"
13
14	#define __C
15	#include "fSimulation.h"
16	#include "fortranWrapDefines.hpp"
17	#include "GenericData.hpp"
18
19
20
21	class SimInfo{
22
23	public:
24
25	SimInfo();
26	~SimInfo();
27
28	int n_atoms; // the number of atoms
29	Atom **atoms; // the array of atom objects
30
31	double tau[9]; // the stress tensor
32
33	unsigned int n_bonds; // number of bends
34	unsigned int n_bends; // number of bends
35	unsigned int n_torsions; // number of torsions
36	unsigned int n_oriented; // number of of atoms with orientation
37	unsigned int ndf; // number of actual degrees of freedom
38	unsigned int ndfRaw; // number of settable degrees of freedom
39
40	unsigned int setTemp; // boolean to set the temperature at each sampleTime
41
42	unsigned int n_dipoles; // number of dipoles
43
44
45	int n_exclude; // the # of pairs excluded from long range forces
46	Exclude** excludes; // the pairs themselves
47
48	int nGlobalExcludes;
49	int* globalExcludes; // same as above, but these guys participate in
50	// no long range forces.
51
52	int* identArray; // array of unique identifiers for the atoms
53	int* molMembershipArray; // map of atom numbers onto molecule numbers
54
55	int n_constraints; // the number of constraints on the system
56
57	unsigned int n_SRI; // the number of short range interactions
58
59	double lrPot; // the potential energy from the long range calculations.
60
61	double Hmat[3][3]; // the periodic boundry conditions. The Hmat is the
62	// column vectors of the x, y, and z box vectors.
63	// h1 h2 h3
64	// [ Xx Yx Zx ]
65	// [ Xy Yy Zy ]
66	// [ Xz Yz Zz ]
67	//
68	double HmatInv[3][3];
69
70	double boxL[3]; // The Lengths of the 3 column vectors of Hmat
71	double boxVol;
72	int orthoRhombic;
73
74
75	double dielectric; // the dielectric of the medium for reaction field
76
77
78	int usePBC; // whether we use periodic boundry conditions.
79	int useLJ;
80	int useSticky;
81	int useDipole;
82	int useReactionField;
83	int useGB;
84	int useEAM;
85
86
87	double dt, run_time; // the time step and total time
88	double sampleTime, statusTime; // the position and energy dump frequencies
89	double target_temp; // the target temperature of the system
90	double thermalTime; // the temp kick interval
91	double currentTime; // Used primarily for correlation Functions
92
93	int n_mol; // n_molecules;
94	Molecule* molecules; // the array of molecules
95
96	int nComponents; // the number of componentsin the system
97	int* componentsNmol; // the number of molecules of each component
98	MoleculeStamp** compStamps;// the stamps matching the components
99	LinkedMolStamp* headStamp; // list of stamps used in the simulation
100
101
102	char ensemble[100]; // the enesemble of the simulation (NVT, NVE, etc. )
103	char mixingRule[100]; // the mixing rules for Lennard jones/van der walls
104	BaseIntegrator *the_integrator; // the integrator of the simulation
105
106	char finalName[300]; // the name of the eor file to be written
107	char sampleName[300]; // the name of the dump file to be written
108	char statusName[300]; // the name of the stat file to be written
109
110
111	// refreshes the sim if things get changed (load balanceing, volume
112	// adjustment, etc.)
113
114	void refreshSim( void );
115
116
117	// sets the internal function pointer to fortran.
118
119	void setInternal( void (*fSetup) setFortranSimList,
120	void (*fBox) setFortranBoxList,
121	void (*fCut) notifyFortranCutOffList ){
122	setFsimulation = fSetup;
123	setFortranBoxSize = fBox;
124	notifyFortranCutOffs = fCut;
125	}
126
127	int getNDF();
128	int getNDFraw();
129
130	void setBox( double newBox[3] );
131	void setBoxM( double newBox[3][3] );
132	void getBoxM( double theBox[3][3] );
133	void scaleBox( double scale );
134
135	void setRcut( double theRcut );
136	void setEcr( double theEcr );
137	void setEcr( double theEcr, double theEst );
138
139	double getRcut( void ) { return rCut; }
140	double getRlist( void ) { return rList; }
141	double getEcr( void ) { return ecr; }
142	double getEst( void ) { return est; }
143
144	void setTime( double theTime ) { currentTime = theTime; }
145	void incrTime( double dt ) { currentTime += dt; }
146	void decrTime( double dt ) { currentTime -= dt; }
147	double getTime( void ) { return currentTime; }
148
149	void wrapVector( double thePos[3] );
150
151	void matMul3(double a[3][3], double b[3][3], double out[3][3]);
152	void matVecMul3(double m[3][3], double inVec[3], double outVec[3]);
153	void invertMat3(double in[3][3], double out[3][3]);
154	void transposeMat3(double in[3][3], double out[3][3]);
155	void printMat3(double A[3][3]);
156	void printMat9(double A[9]);
157	double matDet3(double m[3][3]);
158
159	SimState* getConfiguration( void ) { return myConfiguration; }
160
161	void addProperty(GenericData* prop);
162	GenericData* getProperty(const string& propName);
163	vector<GenericData*> getProperties();
164
165	private:
166
167	SimState* myConfiguration;
168
169	double origRcut, origEcr;
170	int boxIsInit, haveOrigRcut, haveOrigEcr;
171
172	double oldEcr;
173	double oldRcut;
174
175	double rList, rCut; // variables for the neighborlist
176	double ecr; // the electrostatic cutoff radius
177	double est; // the electrostatic skin thickness
178	double maxCutoff;
179
180	void calcHmatInv( void );
181	void calcBoxL();
182	void checkCutOffs( void );
183
184	// private function to initialize the fortran side of the simulation
185	void (*setFsimulation) setFortranSimList;
186
187	void (*setFortranBoxSize) setFortranBoxList;
188
189	void (*notifyFortranCutOffs) notifyFortranCutOffList;
190
191	//Addtional Properties of SimInfo
192	map<string, GenericData*> properties;
193
194	};
195
196
197
198	#endif