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root/group/trunk/OOPSE/libmdtools/Integrator.hpp
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Comparing trunk/OOPSE/libmdtools/Integrator.hpp (file contents):
Revision 378 by mmeineke, Fri Mar 21 17:42:12 2003 UTC vs.
Revision 696 by tim, Thu Aug 14 16:16:39 2003 UTC

# Line 1 | Line 1
1   #ifndef _INTEGRATOR_H_
2   #define _INTEGRATOR_H_
3  
4 + #include <string>
5 + #include <vector>
6   #include "Atom.hpp"
7 + #include "Molecule.hpp"
8   #include "SRI.hpp"
9   #include "AbstractClasses.hpp"
10   #include "SimInfo.hpp"
11   #include "ForceFields.hpp"
12 + #include "Thermo.hpp"
13 + #include "ReadWrite.hpp"
14 + #include "ZConsWriter.hpp"
15  
16 < class Verlet : public Integrator {
16 > using namespace std;
17 > const double kB = 8.31451e-7;// boltzmann constant amu*Ang^2*fs^-2/K
18 > const double eConvert = 4.184e-4; // converts kcal/mol -> amu*A^2/fs^2
19 > const double p_convert = 1.63882576e8; //converts amu*fs^-2*Ang^-1 -> atm
20 > const int maxIteration = 300;
21 > const double tol = 1.0e-6;
22  
23 +
24 + template<typename T = BaseIntegrator> class Integrator : public T {
25 +
26   public:
27 <  Verlet( SimInfo &info, ForceFields* the_ff );
28 <  ~Verlet();
27 >  Integrator( SimInfo *theInfo, ForceFields* the_ff );
28 >  virtual ~Integrator();
29    void integrate( void );
30  
31 < private:
31 >
32 > protected:
33    
34 <  void move_a( double dt );
35 <  void move_b( double dt );
34 >  virtual void integrateStep( int calcPot, int calcStress );
35 >  virtual void preMove( void );
36 >  virtual void moveA( void );
37 >  virtual void moveB( void );
38 >  virtual void constrainA( void );
39 >  virtual void constrainB( void );
40 >  virtual int  readyCheck( void ) { return 1; }
41  
42 +  virtual void calcForce( int calcPot, int calcStress );  
43 +  virtual void thermalize();
44 +  
45 +  void checkConstraints( void );
46 +  void rotate( int axes1, int axes2, double angle, double j[3],
47 +               double A[3][3] );
48 +              
49    ForceFields* myFF;
50  
51 <  SimInfo *entry_plug; // all the info we'll ever need
52 <  int c_natoms;  /* the number of atoms */
53 <  Atom **c_atoms; /* array of atom pointers */
54 <  SRI **c_sr_interactions; /* array of SRI pointers */
55 <  int c_n_SRI; /* the number of short range interactions */
51 >  SimInfo *info; // all the info we'll ever need
52 >  int nAtoms;  /* the number of atoms */
53 >  int oldAtoms;
54 >  Atom **atoms; /* array of atom pointers */
55 >  Molecule* molecules;
56 >  int nMols;
57  
58 <  int c_is_constrained; /*boolean to know whether the systems contains
59 <                          constraints. */
60 <  int c_n_constrained; /*counter for number of constraints */
61 <  int *c_constrained_i; /* the i of a constraint pair */
62 <  int *c_constrained_j; /* the j of a constraint pair */
63 <  double *c_constrained_dsqr; /* the square of the constraint distance */
64 <  double *c_mass; /* the array of masses */
65 <  short is_first; /*boolean for the first time integrate is called */
66 <  double c_box_x;
67 <  double c_box_y;
68 <  double c_box_z;
58 >  int isConstrained; // boolean to know whether the systems contains
59 >                     // constraints.
60 >  int nConstrained;  // counter for number of constraints
61 >  int *constrainedA; // the i of a constraint pair
62 >  int *constrainedB; // the j of a constraint pair
63 >  double *constrainedDsqr; // the square of the constraint distance
64 >  
65 >  int* moving; // tells whether we are moving atom i
66 >  int* moved;  // tells whether we have moved atom i
67 >  double* oldPos; // pre constrained positions
68 >
69 >  short isFirst; /*boolean for the first time integrate is called */
70 >  
71 >  double dt;
72 >  double dt2;
73 >
74 >  Thermo *tStats;
75 >  StatWriter*  statOut;
76 >  DumpWriter*  dumpOut;
77 >  
78   };
79  
80 < class Symplectic : public Integrator {
80 > typedef Integrator<BaseIntegrator> RealIntegrator;
81 >
82 > template<typename T> class NVE : public T {
83 >
84 > public:
85 >  NVE ( SimInfo *theInfo, ForceFields* the_ff ):
86 >    T( theInfo, the_ff ){}
87 >  virtual ~NVE(){}  
88 > };
89 >
90 >
91 > template<typename T> class NVT : public T {
92 >
93 > public:
94 >
95 >  NVT ( SimInfo *theInfo, ForceFields* the_ff);
96 >  virtual ~NVT() {}
97 >
98 >  void setTauThermostat(double tt) {tauThermostat = tt; have_tau_thermostat=1;}
99 >  void setTargetTemp(double tt) {targetTemp = tt; have_target_temp = 1;}
100 >
101 > protected:
102 >
103 >  virtual void moveA( void );
104 >  virtual void moveB( void );
105 >
106 >  virtual int readyCheck();
107 >
108 >  // chi is a propagated degree of freedom.
109 >
110 >  double chi;
111 >
112 >  // targetTemp must be set.  tauThermostat must also be set;
113 >
114 >  double targetTemp;
115 >  double tauThermostat;
116    
117 +  short int have_tau_thermostat, have_target_temp;
118 +
119 + };
120 +
121 +
122 +
123 + template<typename T> class NPTi : public T{
124 +
125   public:
126 <  Symplectic( SimInfo* the_entry_plug,  ForceFields* the_ff );
127 <  ~Symplectic();
126 >
127 >  NPTi ( SimInfo *theInfo, ForceFields* the_ff);
128 >  virtual ~NPTi() {};
129 >
130 >  virtual void integrateStep( int calcPot, int calcStress ){
131 >    calcStress = 1;
132 >    T::integrateStep( calcPot, calcStress );
133 >  }
134 >
135 >  void setTauThermostat(double tt) {tauThermostat = tt; have_tau_thermostat=1;}
136 >  void setTauBarostat(double tb) {tauBarostat = tb; have_tau_barostat=1;}
137 >  void setTargetTemp(double tt) {targetTemp = tt; have_target_temp = 1;}
138 >  void setTargetPressure(double tp) {targetPressure = tp; have_target_pressure = 1;}
139 >
140 > protected:
141 >
142 >  virtual void  moveA( void );
143 >  virtual void moveB( void );
144 >
145 >  virtual int readyCheck();
146 >
147 >  // chi and eta are the propagated degrees of freedom
148 >
149 >  double chi;
150 >  double eta;
151 >  double NkBT;
152 >
153 >  // targetTemp, targetPressure, and tauBarostat must be set.  
154 >  // One of qmass or tauThermostat must be set;
155 >
156 >  double targetTemp;
157 >  double targetPressure;
158 >  double tauThermostat;
159 >  double tauBarostat;
160 >
161 >  short int have_tau_thermostat, have_tau_barostat, have_target_temp;
162 >  short int have_target_pressure;
163 >
164 > };
165 >
166 > template<typename T> class NPTim : public T{
167 >
168 > public:
169 >
170 >  NPTim ( SimInfo *theInfo, ForceFields* the_ff);
171 >  virtual ~NPTim() {};
172 >
173 >  virtual void integrateStep( int calcPot, int calcStress ){
174 >    calcStress = 1;
175 >    T::integrateStep( calcPot, calcStress );
176 >  }
177 >
178 >  void setTauThermostat(double tt) {tauThermostat = tt; have_tau_thermostat=1;}
179 >  void setTauBarostat(double tb) {tauBarostat = tb; have_tau_barostat=1;}
180 >  void setTargetTemp(double tt) {targetTemp = tt; have_target_temp = 1;}
181 >  void setTargetPressure(double tp) {targetPressure = tp; have_target_pressure = 1;}
182 >
183 > protected:
184 >
185 >  virtual void moveA( void );
186 >  virtual void moveB( void );
187 >
188 >  virtual int readyCheck();
189 >
190 >  Molecule* myMolecules;
191 >  Atom** myAtoms;
192 >
193 >  // chi and eta are the propagated degrees of freedom
194 >
195 >  double chi;
196 >  double eta;
197 >  double NkBT;
198 >
199 >  // targetTemp, targetPressure, and tauBarostat must be set.  
200 >  // One of qmass or tauThermostat must be set;
201 >
202 >  double targetTemp;
203 >  double targetPressure;
204 >  double tauThermostat;
205 >  double tauBarostat;
206 >
207 >  short int have_tau_thermostat, have_tau_barostat, have_target_temp;
208 >  short int have_target_pressure;
209 >
210 > };
211 >
212 > template<typename T> class NPTf : public T{
213 >
214 > public:
215 >
216 >  NPTf ( SimInfo *theInfo, ForceFields* the_ff);
217 >  virtual ~NPTf() {};
218 >
219 >  virtual void integrateStep( int calcPot, int calcStress ){
220 >    calcStress = 1;
221 >    T::integrateStep( calcPot, calcStress );
222 >  }
223 >
224 >  void setTauThermostat(double tt) {tauThermostat = tt; have_tau_thermostat=1;}
225 >  void setTauBarostat(double tb) {tauBarostat = tb; have_tau_barostat=1;}
226 >  void setTargetTemp(double tt) {targetTemp = tt; have_target_temp = 1;}
227 >  void setTargetPressure(double tp) {targetPressure = tp; have_target_pressure = 1;}
228 >
229 > protected:
230 >
231 >  virtual void  moveA( void );
232 >  virtual void moveB( void );
233 >
234 >  virtual int readyCheck();
235 >
236 >  // chi and eta are the propagated degrees of freedom
237 >
238 >  double chi;
239 >  double eta[3][3];
240 >  double NkBT;
241 >
242 >  // targetTemp, targetPressure, and tauBarostat must be set.  
243 >  // One of qmass or tauThermostat must be set;
244 >
245 >  double targetTemp;
246 >  double targetPressure;
247 >  double tauThermostat;
248 >  double tauBarostat;
249 >
250 >  short int have_tau_thermostat, have_tau_barostat, have_target_temp;
251 >  short int have_target_pressure;
252 >
253 > };
254 >
255 > template<typename T> class NPTfm : public T{
256 >
257 > public:
258 >
259 >  NPTfm ( SimInfo *theInfo, ForceFields* the_ff);
260 >  virtual ~NPTfm() {};
261 >
262 >  virtual void integrateStep( int calcPot, int calcStress ){
263 >    calcStress = 1;
264 >    T::integrateStep( calcPot, calcStress );
265 >  }
266 >
267 >  void setTauThermostat(double tt) {tauThermostat = tt; have_tau_thermostat=1;}
268 >  void setTauBarostat(double tb) {tauBarostat = tb; have_tau_barostat=1;}
269 >  void setTargetTemp(double tt) {targetTemp = tt; have_target_temp = 1;}
270 >  void setTargetPressure(double tp) {targetPressure = tp; have_target_pressure = 1;}
271 >
272 > protected:
273 >
274 >  virtual void  moveA( void );
275 >  virtual void moveB( void );
276 >
277 >  virtual int readyCheck();
278 >
279 >  Molecule* myMolecules;
280 >  Atom** myAtoms;
281 >
282 >  // chi and eta are the propagated degrees of freedom
283 >
284 >  double chi;
285 >  double eta[3][3];
286 >  double NkBT;
287 >
288 >  // targetTemp, targetPressure, and tauBarostat must be set.  
289 >  // One of qmass or tauThermostat must be set;
290 >
291 >  double targetTemp;
292 >  double targetPressure;
293 >  double tauThermostat;
294 >  double tauBarostat;
295 >
296 >  short int have_tau_thermostat, have_tau_barostat, have_target_temp;
297 >  short int have_target_pressure;
298 >
299 > };
300 >
301 > template<typename T> class ZConstraint : public T {
302 >
303 > public:
304 >
305 >  ZConstraint( SimInfo *theInfo, ForceFields* the_ff);
306 >  ~ZConstraint();
307 >    
308 >  void setZConsTime(double time)                  {this->zconsTime = time;}
309 >  void getZConsTime()                             {return zconsTime;}
310    
311 <  void integrate( void );
311 >  void setIndexOfAllZConsMols(vector<int> index)  {indexOfAllZConsMols = index;}
312 >  void getIndexOfAllZConsMols()                   {return indexOfAllZConsMols;}
313 >  
314 >  void setZConsOutput(const char * fileName)      {zconsOutput = fileName;}
315 >  string getZConsOutput()                         {return zconsOutput;}
316 >  
317 >  virtual void integrate();
318 >  
319  
320 < private:
320 > #ifdef IS_MPI
321 >  virtual void update(); //which is called to indicate the molecules' migration
322 > #endif
323  
324 <  void rotate( int axes1, int axes2, double angle, double j[3],
54 <               double A[3][3] );
324 > protected:
325  
326 <  SimInfo* entry_plug;
57 <  ForceFields* myFF;
326 >  enum ZConsState {zcsMoving, zcsFixed};
327  
59  int is_constrained; /*boolean to know whether the systems contains
60                          constraints. */
61  int n_constrained; /*counter for number of constraints */
62  int *constrained_i; /* the i of a constraint pair */
63  int *constrained_j; /* the j of a constraint pair */
64  double *constrained_dsqr; /* the square of the constraint distance */
65  double *mass; /* the array of masses */
328  
329 <  short int isFirst;
329 >
330 >  virtual void calcForce( int calcPot, int calcStress );
331 >  virtual void thermalize(void);
332 >  
333 >  void zeroOutVel();
334 >  void doZconstraintForce();
335 >  void doHarmonic();
336 >  bool checkZConsState();
337  
338 <  SRI **srInteractions; /* array of SRI pointers */
339 <  int nSRI; /* the number of short range interactions */
338 >  bool haveFixedZMols();
339 >  bool haveMovingZMols();
340 >
341 >  double calcZSys();
342 >
343 >  int isZConstraintMol(Molecule* mol);
344 >
345 >
346 >  double zconsTime;
347 >  double zconsTol;
348 >  double zForceConst;
349    
350 +  vector<Molecule*> zconsMols;
351 +  vector<double> massOfZConsMols;
352 +  vector<double> kz;
353 +  vector<ZConsState> states;
354 +  vector<double> zPos;
355 +  
356 +  
357 +  vector<Molecule*> unconsMols;
358 +  vector<double> massOfUnconsMols;
359 +  double totalMassOfUncons;
360 +
361 +  vector<ZConsParaItem>* parameters;
362 +  
363 +  vector<int> indexOfAllZConsMols;     //index of All Z-Constraint Molecuels
364 +
365 +  int* indexOfZConsMols;                   //index of local Z-Constraint Molecules  
366 +  double* fz;
367 +  
368 +  int totNumOfUnconsAtoms;
369 +
370 +  int whichDirection;                           //constraint direction
371 +  
372 + private:
373 +  
374 +  string zconsOutput;
375 +  ZConsWriter* fzOut;
376 +
377 +  double calcMovingMolsCOMVel();
378 +  double calcSysCOMVel();
379 +  double calcTotalForce();
380 +
381   };
382  
383   #endif

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