[ViewVC] Diff of: group/trunk/OOPSE/libmdtools/SimInfo.cpp

Comparing trunk/OOPSE/libmdtools/SimInfo.cpp (file contents):
Revision 574 by gezelter, Tue Jul 8 20:56:10 2003 UTC vs.
Revision 1144 by tim, Sat May 1 18:52:38 2004 UTC

#	Line 1 \| Line 1
1	<	#include <cstdlib>
2	<	#include <cstring>
3	<	#include <cmath>
1	>	#include <stdlib.h>
2	>	#include <string.h>
3	>	#include <math.h>
4
5		#include <iostream>
6		using namespace std;
#	Line 12 \| Line 12 \| using namespace std;
12
13		#include "fortranWrappers.hpp"
14
15	+	#include "MatVec3.h"
16	+
17		#ifdef IS_MPI
18		#include "mpiSimulation.hpp"
19		#endif
#	Line 20 \| Line 22 \| inline double roundMe( double x ){
22		return ( x >= 0 ) ? floor( x + 0.5 ) : ceil( x - 0.5 );
23		}
24
25	+	inline double min( double a, double b ){
26	+	return (a < b ) ? a : b;
27	+	}
28
29		SimInfo* currentInfo;
30
31		SimInfo::SimInfo(){
32	<	excludes = NULL;
32	>
33		n_constraints = 0;
34	+	nZconstraints = 0;
35		n_oriented = 0;
36		n_dipoles = 0;
37		ndf = 0;
38		ndfRaw = 0;
39	+	nZconstraints = 0;
40		the_integrator = NULL;
41		setTemp = 0;
42		thermalTime = 0.0;
43	+	currentTime = 0.0;
44		rCut = 0.0;
45	+	ecr = 0.0;
46	+	est = 0.0;
47
48	+	haveRcut = 0;
49	+	haveEcr = 0;
50	+	boxIsInit = 0;
51	+
52	+	resetTime = 1e99;
53	+
54	+	orthoRhombic = 0;
55	+	orthoTolerance = 1E-6;
56	+	useInitXSstate = true;
57	+
58		usePBC = 0;
59		useLJ = 0;
60		useSticky = 0;
61	<	useDipole = 0;
61	>	useCharges = 0;
62	>	useDipoles = 0;
63		useReactionField = 0;
64		useGB = 0;
65		useEAM = 0;
66	+	useMolecularCutoffs = 0;
67
68	<	wrapMeSimInfo( this );
47	<	}
68	>	excludes = Exclude::Instance();
69
70	<	void SimInfo::setBox(double newBox[3]) {
70	>	myConfiguration = new SimState();
71
72	<	double smallestBoxL, maxCutoff;
73	<	int status;
53	<	int i;
72	>	has_minimizer = false;
73	>	the_minimizer =NULL;
74
75	<	for(i=0; i<9; i++) Hmat[i] = 0.0;;
75	>	ngroup = 0;
76
77	<	Hmat[0] = newBox[0];
78	<	Hmat[4] = newBox[1];
59	<	Hmat[8] = newBox[2];
77	>	wrapMeSimInfo( this );
78	>	}
79
61	–	calcHmatI();
62	–	calcBoxL();
80
81	<	setFortranBoxSize(Hmat, HmatI, &orthoRhombic);
81	>	SimInfo::~SimInfo(){
82
83	<	smallestBoxL = boxLx;
67	<	if (boxLy < smallestBoxL) smallestBoxL = boxLy;
68	<	if (boxLz < smallestBoxL) smallestBoxL = boxLz;
83	>	delete myConfiguration;
84
85	<	maxCutoff = smallestBoxL / 2.0;
85	>	map<string, GenericData*>::iterator i;
86	>
87	>	for(i = properties.begin(); i != properties.end(); i++)
88	>	delete (*i).second;
89	>
90	>	}
91
92	<	if (rList > maxCutoff) {
93	<	sprintf( painCave.errMsg,
94	<	"New Box size is forcing neighborlist radius down to %lf\n",
95	<	maxCutoff );
76	<	painCave.isFatal = 0;
77	<	simError();
92	>	void SimInfo::setBox(double newBox[3]) {
93	>
94	>	int i, j;
95	>	double tempMat[3][3];
96
97	<	rList = maxCutoff;
97	>	for(i=0; i<3; i++)
98	>	for (j=0; j<3; j++) tempMat[i][j] = 0.0;;
99
100	<	sprintf( painCave.errMsg,
101	<	"New Box size is forcing cutoff radius down to %lf\n",
102	<	maxCutoff - 1.0 );
84	<	painCave.isFatal = 0;
85	<	simError();
100	>	tempMat[0][0] = newBox[0];
101	>	tempMat[1][1] = newBox[1];
102	>	tempMat[2][2] = newBox[2];
103
104	<	rCut = rList - 1.0;
104	>	setBoxM( tempMat );
105
89	–	// list radius changed so we have to refresh the simulation structure.
90	–	refreshSim();
91	–	}
92	–
93	–	if (rCut > maxCutoff) {
94	–	sprintf( painCave.errMsg,
95	–	"New Box size is forcing cutoff radius down to %lf\n",
96	–	maxCutoff );
97	–	painCave.isFatal = 0;
98	–	simError();
99	–
100	–	status = 0;
101	–	LJ_new_rcut(&rCut, &status);
102	–	if (status != 0) {
103	–	sprintf( painCave.errMsg,
104	–	"Error in recomputing LJ shifts based on new rcut\n");
105	–	painCave.isFatal = 1;
106	–	simError();
107	–	}
108	–	}
106		}
107
108	<	void SimInfo::setBoxM( double theBox[9] ){
108	>	void SimInfo::setBoxM( double theBox[3][3] ){
109
110	<	int i, status;
111	<	double smallestBoxL, maxCutoff;
110	>	int i, j;
111	>	double FortranHmat[9]; // to preserve compatibility with Fortran the
112	>	// ordering in the array is as follows:
113	>	// [ 0 3 6 ]
114	>	// [ 1 4 7 ]
115	>	// [ 2 5 8 ]
116	>	double FortranHmatInv[9]; // the inverted Hmat (for Fortran);
117
118	<	for(i=0; i<9; i++) Hmat[i] = theBox[i];
119	<	calcHmatI();
118	>	if( !boxIsInit ) boxIsInit = 1;
119	>
120	>	for(i=0; i < 3; i++)
121	>	for (j=0; j < 3; j++) Hmat[i][j] = theBox[i][j];
122	>
123		calcBoxL();
124	+	calcHmatInv();
125
126	<	setFortranBoxSize(Hmat, HmatI, &orthoRhombic);
127	<
128	<	smallestBoxL = boxLx;
129	<	if (boxLy < smallestBoxL) smallestBoxL = boxLy;
124	<	if (boxLz < smallestBoxL) smallestBoxL = boxLz;
125	<
126	<	maxCutoff = smallestBoxL / 2.0;
127	<
128	<	if (rList > maxCutoff) {
129	<	sprintf( painCave.errMsg,
130	<	"New Box size is forcing neighborlist radius down to %lf\n",
131	<	maxCutoff );
132	<	painCave.isFatal = 0;
133	<	simError();
134	<
135	<	rList = maxCutoff;
136	<
137	<	sprintf( painCave.errMsg,
138	<	"New Box size is forcing cutoff radius down to %lf\n",
139	<	maxCutoff - 1.0 );
140	<	painCave.isFatal = 0;
141	<	simError();
142	<
143	<	rCut = rList - 1.0;
144	<
145	<	// list radius changed so we have to refresh the simulation structure.
146	<	refreshSim();
147	<	}
148	<
149	<	if (rCut > maxCutoff) {
150	<	sprintf( painCave.errMsg,
151	<	"New Box size is forcing cutoff radius down to %lf\n",
152	<	maxCutoff );
153	<	painCave.isFatal = 0;
154	<	simError();
155	<
156	<	status = 0;
157	<	LJ_new_rcut(&rCut, &status);
158	<	if (status != 0) {
159	<	sprintf( painCave.errMsg,
160	<	"Error in recomputing LJ shifts based on new rcut\n");
161	<	painCave.isFatal = 1;
162	<	simError();
126	>	for(i=0; i < 3; i++) {
127	>	for (j=0; j < 3; j++) {
128	>	FortranHmat[3*j + i] = Hmat[i][j];
129	>	FortranHmatInv[3*j + i] = HmatInv[i][j];
130		}
131		}
132	+
133	+	setFortranBoxSize(FortranHmat, FortranHmatInv, &orthoRhombic);
134	+
135		}
136
137
138	<	void SimInfo::getBoxM (double theBox[9]) {
138	>	void SimInfo::getBoxM (double theBox[3][3]) {
139
140	<	int i;
141	<	for(i=0; i<9; i++) theBox[i] = Hmat[i];
140	>	int i, j;
141	>	for(i=0; i<3; i++)
142	>	for (j=0; j<3; j++) theBox[i][j] = Hmat[i][j];
143		}
144
145
146		void SimInfo::scaleBox(double scale) {
147	<	double theBox[9];
148	<	int i;
147	>	double theBox[3][3];
148	>	int i, j;
149
150	<	for(i=0; i<9; i++) theBox[i] = Hmat[i]*scale;
150	>	// cerr << "Scaling box by " << scale << "\n";
151
152	+	for(i=0; i<3; i++)
153	+	for (j=0; j<3; j++) theBox[i][j] = Hmat[i][j]*scale;
154	+
155		setBoxM(theBox);
156
157		}
158
159	<	void SimInfo::calcHmatI( void ) {
160	<
161	<	double C[3][3];
162	<	double detHmat;
189	<	int i, j, k;
159	>	void SimInfo::calcHmatInv( void ) {
160	>
161	>	int oldOrtho;
162	>	int i,j;
163		double smallDiag;
164		double tol;
165		double sanity[3][3];
166
167	<	// calculate the adjunct of Hmat;
167	>	invertMat3( Hmat, HmatInv );
168
169	<	C[0][0] = ( Hmat[4]Hmat[8]) - (Hmat[7]Hmat[5]);
197	<	C[1][0] = -( Hmat[1]Hmat[8]) + (Hmat[7]Hmat[2]);
198	<	C[2][0] = ( Hmat[1]Hmat[5]) - (Hmat[4]Hmat[2]);
199	<
200	<	C[0][1] = -( Hmat[3]Hmat[8]) + (Hmat[6]Hmat[5]);
201	<	C[1][1] = ( Hmat[0]Hmat[8]) - (Hmat[6]Hmat[2]);
202	<	C[2][1] = -( Hmat[0]Hmat[5]) + (Hmat[3]Hmat[2]);
203	<
204	<	C[0][2] = ( Hmat[3]Hmat[7]) - (Hmat[6]Hmat[4]);
205	<	C[1][2] = -( Hmat[0]Hmat[7]) + (Hmat[6]Hmat[1]);
206	<	C[2][2] = ( Hmat[0]Hmat[4]) - (Hmat[3]Hmat[1]);
207	<
208	<	// calcutlate the determinant of Hmat
169	>	// check to see if Hmat is orthorhombic
170
171	<	detHmat = 0.0;
211	<	for(i=0; i<3; i++) detHmat += Hmat[i] * C[i][0];
171	>	oldOrtho = orthoRhombic;
172
173	<
174	<	// H^-1 = C^T / det(H)
175	<
176	<	i=0;
217	<	for(j=0; j<3; j++){
218	<	for(k=0; k<3; k++){
173	>	smallDiag = fabs(Hmat[0][0]);
174	>	if(smallDiag > fabs(Hmat[1][1])) smallDiag = fabs(Hmat[1][1]);
175	>	if(smallDiag > fabs(Hmat[2][2])) smallDiag = fabs(Hmat[2][2]);
176	>	tol = smallDiag * orthoTolerance;
177
178	<	HmatI[i] = C[j][k] / detHmat;
179	<	i++;
180	<	}
181	<	}
182	<
183	<	// sanity check
184	<
185	<	for(i=0; i<3; i++){
228	<	for(j=0; j<3; j++){
229	<
230	<	sanity[i][j] = 0.0;
231	<	for(k=0; k<3; k++){
232	<	sanity[i][j] += Hmat[3k+i] HmatI[3*j+k];
178	>	orthoRhombic = 1;
179	>
180	>	for (i = 0; i < 3; i++ ) {
181	>	for (j = 0 ; j < 3; j++) {
182	>	if (i != j) {
183	>	if (orthoRhombic) {
184	>	if ( fabs(Hmat[i][j]) >= tol) orthoRhombic = 0;
185	>	}
186		}
187		}
188		}
189
190	<	cerr << "sanity => \n"
238	<	<< sanity[0][0] << "\t" << sanity[0][1] << "\t" << sanity [0][2] << "\n"
239	<	<< sanity[1][0] << "\t" << sanity[1][1] << "\t" << sanity [1][2] << "\n"
240	<	<< sanity[2][0] << "\t" << sanity[2][1] << "\t" << sanity [2][2]
241	<	<< "\n";
190	>	if( oldOrtho != orthoRhombic ){
191
192	<
193	<	// check to see if Hmat is orthorhombic
194	<
195	<	smallDiag = Hmat[0];
196	<	if(smallDiag > Hmat[4]) smallDiag = Hmat[4];
197	<	if(smallDiag > Hmat[8]) smallDiag = Hmat[8];
198	<	tol = smallDiag * 1E-6;
199	<
200	<	orthoRhombic = 1;
252	<	for(i=0; (i<9) && orthoRhombic; i++){
253	<
254	<	if( (i%4) ){ // ignore the diagonals (0, 4, and 8)
255	<	orthoRhombic = (Hmat[i] <= tol);
192	>	if( orthoRhombic ){
193	>	sprintf( painCave.errMsg,
194	>	"OOPSE is switching from the default Non-Orthorhombic\n"
195	>	"\tto the faster Orthorhombic periodic boundary computations.\n"
196	>	"\tThis is usually a good thing, but if you wan't the\n"
197	>	"\tNon-Orthorhombic computations, make the orthoBoxTolerance\n"
198	>	"\tvariable ( currently set to %G ) smaller.\n",
199	>	orthoTolerance);
200	>	simError();
201		}
202	+	else {
203	+	sprintf( painCave.errMsg,
204	+	"OOPSE is switching from the faster Orthorhombic to the more\n"
205	+	"\tflexible Non-Orthorhombic periodic boundary computations.\n"
206	+	"\tThis is usually because the box has deformed under\n"
207	+	"\tNPTf integration. If you wan't to live on the edge with\n"
208	+	"\tthe Orthorhombic computations, make the orthoBoxTolerance\n"
209	+	"\tvariable ( currently set to %G ) larger.\n",
210	+	orthoTolerance);
211	+	simError();
212	+	}
213		}
258	–
214		}
215
216		void SimInfo::calcBoxL( void ){
217
218		double dx, dy, dz, dsq;
264	–	int i;
219
220	<	// boxVol = h1 (dot) h2 (cross) h3
220	>	// boxVol = Determinant of Hmat
221
222	<	boxVol = Hmat[0] * ( (Hmat[4]Hmat[8]) - (Hmat[7]Hmat[5]) )
269	<	+ Hmat[1] * ( (Hmat[5]Hmat[6]) - (Hmat[8]Hmat[3]) )
270	<	+ Hmat[2] * ( (Hmat[3]Hmat[7]) - (Hmat[6]Hmat[4]) );
222	>	boxVol = matDet3( Hmat );
223
272	–
224		// boxLx
225
226	<	dx = Hmat[0]; dy = Hmat[1]; dz = Hmat[2];
226	>	dx = Hmat[0][0]; dy = Hmat[1][0]; dz = Hmat[2][0];
227		dsq = dxdx + dydy + dz*dz;
228	<	boxLx = sqrt( dsq );
228	>	boxL[0] = sqrt( dsq );
229	>	//maxCutoff = 0.5 * boxL[0];
230
231		// boxLy
232
233	<	dx = Hmat[3]; dy = Hmat[4]; dz = Hmat[5];
233	>	dx = Hmat[0][1]; dy = Hmat[1][1]; dz = Hmat[2][1];
234		dsq = dxdx + dydy + dz*dz;
235	<	boxLy = sqrt( dsq );
235	>	boxL[1] = sqrt( dsq );
236	>	//if( (0.5 * boxL[1]) < maxCutoff ) maxCutoff = 0.5 * boxL[1];
237
238	+
239		// boxLz
240
241	<	dx = Hmat[6]; dy = Hmat[7]; dz = Hmat[8];
241	>	dx = Hmat[0][2]; dy = Hmat[1][2]; dz = Hmat[2][2];
242		dsq = dxdx + dydy + dz*dz;
243	<	boxLz = sqrt( dsq );
243	>	boxL[2] = sqrt( dsq );
244	>	//if( (0.5 * boxL[2]) < maxCutoff ) maxCutoff = 0.5 * boxL[2];
245	>
246	>	//calculate the max cutoff
247	>	maxCutoff = calcMaxCutOff();
248
249	+	checkCutOffs();
250	+
251		}
252
253
254	+	double SimInfo::calcMaxCutOff(){
255	+
256	+	double ri[3], rj[3], rk[3];
257	+	double rij[3], rjk[3], rki[3];
258	+	double minDist;
259	+
260	+	ri[0] = Hmat[0][0];
261	+	ri[1] = Hmat[1][0];
262	+	ri[2] = Hmat[2][0];
263	+
264	+	rj[0] = Hmat[0][1];
265	+	rj[1] = Hmat[1][1];
266	+	rj[2] = Hmat[2][1];
267	+
268	+	rk[0] = Hmat[0][2];
269	+	rk[1] = Hmat[1][2];
270	+	rk[2] = Hmat[2][2];
271	+
272	+	crossProduct3(ri, rj, rij);
273	+	distXY = dotProduct3(rk,rij) / norm3(rij);
274	+
275	+	crossProduct3(rj,rk, rjk);
276	+	distYZ = dotProduct3(ri,rjk) / norm3(rjk);
277	+
278	+	crossProduct3(rk,ri, rki);
279	+	distZX = dotProduct3(rj,rki) / norm3(rki);
280	+
281	+	minDist = min(min(distXY, distYZ), distZX);
282	+	return minDist/2;
283	+
284	+	}
285	+
286		void SimInfo::wrapVector( double thePos[3] ){
287
288	<	int i, j, k;
288	>	int i;
289		double scaled[3];
290
291		if( !orthoRhombic ){
292		// calc the scaled coordinates.
293	+
294	+
295	+	matVecMul3(HmatInv, thePos, scaled);
296
297		for(i=0; i<3; i++)
303	–	scaled[i] =
304	–	thePos[0]HmatI[i] + thePos[1]HmatI[i+3] + thePos[3]*HmatI[i+6];
305	–
306	–	// wrap the scaled coordinates
307	–
308	–	for(i=0; i<3; i++)
298		scaled[i] -= roundMe(scaled[i]);
299
300		// calc the wrapped real coordinates from the wrapped scaled coordinates
301
302	<	for(i=0; i<3; i++)
303	<	thePos[i] =
315	<	scaled[0]Hmat[i] + scaled[1]Hmat[i+3] + scaled[2]*Hmat[i+6];
302	>	matVecMul3(Hmat, scaled, thePos);
303	>
304		}
305		else{
306		// calc the scaled coordinates.
307
308		for(i=0; i<3; i++)
309	<	scaled[i] = thePos[i]HmatI[i4];
309	>	scaled[i] = thePos[i]*HmatInv[i][i];
310
311		// wrap the scaled coordinates
312
#	Line 328 \| Line 316 \| void SimInfo::wrapVector( double thePos[3] ){
316		// calc the wrapped real coordinates from the wrapped scaled coordinates
317
318		for(i=0; i<3; i++)
319	<	thePos[i] = scaled[i]Hmat[i4];
319	>	thePos[i] = scaled[i]*Hmat[i][i];
320		}
321
334	–
322		}
323
324
325		int SimInfo::getNDF(){
326	<	int ndf_local, ndf;
326	>	int ndf_local;
327	>
328	>	ndf_local = 0;
329
330	<	ndf_local = 3 * n_atoms + 3 * n_oriented - n_constraints;
330	>	for(int i = 0; i < integrableObjects.size(); i++){
331	>	ndf_local += 3;
332	>	if (integrableObjects[i]->isDirectional()) {
333	>	if (integrableObjects[i]->isLinear())
334	>	ndf_local += 2;
335	>	else
336	>	ndf_local += 3;
337	>	}
338	>	}
339
340	+	// n_constraints is local, so subtract them on each processor:
341	+
342	+	ndf_local -= n_constraints;
343	+
344		#ifdef IS_MPI
345		MPI_Allreduce(&ndf_local,&ndf,1,MPI_INT,MPI_SUM, MPI_COMM_WORLD);
346		#else
347		ndf = ndf_local;
348		#endif
349
350	<	ndf = ndf - 3;
350	>	// nZconstraints is global, as are the 3 COM translations for the
351	>	// entire system:
352
353	+	ndf = ndf - 3 - nZconstraints;
354	+
355		return ndf;
356		}
357
358		int SimInfo::getNDFraw() {
359	<	int ndfRaw_local, ndfRaw;
359	>	int ndfRaw_local;
360
361		// Raw degrees of freedom that we have to set
362	<	ndfRaw_local = 3 * n_atoms + 3 * n_oriented;
363	<
362	>	ndfRaw_local = 0;
363	>
364	>	for(int i = 0; i < integrableObjects.size(); i++){
365	>	ndfRaw_local += 3;
366	>	if (integrableObjects[i]->isDirectional()) {
367	>	if (integrableObjects[i]->isLinear())
368	>	ndfRaw_local += 2;
369	>	else
370	>	ndfRaw_local += 3;
371	>	}
372	>	}
373	>
374		#ifdef IS_MPI
375		MPI_Allreduce(&ndfRaw_local,&ndfRaw,1,MPI_INT,MPI_SUM, MPI_COMM_WORLD);
376		#else
#	Line 365 \| Line 379 \| int SimInfo::getNDFraw() {
379
380		return ndfRaw;
381		}
382	<
382	>
383	>	int SimInfo::getNDFtranslational() {
384	>	int ndfTrans_local;
385	>
386	>	ndfTrans_local = 3 * integrableObjects.size() - n_constraints;
387	>
388	>
389	>	#ifdef IS_MPI
390	>	MPI_Allreduce(&ndfTrans_local,&ndfTrans,1,MPI_INT,MPI_SUM, MPI_COMM_WORLD);
391	>	#else
392	>	ndfTrans = ndfTrans_local;
393	>	#endif
394	>
395	>	ndfTrans = ndfTrans - 3 - nZconstraints;
396	>
397	>	return ndfTrans;
398	>	}
399	>
400	>	int SimInfo::getTotIntegrableObjects() {
401	>	int nObjs_local;
402	>	int nObjs;
403	>
404	>	nObjs_local = integrableObjects.size();
405	>
406	>
407	>	#ifdef IS_MPI
408	>	MPI_Allreduce(&nObjs_local,&nObjs,1,MPI_INT,MPI_SUM, MPI_COMM_WORLD);
409	>	#else
410	>	nObjs = nObjs_local;
411	>	#endif
412	>
413	>
414	>	return nObjs;
415	>	}
416	>
417		void SimInfo::refreshSim(){
418
419		simtype fInfo;
420		int isError;
421		int n_global;
422		int* excl;
423	<
376	<	fInfo.rrf = 0.0;
377	<	fInfo.rt = 0.0;
423	>
424		fInfo.dielect = 0.0;
425
426	<	fInfo.rlist = rList;
381	<	fInfo.rcut = rCut;
382	<
383	<	if( useDipole ){
384	<	fInfo.rrf = ecr;
385	<	fInfo.rt = ecr - est;
426	>	if( useDipoles ){
427		if( useReactionField )fInfo.dielect = dielectric;
428		}
429
#	Line 391 \| Line 432 \| void SimInfo::refreshSim(){
432		fInfo.SIM_uses_LJ = useLJ;
433		fInfo.SIM_uses_sticky = useSticky;
434		//fInfo.SIM_uses_sticky = 0;
435	<	fInfo.SIM_uses_dipoles = useDipole;
435	>	fInfo.SIM_uses_charges = useCharges;
436	>	fInfo.SIM_uses_dipoles = useDipoles;
437		//fInfo.SIM_uses_dipoles = 0;
438	<	//fInfo.SIM_uses_RF = useReactionField;
439	<	fInfo.SIM_uses_RF = 0;
438	>	fInfo.SIM_uses_RF = useReactionField;
439	>	//fInfo.SIM_uses_RF = 0;
440		fInfo.SIM_uses_GB = useGB;
441		fInfo.SIM_uses_EAM = useEAM;
442
443	<	excl = Exclude::getArray();
444	<
443	>	n_exclude = excludes->getSize();
444	>	excl = excludes->getFortranArray();
445	>
446		#ifdef IS_MPI
447		n_global = mpiSim->getTotAtoms();
448		#else
#	Line 408 \| Line 451 \| void SimInfo::refreshSim(){
451
452		isError = 0;
453
454	+	getFortranGroupArray(this, mfact, ngroup, groupList, groupStart);
455	+
456		setFsimulation( &fInfo, &n_global, &n_atoms, identArray, &n_exclude, excl,
457	<	&nGlobalExcludes, globalExcludes, molMembershipArray,
458	<	&isError );
457	>	&nGlobalExcludes, globalExcludes, molMembershipArray,
458	>	&mfact[0], &ngroup, &groupList[0], &groupStart[0], &isError );
459
460		if( isError ){
461
#	Line 428 \| Line 473 \| void SimInfo::refreshSim(){
473
474		this->ndf = this->getNDF();
475		this->ndfRaw = this->getNDFraw();
476	+	this->ndfTrans = this->getNDFtranslational();
477	+	}
478
479	+	void SimInfo::setDefaultRcut( double theRcut ){
480	+
481	+	haveRcut = 1;
482	+	rCut = theRcut;
483	+
484	+	( rCut > ecr )? rList = rCut + 1.0: rList = ecr + 1.0;
485	+
486	+	notifyFortranCutOffs( &rCut, &rList, &ecr, &est );
487		}
488
489	+	void SimInfo::setDefaultEcr( double theEcr ){
490	+
491	+	haveEcr = 1;
492	+	ecr = theEcr;
493	+
494	+	( rCut > ecr )? rList = rCut + 1.0: rList = ecr + 1.0;
495	+
496	+	notifyFortranCutOffs( &rCut, &rList, &ecr, &est );
497	+	}
498	+
499	+	void SimInfo::setDefaultEcr( double theEcr, double theEst ){
500	+
501	+	est = theEst;
502	+	setDefaultEcr( theEcr );
503	+	}
504	+
505	+
506	+	void SimInfo::checkCutOffs( void ){
507	+
508	+	if( boxIsInit ){
509	+
510	+	//we need to check cutOffs against the box
511	+
512	+	if( rCut > maxCutoff ){
513	+	sprintf( painCave.errMsg,
514	+	"LJrcut is too large for the current periodic box.\n"
515	+	"\tCurrent Value of LJrcut = %G at time %G\n "
516	+	"\tThis is larger than half of at least one of the\n"
517	+	"\tperiodic box vectors. Right now, the Box matrix is:\n"
518	+	"\n"
519	+	"\t[ %G %G %G ]\n"
520	+	"\t[ %G %G %G ]\n"
521	+	"\t[ %G %G %G ]\n",
522	+	rCut, currentTime,
523	+	Hmat[0][0], Hmat[0][1], Hmat[0][2],
524	+	Hmat[1][0], Hmat[1][1], Hmat[1][2],
525	+	Hmat[2][0], Hmat[2][1], Hmat[2][2]);
526	+	painCave.isFatal = 1;
527	+	simError();
528	+	}
529	+
530	+	if( haveEcr ){
531	+	if( ecr > maxCutoff ){
532	+	sprintf( painCave.errMsg,
533	+	"electrostaticCutoffRadius is too large for the current\n"
534	+	"\tperiodic box.\n\n"
535	+	"\tCurrent Value of ECR = %G at time %G\n "
536	+	"\tThis is larger than half of at least one of the\n"
537	+	"\tperiodic box vectors. Right now, the Box matrix is:\n"
538	+	"\n"
539	+	"\t[ %G %G %G ]\n"
540	+	"\t[ %G %G %G ]\n"
541	+	"\t[ %G %G %G ]\n",
542	+	ecr, currentTime,
543	+	Hmat[0][0], Hmat[0][1], Hmat[0][2],
544	+	Hmat[1][0], Hmat[1][1], Hmat[1][2],
545	+	Hmat[2][0], Hmat[2][1], Hmat[2][2]);
546	+	painCave.isFatal = 1;
547	+	simError();
548	+	}
549	+	}
550	+	} else {
551	+	// initialize this stuff before using it, OK?
552	+	sprintf( painCave.errMsg,
553	+	"Trying to check cutoffs without a box.\n"
554	+	"\tOOPSE should have better programmers than that.\n" );
555	+	painCave.isFatal = 1;
556	+	simError();
557	+	}
558	+
559	+	}
560	+
561	+	void SimInfo::addProperty(GenericData* prop){
562	+
563	+	map<string, GenericData*>::iterator result;
564	+	result = properties.find(prop->getID());
565	+
566	+	//we can't simply use properties[prop->getID()] = prop,
567	+	//it will cause memory leak if we already contain a propery which has the same name of prop
568	+
569	+	if(result != properties.end()){
570	+
571	+	delete (*result).second;
572	+	(*result).second = prop;
573	+
574	+	}
575	+	else{
576	+
577	+	properties[prop->getID()] = prop;
578	+
579	+	}
580	+
581	+	}
582	+
583	+	GenericData* SimInfo::getProperty(const string& propName){
584	+
585	+	map<string, GenericData*>::iterator result;
586	+
587	+	//string lowerCaseName = ();
588	+
589	+	result = properties.find(propName);
590	+
591	+	if(result != properties.end())
592	+	return (*result).second;
593	+	else
594	+	return NULL;
595	+	}
596	+
597	+
598	+	void getFortranGroupArray(SimInfo* info, vector<double>& mfact, int& ngroup,
599	+	vector<int>& groupList, vector<int>& groupStart){
600	+	Molecule* mol;
601	+	int numAtom;
602	+	int curIndex;
603	+
604	+	mfact.clear();
605	+	groupList.clear();
606	+	groupStart.clear();
607	+
608	+	//Be careful, fortran array begin at 1
609	+	curIndex = 1;
610	+
611	+	if(info->useMolecularCutoffs){
612	+	//if using molecular cutoff
613	+	ngroup = info->n_mol;
614	+
615	+	for(int i = 0; i < ngroup; i ++){
616	+	mol = &(info->molecules[i]);
617	+	numAtom = mol->getNAtoms();
618	+
619	+	for(int j=0; j < numAtom; j++){
620	+	#ifdef IS_MPI
621	+	groupList.push_back((info->atoms[i])->getGlobalIndex() + 1);
622	+	#else
623	+	groupList.push_back((info->atoms[i])->getIndex() + 1);
624	+	#endif
625	+	}//for(int j=0; j < numAtom; j++)
626	+
627	+	groupStart.push_back(curIndex);
628	+	curIndex += numAtom;
629	+
630	+	}//end for(int i =0 ; i < ngroup; i++)
631	+	}
632	+	else{
633	+	//using atomic cutoff, every single atom is just a group
634	+	ngroup = info->n_atoms;
635	+	for(int i =0 ; i < ngroup; i++){
636	+	groupStart.push_back(curIndex++);
637	+
638	+	#ifdef IS_MPI
639	+	groupList.push_back((info->atoms[i])->getGlobalIndex() + 1);
640	+	#else
641	+	groupList.push_back((info->atoms[i])->getIndex() + 1);
642	+	#endif
643	+
644	+	}//end for(int i =0 ; i < ngroup; i++)
645	+
646	+	}//end if (info->useMolecularCutoffs)
647	+
648	+	}

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Comparing trunk/OOPSE/libmdtools/SimInfo.cpp (file contents): Revision 574 by gezelter, Tue Jul 8 20:56:10 2003 UTC vs. Revision 1144 by tim, Sat May 1 18:52:38 2004 UTC

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Comparing trunk/OOPSE/libmdtools/SimInfo.cpp (file contents):
Revision 574 by gezelter, Tue Jul 8 20:56:10 2003 UTC vs.
Revision 1144 by tim, Sat May 1 18:52:38 2004 UTC