ViewVC Help

View File | Revision Log | Show Annotations | View Changeset | Root Listing

root/OpenMD/trunk/src/UseTheForce/DUFF.cpp

Comparing trunk/src/UseTheForce/DUFF.cpp (file contents):
Revision 177 by gezelter, Thu Oct 28 16:56:20 2004 UTC vs.
Revision 409 by gezelter, Wed Mar 9 14:25:51 2005 UTC

#	Line 1 | Line 1
1	<	#include <stdlib.h>
2	<	#include <stdio.h>
3	<	#include <string.h>
1	>	/*
2	>	* Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
3	>	*
4	>	* The University of Notre Dame grants you ("Licensee") a
5	>	* non-exclusive, royalty free, license to use, modify and
6	>	* redistribute this software in source and binary code form, provided
7	>	* that the following conditions are met:
8	>	*
9	>	* 1. Acknowledgement of the program authors must be made in any
10	>	*    publication of scientific results based in part on use of the
11	>	*    program.  An acceptable form of acknowledgement is citation of
12	>	*    the article in which the program was described (Matthew
13	>	*    A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
14	>	*    J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
15	>	*    Parallel Simulation Engine for Molecular Dynamics,"
16	>	*    J. Comput. Chem. 26, pp. 252-271 (2005))
17	>	*
18	>	* 2. Redistributions of source code must retain the above copyright
19	>	*    notice, this list of conditions and the following disclaimer.
20	>	*
21	>	* 3. Redistributions in binary form must reproduce the above copyright
22	>	*    notice, this list of conditions and the following disclaimer in the
23	>	*    documentation and/or other materials provided with the
24	>	*    distribution.
25	>	*
26	>	* This software is provided "AS IS," without a warranty of any
27	>	* kind. All express or implied conditions, representations and
28	>	* warranties, including any implied warranty of merchantability,
29	>	* fitness for a particular purpose or non-infringement, are hereby
30	>	* excluded.  The University of Notre Dame and its licensors shall not
31	>	* be liable for any damages suffered by licensee as a result of
32	>	* using, modifying or distributing the software or its
33	>	* derivatives. In no event will the University of Notre Dame or its
34	>	* licensors be liable for any lost revenue, profit or data, or for
35	>	* direct, indirect, special, consequential, incidental or punitive
36	>	* damages, however caused and regardless of the theory of liability,
37	>	* arising out of the use of or inability to use software, even if the
38	>	* University of Notre Dame has been advised of the possibility of
39	>	* such damages.
40	>	*/
41
5	–	#include <iostream>
6	–	using namespace std;
42
43	<	#include "UseTheForce/ForceFields.hpp"
9	<	#include "primitives/SRI.hpp"
10	<	#include "utils/simError.h"
11	<	#include "types/DirectionalAtomType.hpp"
43	>	#include "UseTheForce/DUFF.hpp"
44		#include "UseTheForce/DarkSide/lj_interface.h"
13	–	#include "UseTheForce/DarkSide/dipole_interface.h"
45		#include "UseTheForce/DarkSide/sticky_interface.h"
46	+	#include "UseTheForce/ForceFieldFactory.hpp"
47	+	#include "io/DirectionalAtomTypesSectionParser.hpp"
48	+	#include "io/AtomTypesSectionParser.hpp"
49	+	#include "io/LennardJonesAtomTypesSectionParser.hpp"
50	+	#include "io/ElectrostaticAtomTypesSectionParser.hpp"
51	+	#include "io/StickyAtomTypesSectionParser.hpp"
52	+	#include "io/BondTypesSectionParser.hpp"
53	+	#include "io/BendTypesSectionParser.hpp"
54	+	#include "io/TorsionTypesSectionParser.hpp"
55	+	#include "UseTheForce/ForceFieldCreator.hpp"
56
57	<	#ifdef IS_MPI
17	<	#include "UseTheForce/mpiForceField.h"
18	<	#endif // is_mpi
19	<
20	<
21	<	// define some bond Types
22	<
23	<	#define FIXED_BOND    0
24	<	#define HARMONIC_BOND 1
25	<
26	<
27	<	namespace DUFF_NS {  // restrict the access of the folowing to this file only.
28	<
29	<
30	<	// Declare the structures that will be passed by MPI
31	<
32	<	typedef struct{
33	<	char name[15];
34	<	double mass;
35	<	double epslon;
36	<	double sigma;
37	<	double charge;
38	<	double dipole;
39	<	double w0;
40	<	double v0;
41	<	double v0p;
42	<	double rl;
43	<	double ru;
44	<	double rlp;
45	<	double rup;
46	<	int isSSD;
47	<	int isCharge;
48	<	int isDipole;
49	<	int ident;
50	<	int last;      //  0  -> default
51	<	//  1  -> tells nodes to stop listening
52	<	} atomStruct;
53	<
54	<
55	<	typedef struct{
56	<	char nameA[15];
57	<	char nameB[15];
58	<	double d0;
59	<	double k0;
60	<	int last;      //  0  -> default
61	<	//  1  -> tells nodes to stop listening
62	<	int type;
63	<	} bondStruct;
64	<
65	<
66	<	typedef struct{
67	<	char nameA[15];
68	<	char nameB[15];
69	<	char nameC[15];
70	<	char type[30];
71	<	double k1, k2, k3, t0;
72	<	int last;      //  0  -> default
73	<	//  1  -> tells nodes to stop listening
74	<	} bendStruct;
75	<
76	<
77	<	typedef struct{
78	<	char nameA[15];
79	<	char nameB[15];
80	<	char nameC[15];
81	<	char nameD[15];
82	<	char type[30];
83	<	double k1, k2, k3, k4;
84	<	int last;      //  0  -> default
85	<	//  1  -> tells nodes to stop listening
86	<	} torsionStruct;
87	<
88	<
89	<	int parseAtom(    char *lineBuffer, int lineNum, atomStruct     &info );
90	<	int parseBond(    char *lineBuffer, int lineNum, bondStruct     &info );
91	<	int parseBend(    char *lineBuffer, int lineNum, bendStruct     &info );
92	<	int parseTorsion( char *lineBuffer, int lineNum, torsionStruct  &info );
93	<
94	<
95	<	#ifdef IS_MPI
96	<
97	<	MPI_Datatype mpiAtomStructType;
98	<	MPI_Datatype mpiBondStructType;
99	<	MPI_Datatype mpiBendStructType;
100	<	MPI_Datatype mpiTorsionStructType;
101	<
102	<	#endif
103	<
104	<	class LinkedAtomType {
105	<	public:
106	<	LinkedAtomType(){
107	<	next = NULL;
108	<	name[0] = '\0';
109	<	}
110	<	~LinkedAtomType(){ if( next != NULL ) delete next; }
111	<
112	<	LinkedAtomType* find(char* key){
113	<	if( !strcmp(name, key) ) return this;
114	<	if( next != NULL ) return next->find(key);
115	<	return NULL;
116	<	}
57	>	namespace oopse {
58
59	<	void printMe( void ){
119	<
120	<	std::cerr << "LinkedAtype " << name << ": ident = " << ident << "\n";
121	<	//      if( next != NULL ) next->printMe();
59	>	DUFF::DUFF(){
60
61	<	}
61	>	//set default force field filename
62	>	setForceFieldFileName("DUFF2.frc");
63
64	<	void add( atomStruct &info ){
65	<
66	<	// check for duplicates
67	<
68	<	if( !strcmp( info.name, name ) ){
69	<	sprintf( painCave.errMsg,
70	<	"Duplicate DUFF atom type \"%s\" found in "
71	<	"the DUFF param file./n",
72	<	name );
73	<	painCave.isFatal = 1;
74	<	simError();
75	<	}
76	<
77	<	if( next != NULL ) next->add(info);
78	<	else{
79	<	next = new LinkedAtomType();
80	<	strcpy(next->name, info.name);
81	<	next->isDipole = info.isDipole;
143	<	next->isSSD    = info.isSSD;
144	<	next->mass     = info.mass;
145	<	next->epslon   = info.epslon;
146	<	next->sigma    = info.sigma;
147	<	next->dipole   = info.dipole;
148	<	next->w0       = info.w0;
149	<	next->v0       = info.v0;
150	<	next->v0p      = info.v0p;
151	<	next->rl       = info.rl;
152	<	next->ru       = info.ru;
153	<	next->rlp      = info.rlp;
154	<	next->rup      = info.rup;
155	<	next->ident    = info.ident;
156	<	}
157	<	}
158	<
159	<	#ifdef IS_MPI
64	>	//the order of adding section parsers are important
65	>	//DirectionalAtomTypesSectionParser should be added before AtomTypesSectionParser Since
66	>	//These two section parsers will actually create "real" AtomTypes (AtomTypesSectionParser will create
67	>	//AtomType and DirectionalAtomTypesSectionParser will creat DirectionalAtomType which is a subclass
68	>	//of AtomType, therefore it should come first). Other AtomTypes Section Parser will not create the
69	>	//"real" AtomType, they only add and set some attribute of the AtomType. Thus their order are not
70	>	//important. AtomTypesSectionParser should be added before other atom type section parsers.
71	>	//Make sure they are added after DirectionalAtomTypesSectionParser and AtomTypesSectionParser.
72	>	//The order of BondTypesSectionParser, BendTypesSectionParser and TorsionTypesSectionParser are
73	>	//not important.
74	>	spMan_.push_back(new DirectionalAtomTypesSectionParser());
75	>	spMan_.push_back(new AtomTypesSectionParser());
76	>	spMan_.push_back(new LennardJonesAtomTypesSectionParser());
77	>	spMan_.push_back(new ElectrostaticAtomTypesSectionParser());
78	>	spMan_.push_back(new StickyAtomTypesSectionParser());
79	>	spMan_.push_back(new BondTypesSectionParser());
80	>	spMan_.push_back(new BendTypesSectionParser());
81	>	spMan_.push_back(new TorsionTypesSectionParser());
82
83	<	void duplicate( atomStruct &info ){
162	<	strcpy(info.name, name);
163	<	info.isDipole = isDipole;
164	<	info.isSSD    = isSSD;
165	<	info.mass     = mass;
166	<	info.epslon   = epslon;
167	<	info.sigma    = sigma;
168	<	info.dipole   = dipole;
169	<	info.w0       = w0;
170	<	info.v0       = v0;
171	<	info.v0p      = v0p;
172	<	info.rl       = rl;
173	<	info.ru       = ru;
174	<	info.rlp      = rlp;
175	<	info.rup      = rup;
176	<	info.ident    = ident;
177	<	info.last     = 0;
178	<	}
83	>	}
84
85	+	void DUFF::parse(const std::string& filename) {
86	+	ifstrstream* ffStream;
87	+	ffStream = openForceFieldFile(filename);
88
89	<	#endif
89	>	spMan_.parse(*ffStream, *this);
90
91	<	char name[15];
92	<	int isDipole;
185	<	int isSSD;
186	<	double mass;
187	<	double epslon;
188	<	double sigma;
189	<	double dipole;
190	<	double w0;
191	<	double v0;
192	<	double v0p;
193	<	double rl;
194	<	double ru;
195	<	double rlp;
196	<	double rup;
197	<	int ident;
198	<	LinkedAtomType* next;
199	<	};
91	>	ForceField::AtomTypeContainer::MapTypeIterator i;
92	>	AtomType* at;
93
94	<	class LinkedBondType {
95	<	public:
203	<	LinkedBondType(){
204	<	next = NULL;
205	<	nameA[0] = '\0';
206	<	nameB[0] = '\0';
94	>	for (at = atomTypeCont_.beginType(i); at != NULL; at = atomTypeCont_.nextType(i)) {
95	>	at->makeFortranAtomType();
96		}
208	–	~LinkedBondType(){ if( next != NULL ) delete next; }
97
98	<	LinkedBondType* find(char* key1, char* key2){
99	<	if( !strcmp(nameA, key1 ) && !strcmp( nameB, key2 ) ) return this;
212	<	if( !strcmp(nameA, key2 ) && !strcmp( nameB, key1 ) ) return this;
213	<	if( next != NULL ) return next->find(key1, key2);
214	<	return NULL;
215	<	}
216	<
217	<
218	<	void add( bondStruct &info ){
219	<
220	<	// check for duplicates
221	<	int dup = 0;
222	<
223	<	if( !strcmp(nameA, info.nameA ) && !strcmp( nameB, info.nameB ) ) dup = 1;
224	<	if( !strcmp(nameA, info.nameB ) && !strcmp( nameB, info.nameA ) ) dup = 1;
225	<
226	<	if(dup){
227	<	sprintf( painCave.errMsg,
228	<	"Duplicate DUFF bond type \"%s - %s\" found in "
229	<	"the DUFF param file./n",
230	<	nameA, nameB );
231	<	painCave.isFatal = 1;
232	<	simError();
233	<	}
234	<
235	<
236	<	if( next != NULL ) next->add(info);
237	<	else{
238	<	next = new LinkedBondType();
239	<	strcpy(next->nameA, info.nameA);
240	<	strcpy(next->nameB, info.nameB);
241	<	next->type = info.type;
242	<	next->d0 = info.d0;
243	<	next->k0 = info.k0;
244	<	}
245	<	}
246	<
247	<	#ifdef IS_MPI
248	<	void duplicate( bondStruct &info ){
249	<	strcpy(info.nameA, nameA);
250	<	strcpy(info.nameB, nameB);
251	<	info.type = type;
252	<	info.d0   = d0;
253	<	info.k0   = k0;
254	<	info.last = 0;
255	<	}
256	<
257	<
258	<	#endif
259	<
260	<	char nameA[15];
261	<	char nameB[15];
262	<	int type;
263	<	double d0;
264	<	double k0;
265	<
266	<	LinkedBondType* next;
267	<	};
268	<
269	<	class LinkedBendType {
270	<	public:
271	<	LinkedBendType(){
272	<	next = NULL;
273	<	nameA[0] = '\0';
274	<	nameB[0] = '\0';
275	<	nameC[0] = '\0';
276	<	type[0] = '\0';
277	<	}
278	<	~LinkedBendType(){ if( next != NULL ) delete next; }
279	<
280	<	LinkedBendType* find( char* key1, char* key2, char* key3 ){
281	<	if( !strcmp( nameA, key1 ) && !strcmp( nameB, key2 )
282	<	&& !strcmp( nameC, key3 ) ) return this;
283	<	if( !strcmp( nameA, key3 ) && !strcmp( nameB, key2 )
284	<	&& !strcmp( nameC, key1 ) ) return this;
285	<	if( next != NULL ) return next->find(key1, key2, key3);
286	<	return NULL;
287	<	}
288	<
289	<	void add( bendStruct &info ){
290	<
291	<	// check for duplicates
292	<	int dup = 0;
293	<
294	<	if( !strcmp( nameA, info.nameA ) && !strcmp( nameB, info.nameB )
295	<	&& !strcmp( nameC, info.nameC ) ) dup = 1;
296	<	if( !strcmp( nameA, info.nameC ) && !strcmp( nameB, info.nameB )
297	<	&& !strcmp( nameC, info.nameA ) ) dup = 1;
298	<
299	<	if(dup){
300	<	sprintf( painCave.errMsg,
301	<	"Duplicate DUFF bend type \"%s - %s - %s\" found in "
302	<	"the DUFF param file./n",
303	<	nameA, nameB, nameC );
304	<	painCave.isFatal = 1;
305	<	simError();
306	<	}
307	<
308	<	if( next != NULL ) next->add(info);
309	<	else{
310	<	next = new LinkedBendType();
311	<	strcpy(next->nameA, info.nameA);
312	<	strcpy(next->nameB, info.nameB);
313	<	strcpy(next->nameC, info.nameC);
314	<	strcpy(next->type,  info.type);
315	<	next->k1 = info.k1;
316	<	next->k2 = info.k2;
317	<	next->k3 = info.k3;
318	<	next->t0 = info.t0;
319	<	}
320	<	}
321	<
322	<	#ifdef IS_MPI
323	<
324	<	void duplicate( bendStruct &info ){
325	<	strcpy(info.nameA, nameA);
326	<	strcpy(info.nameB, nameB);
327	<	strcpy(info.nameC, nameC);
328	<	strcpy(info.type,  type);
329	<	info.k1   = k1;
330	<	info.k2   = k2;
331	<	info.k3   = k3;
332	<	info.t0   = t0;
333	<	info.last = 0;
334	<	}
335	<
336	<	#endif // is_mpi
337	<
338	<	char nameA[15];
339	<	char nameB[15];
340	<	char nameC[15];
341	<	char type[30];
342	<	double k1, k2, k3, t0;
343	<
344	<	LinkedBendType* next;
345	<	};
346	<
347	<	class LinkedTorsionType {
348	<	public:
349	<	LinkedTorsionType(){
350	<	next = NULL;
351	<	nameA[0] = '\0';
352	<	nameB[0] = '\0';
353	<	nameC[0] = '\0';
354	<	type[0] = '\0';
355	<	}
356	<	~LinkedTorsionType(){ if( next != NULL ) delete next; }
357	<
358	<	LinkedTorsionType* find( char* key1, char* key2, char* key3, char* key4 ){
359	<
360	<
361	<
362	<
363	<	if( !strcmp( nameA, key1 ) && !strcmp( nameB, key2 ) &&
364	<	!strcmp( nameC, key3 ) && !strcmp( nameD, key4 ) ) return this;
365	<
366	<	if( !strcmp( nameA, key4 ) && !strcmp( nameB, key3 ) &&
367	<	!strcmp( nameC, key2 ) && !strcmp( nameD, key1 ) ) return this;
368	<
369	<	if( next != NULL ) return next->find(key1, key2, key3, key4);
370	<	return NULL;
371	<	}
372	<
373	<	void add( torsionStruct &info ){
374	<
375	<	// check for duplicates
376	<	int dup = 0;
377	<
378	<	if( !strcmp( nameA, info.nameA ) && !strcmp( nameB, info.nameB ) &&
379	<	!strcmp( nameC, info.nameC ) && !strcmp( nameD, info.nameD ) ) dup = 1;
380	<
381	<	if( !strcmp( nameA, info.nameD ) && !strcmp( nameB, info.nameC ) &&
382	<	!strcmp( nameC, info.nameB ) && !strcmp( nameD, info.nameA ) ) dup = 1;
383	<
384	<	if(dup){
385	<	sprintf( painCave.errMsg,
386	<	"Duplicate DUFF torsion type \"%s - %s - %s - %s\" found in "
387	<	"the DUFF param file./n", nameA, nameB, nameC, nameD );
388	<	painCave.isFatal = 1;
389	<	simError();
390	<	}
391	<
392	<	if( next != NULL ) next->add(info);
393	<	else{
394	<	next = new LinkedTorsionType();
395	<	strcpy(next->nameA, info.nameA);
396	<	strcpy(next->nameB, info.nameB);
397	<	strcpy(next->nameC, info.nameC);
398	<	strcpy(next->nameD, info.nameD);
399	<	strcpy(next->type,  info.type);
400	<	next->k1 = info.k1;
401	<	next->k2 = info.k2;
402	<	next->k3 = info.k3;
403	<	next->k4 = info.k4;
404	<
405	<	}
406	<	}
407	<
408	<	#ifdef IS_MPI
409	<
410	<	void duplicate( torsionStruct &info ){
411	<	strcpy(info.nameA, nameA);
412	<	strcpy(info.nameB, nameB);
413	<	strcpy(info.nameC, nameC);
414	<	strcpy(info.nameD, nameD);
415	<	strcpy(info.type,  type);
416	<	info.k1   = k1;
417	<	info.k2   = k2;
418	<	info.k3   = k3;
419	<	info.k4   = k4;
420	<	info.last = 0;
98	>	for (at = atomTypeCont_.beginType(i); at != NULL; at = atomTypeCont_.nextType(i)) {
99	>	at->complete();
100		}
422	–
423	–	#endif
424	–
425	–	char nameA[15];
426	–	char nameB[15];
427	–	char nameC[15];
428	–	char nameD[15];
429	–	char type[30];
430	–	double k1, k2, k3, k4;
431	–
432	–	LinkedTorsionType* next;
433	–	};
434	–
435	–
436	–	LinkedAtomType* headAtomType;
437	–	LinkedAtomType* currentAtomType;
438	–	LinkedBondType* headBondType;
439	–	LinkedBondType* currentBondType;
440	–	LinkedBendType* headBendType;
441	–	LinkedBendType* currentBendType;
442	–	LinkedTorsionType* headTorsionType;
443	–	LinkedTorsionType* currentTorsionType;
444	–
445	–	} // namespace
446	–
447	–	using namespace DUFF_NS;
448	–
449	–
450	–	//****************************************************************
451	–	// begins the actual forcefield stuff.
452	–	//****************************************************************
453	–
454	–
455	–	DUFF::DUFF(){
456	–
457	–	string fileName;
458	–	string tempString;
459	–
460	–	headAtomType       = NULL;
461	–	currentAtomType    = NULL;
462	–	headBondType       = NULL;
463	–	currentBondType    = NULL;
464	–	headBendType       = NULL;
465	–	currentBendType    = NULL;
466	–	headTorsionType    = NULL;
467	–	currentTorsionType = NULL;
468	–
469	–
470	–	#ifdef IS_MPI
471	–	int i;
472	–
473	–	// **********************************************************************
474	–	// Init the atomStruct mpi type
475	–
476	–	atomStruct atomProto; // mpiPrototype
477	–	int atomBC[3] = {15,12,5};  // block counts
478	–	MPI_Aint atomDspls[3];           // displacements
479	–	MPI_Datatype atomMbrTypes[3];    // member mpi types
480	–
481	–	MPI_Address(&atomProto.name, &atomDspls[0]);
482	–	MPI_Address(&atomProto.mass, &atomDspls[1]);
483	–	MPI_Address(&atomProto.isSSD, &atomDspls[2]);
484	–
485	–	atomMbrTypes[0] = MPI_CHAR;
486	–	atomMbrTypes[1] = MPI_DOUBLE;
487	–	atomMbrTypes[2] = MPI_INT;
488	–
489	–	for (i=2; i >= 0; i--) atomDspls[i] -= atomDspls[0];
490	–
491	–	MPI_Type_struct(3, atomBC, atomDspls, atomMbrTypes, &mpiAtomStructType);
492	–	MPI_Type_commit(&mpiAtomStructType);
493	–
494	–
495	–	// **********************************************************************
496	–	// Init the bondStruct mpi type
497	–
498	–	bondStruct bondProto; // mpiPrototype
499	–	int bondBC[3] = {30,2,2};  // block counts
500	–	MPI_Aint bondDspls[3];           // displacements
501	–	MPI_Datatype bondMbrTypes[3];    // member mpi types
502	–
503	–	MPI_Address(&bondProto.nameA, &bondDspls[0]);
504	–	MPI_Address(&bondProto.d0,    &bondDspls[1]);
505	–	MPI_Address(&bondProto.last,  &bondDspls[2]);
506	–
507	–	bondMbrTypes[0] = MPI_CHAR;
508	–	bondMbrTypes[1] = MPI_DOUBLE;
509	–	bondMbrTypes[2] = MPI_INT;
510	–
511	–	for (i=2; i >= 0; i--) bondDspls[i] -= bondDspls[0];
512	–
513	–	MPI_Type_struct(3, bondBC, bondDspls, bondMbrTypes, &mpiBondStructType);
514	–	MPI_Type_commit(&mpiBondStructType);
515	–
516	–
517	–	// **********************************************************************
518	–	// Init the bendStruct mpi type
519	–
520	–	bendStruct bendProto; // mpiPrototype
521	–	int bendBC[3] = {75,4,1};  // block counts
522	–	MPI_Aint bendDspls[3];           // displacements
523	–	MPI_Datatype bendMbrTypes[3];    // member mpi types
524	–
525	–	MPI_Address(&bendProto.nameA, &bendDspls[0]);
526	–	MPI_Address(&bendProto.k1,    &bendDspls[1]);
527	–	MPI_Address(&bendProto.last,  &bendDspls[2]);
528	–
529	–	bendMbrTypes[0] = MPI_CHAR;
530	–	bendMbrTypes[1] = MPI_DOUBLE;
531	–	bendMbrTypes[2] = MPI_INT;
532	–
533	–	for (i=2; i >= 0; i--) bendDspls[i] -= bendDspls[0];
534	–
535	–	MPI_Type_struct(3, bendBC, bendDspls, bendMbrTypes, &mpiBendStructType);
536	–	MPI_Type_commit(&mpiBendStructType);
537	–
538	–
539	–	// **********************************************************************
540	–	// Init the torsionStruct mpi type
541	–
542	–	torsionStruct torsionProto; // mpiPrototype
543	–	int torsionBC[3] = {90,4,1};  // block counts
544	–	MPI_Aint torsionDspls[3];           // displacements
545	–	MPI_Datatype torsionMbrTypes[3];    // member mpi types
546	–
547	–	MPI_Address(&torsionProto.nameA, &torsionDspls[0]);
548	–	MPI_Address(&torsionProto.k1,    &torsionDspls[1]);
549	–	MPI_Address(&torsionProto.last,  &torsionDspls[2]);
550	–
551	–	torsionMbrTypes[0] = MPI_CHAR;
552	–	torsionMbrTypes[1] = MPI_DOUBLE;
553	–	torsionMbrTypes[2] = MPI_INT;
554	–
555	–	for (i=2; i >= 0; i--) torsionDspls[i] -= torsionDspls[0];
556	–
557	–	MPI_Type_struct(3, torsionBC, torsionDspls, torsionMbrTypes,
558	–	&mpiTorsionStructType);
559	–	MPI_Type_commit(&mpiTorsionStructType);
560	–
561	–	// ***********************************************************************
562	–
563	–	if( worldRank == 0 ){
564	–	#endif
101
566	–	// generate the force file name
567	–
568	–	fileName = "DUFF.frc";
569	–	//    fprintf( stderr,"Trying to open %s\n", fileName );
570	–
571	–	// attempt to open the file in the current directory first.
572	–
573	–	frcFile = fopen( fileName.c_str(), "r" );
574	–
575	–	if( frcFile == NULL ){
576	–
577	–	// next see if the force path enviorment variable is set
578	–
579	–	tempString = ffPath + "/" + fileName;
580	–	fileName = tempString;
581	–
582	–	frcFile = fopen( fileName.c_str(), "r" );
583	–
584	–	if( frcFile == NULL ){
585	–
586	–	sprintf( painCave.errMsg,
587	–	"Error opening the force field parameter file:\n"
588	–	"\t%s\n"
589	–	"\tHave you tried setting the FORCE_PARAM_PATH environment "
590	–	"variable?\n",
591	–	fileName.c_str() );
592	–	painCave.severity = OOPSE_ERROR;
593	–	painCave.isFatal = 1;
594	–	simError();
595	–	}
596	–	}
597	–
598	–	#ifdef IS_MPI
599	–	}
600	–
601	–	sprintf( checkPointMsg, "DUFF file opened sucessfully." );
602	–	MPIcheckPoint();
603	–
604	–	#endif // is_mpi
605	–	}
606	–
607	–
608	–	DUFF::~DUFF(){
609	–
610	–	if( headAtomType != NULL ) delete headAtomType;
611	–	if( headBondType != NULL ) delete headBondType;
612	–	if( headBendType != NULL ) delete headBendType;
613	–	if( headTorsionType != NULL ) delete headTorsionType;
614	–
615	–	#ifdef IS_MPI
616	–	if( worldRank == 0 ){
617	–	#endif // is_mpi
618	–
619	–	fclose( frcFile );
620	–
621	–	#ifdef IS_MPI
622	–	}
623	–	#endif // is_mpi
624	–	}
625	–
626	–	void DUFF::cleanMe( void ){
627	–
628	–	#ifdef IS_MPI
629	–
630	–	// keep the linked lists in the mpi version
631	–
632	–	#else // is_mpi
633	–
634	–	// delete the linked lists in the single processor version
635	–
636	–	if( headAtomType != NULL ) delete headAtomType;
637	–	if( headBondType != NULL ) delete headBondType;
638	–	if( headBendType != NULL ) delete headBendType;
639	–	if( headTorsionType != NULL ) delete headTorsionType;
640	–
641	–	#endif // is_mpi
642	–	}
643	–
644	–
645	–	void DUFF::initForceField(){
646	–
647	–	initFortran( entry_plug->useReactionField );
648	–	}
649	–
650	–
651	–	void DUFF::readParams( void ){
652	–
653	–	int identNum, isError;
654	–
655	–	atomStruct atomInfo;
656	–	bondStruct bondInfo;
657	–	bendStruct bendInfo;
658	–	torsionStruct torsionInfo;
659	–
660	–	AtomType* at;
661	–
662	–	bigSigma = 0.0;
663	–
664	–	atomInfo.last = 1;
665	–	bondInfo.last = 1;
666	–	bendInfo.last = 1;
667	–	torsionInfo.last = 1;
668	–
669	–	// read in the atom info
670	–
671	–	#ifdef IS_MPI
672	–	if( worldRank == 0 ){
673	–	#endif
674	–
675	–	// read in the atom types.
676	–
677	–	headAtomType = new LinkedAtomType;
678	–
679	–	fastForward( "AtomTypes", "initializeAtoms" );
680	–
681	–	// we are now at the AtomTypes section.
682	–
683	–	eof_test = fgets( readLine, sizeof(readLine), frcFile );
684	–	lineNum++;
685	–
686	–
687	–	// read a line, and start parseing out the atom types
688	–
689	–	if( eof_test == NULL ){
690	–	sprintf( painCave.errMsg,
691	–	"Error in reading Atoms from force file at line %d.\n",
692	–	lineNum );
693	–	painCave.isFatal = 1;
694	–	simError();
695	–	}
696	–
697	–	identNum = 1;
698	–	// stop reading at end of file, or at next section
699	–	while( readLine[0] != '#' && eof_test != NULL ){
700	–
701	–	// toss comment lines
702	–	if( readLine[0] != '!' ){
703	–
704	–	// the parser returns 0 if the line was blank
705	–	if( parseAtom( readLine, lineNum, atomInfo ) ){
706	–	atomInfo.ident = identNum;
707	–	headAtomType->add( atomInfo );;
708	–	identNum++;
709	–	}
710	–	}
711	–	eof_test = fgets( readLine, sizeof(readLine), frcFile );
712	–	lineNum++;
713	–	}
714	–
715	–	#ifdef IS_MPI
716	–
717	–	// send out the linked list to all the other processes
718	–
719	–	sprintf( checkPointMsg,
720	–	"DUFF atom structures read successfully." );
721	–	MPIcheckPoint();
722	–
723	–	currentAtomType = headAtomType->next; //skip the first element who is a place holder.
724	–	while( currentAtomType != NULL ){
725	–	currentAtomType->duplicate( atomInfo );
726	–
727	–	sendFrcStruct( &atomInfo, mpiAtomStructType );
728	–
729	–	sprintf( checkPointMsg,
730	–	"successfully sent DUFF force type: \"%s\"\n",
731	–	atomInfo.name );
732	–	MPIcheckPoint();
733	–
734	–	currentAtomType = currentAtomType->next;
735	–	}
736	–	atomInfo.last = 1;
737	–	sendFrcStruct( &atomInfo, mpiAtomStructType );
738	–
739	–	}
740	–
741	–	else{
742	–
743	–	// listen for node 0 to send out the force params
744	–
745	–	MPIcheckPoint();
746	–
747	–	headAtomType = new LinkedAtomType;
748	–	receiveFrcStruct( &atomInfo, mpiAtomStructType );
749	–
750	–	while( !atomInfo.last ){
751	–
752	–	headAtomType->add( atomInfo );
753	–
754	–	MPIcheckPoint();
755	–
756	–	receiveFrcStruct( &atomInfo, mpiAtomStructType );
757	–	}
758	–	}
759	–
760	–	#endif // is_mpi
761	–
762	–	// dummy variables
763	–
764	–	currentAtomType = headAtomType->next;;
765	–	while( currentAtomType != NULL ){
766	–
767	–	if( currentAtomType->name[0] != '\0' ){
768	–
769	–	if (currentAtomType->isSSD || currentAtomType->isDipole)
770	–	at = new DirectionalAtomType();
771	–	else
772	–	at = new AtomType();
773	–
774	–	if (currentAtomType->isSSD) {
775	–	((DirectionalAtomType*)at)->setSticky();
776	–	entry_plug->useSticky = 1;
777	–	}
778	–
779	–	if (currentAtomType->isDipole) {
780	–	((DirectionalAtomType*)at)->setDipole();
781	–	entry_plug->useDipoles = 1;
782	–	}
783	–
784	–	at->setIdent(currentAtomType->ident);
785	–	at->setName(currentAtomType->name);
786	–	at->setLennardJones();
787	–	at->complete();
788	–	}
789	–	currentAtomType = currentAtomType->next;
790	–	}
791	–
792	–	currentAtomType = headAtomType->next;;
793	–	while( currentAtomType != NULL ){
794	–
795	–	if( currentAtomType->name[0] != '\0' ){
796	–	isError = 0;
797	–	newLJtype( &(currentAtomType->ident), &(currentAtomType->sigma),
798	–	&(currentAtomType->epslon), &isError);
799	–	if( isError ){
800	–	sprintf( painCave.errMsg,
801	–	"Error initializing the \"%s\" LJ type in fortran\n",
802	–	currentAtomType->name );
803	–	painCave.isFatal = 1;
804	–	simError();
805	–	}
806	–
807	–	if (currentAtomType->isDipole) {
808	–	newDipoleType(&(currentAtomType->ident), &(currentAtomType->dipole),
809	–	&isError);
810	–	if( isError ){
811	–	sprintf( painCave.errMsg,
812	–	"Error initializing the \"%s\" dipole type in fortran\n",
813	–	currentAtomType->name );
814	–	painCave.isFatal = 1;
815	–	simError();
816	–	}
817	–	}
818	–
819	–	if(currentAtomType->isSSD) {
820	–	makeStickyType( &(currentAtomType->w0), &(currentAtomType->v0),
821	–	&(currentAtomType->v0p),
822	–	&(currentAtomType->rl), &(currentAtomType->ru),
823	–	&(currentAtomType->rlp), &(currentAtomType->rup));
824	–	}
825	–
826	–	}
827	–	currentAtomType = currentAtomType->next;
828	–	}
829	–
830	–	#ifdef IS_MPI
831	–	sprintf( checkPointMsg,
832	–	"DUFF atom structures successfully sent to fortran\n" );
833	–	MPIcheckPoint();
834	–	#endif // is_mpi
835	–
836	–
837	–
838	–	// read in the bonds
839	–
840	–	#ifdef IS_MPI
841	–	if( worldRank == 0 ){
842	–	#endif
843	–
844	–	// read in the bond types.
845	–
846	–	headBondType = new LinkedBondType;
847	–
848	–	fastForward( "BondTypes", "initializeBonds" );
849	–
850	–	// we are now at the bondTypes section
851	–
852	–	eof_test =  fgets( readLine, sizeof(readLine), frcFile );
853	–	lineNum++;
854	–
855	–
856	–	// read a line, and start parseing out the atom types
857	–
858	–	if( eof_test == NULL ){
859	–	sprintf( painCave.errMsg,
860	–	"Error in reading bonds from force file at line %d.\n",
861	–	lineNum );
862	–	painCave.isFatal = 1;
863	–	simError();
864	–	}
865	–
866	–	// stop reading at end of file, or at next section
867	–	while( readLine[0] != '#' && eof_test != NULL ){
868	–
869	–	// toss comment lines
870	–	if( readLine[0] != '!' ){
871	–
872	–	// the parser returns 0 if the line was blank
873	–	if( parseBond( readLine, lineNum, bondInfo ) ){
874	–	headBondType->add( bondInfo );
875	–	}
876	–	}
877	–	eof_test = fgets( readLine, sizeof(readLine), frcFile );
878	–	lineNum++;
879	–	}
880	–
881	–	#ifdef IS_MPI
882	–
883	–	// send out the linked list to all the other processes
884	–
885	–	sprintf( checkPointMsg,
886	–	"DUFF bond structures read successfully." );
887	–	MPIcheckPoint();
888	–
889	–	currentBondType = headBondType->next;
890	–	while( currentBondType != NULL ){
891	–	currentBondType->duplicate( bondInfo );
892	–	sendFrcStruct( &bondInfo, mpiBondStructType );
893	–	currentBondType = currentBondType->next;
894	–	}
895	–	bondInfo.last = 1;
896	–	sendFrcStruct( &bondInfo, mpiBondStructType );
897	–
898	–	}
899	–
900	–	else{
901	–
902	–	// listen for node 0 to send out the force params
903	–
904	–	MPIcheckPoint();
905	–
906	–	headBondType = new LinkedBondType;
907	–	receiveFrcStruct( &bondInfo, mpiBondStructType );
908	–	while( !bondInfo.last ){
909	–
910	–	headBondType->add( bondInfo );
911	–	receiveFrcStruct( &bondInfo, mpiBondStructType );
912	–	}
913	–	}
914	–
915	–	sprintf( checkPointMsg,
916	–	"DUFF bond structures broadcast successfully." );
917	–	MPIcheckPoint();
918	–
919	–	#endif // is_mpi
920	–
921	–
922	–	// read in the bends
923	–
924	–	#ifdef IS_MPI
925	–	if( worldRank == 0 ){
926	–	#endif
927	–
928	–	// read in the bend types.
929	–
930	–	headBendType = new LinkedBendType;
931	–
932	–	fastForward( "BendTypes", "initializeBends" );
933	–
934	–	// we are now at the bendTypes section
935	–
936	–	eof_test =  fgets( readLine, sizeof(readLine), frcFile );
937	–	lineNum++;
938	–
939	–	// read a line, and start parseing out the bend types
940	–
941	–	if( eof_test == NULL ){
942	–	sprintf( painCave.errMsg,
943	–	"Error in reading bends from force file at line %d.\n",
944	–	lineNum );
945	–	painCave.isFatal = 1;
946	–	simError();
947	–	}
948	–
949	–	// stop reading at end of file, or at next section
950	–	while( readLine[0] != '#' && eof_test != NULL ){
951	–
952	–	// toss comment lines
953	–	if( readLine[0] != '!' ){
954	–
955	–	// the parser returns 0 if the line was blank
956	–	if( parseBend( readLine, lineNum, bendInfo ) ){
957	–	headBendType->add( bendInfo );
958	–	}
959	–	}
960	–	eof_test = fgets( readLine, sizeof(readLine), frcFile );
961	–	lineNum++;
962	–	}
963	–
964	–	#ifdef IS_MPI
965	–
966	–	// send out the linked list to all the other processes
967	–
968	–	sprintf( checkPointMsg,
969	–	"DUFF bend structures read successfully." );
970	–	MPIcheckPoint();
971	–
972	–	currentBendType = headBendType->next;
973	–	while( currentBendType != NULL ){
974	–	currentBendType->duplicate( bendInfo );
975	–	sendFrcStruct( &bendInfo, mpiBendStructType );
976	–	currentBendType = currentBendType->next;
977	–	}
978	–	bendInfo.last = 1;
979	–	sendFrcStruct( &bendInfo, mpiBendStructType );
980	–
981	–	}
982	–
983	–	else{
984	–
985	–	// listen for node 0 to send out the force params
986	–
987	–	MPIcheckPoint();
988	–
989	–	headBendType = new LinkedBendType;
990	–	receiveFrcStruct( &bendInfo, mpiBendStructType );
991	–	while( !bendInfo.last ){
992	–
993	–	headBendType->add( bendInfo );
994	–	receiveFrcStruct( &bendInfo, mpiBendStructType );
995	–	}
996	–	}
997	–
998	–	sprintf( checkPointMsg,
999	–	"DUFF bend structures broadcast successfully." );
1000	–	MPIcheckPoint();
1001	–
1002	–	#endif // is_mpi
1003	–
1004	–
1005	–	// read in the torsions
1006	–
1007	–	#ifdef IS_MPI
1008	–	if( worldRank == 0 ){
1009	–	#endif
1010	–
1011	–	// read in the torsion types.
1012	–
1013	–	headTorsionType = new LinkedTorsionType;
1014	–
1015	–	fastForward( "TorsionTypes", "initializeTorsions" );
1016	–
1017	–	// we are now at the torsionTypes section
1018	–
1019	–	eof_test =  fgets( readLine, sizeof(readLine), frcFile );
1020	–	lineNum++;
1021	–
1022	–
1023	–	// read a line, and start parseing out the atom types
1024	–
1025	–	if( eof_test == NULL ){
1026	–	sprintf( painCave.errMsg,
1027	–	"Error in reading torsions from force file at line %d.\n",
1028	–	lineNum );
1029	–	painCave.isFatal = 1;
1030	–	simError();
1031	–	}
1032	–
1033	–	// stop reading at end of file, or at next section
1034	–	while( readLine[0] != '#' && eof_test != NULL ){
1035	–
1036	–	// toss comment lines
1037	–	if( readLine[0] != '!' ){
1038	–
1039	–	// the parser returns 0 if the line was blank
1040	–	if( parseTorsion( readLine, lineNum, torsionInfo ) ){
1041	–	headTorsionType->add( torsionInfo );
1042	–
1043	–	}
1044	–	}
1045	–	eof_test = fgets( readLine, sizeof(readLine), frcFile );
1046	–	lineNum++;
1047	–	}
1048	–
1049	–	#ifdef IS_MPI
1050	–
1051	–	// send out the linked list to all the other processes
1052	–
1053	–	sprintf( checkPointMsg,
1054	–	"DUFF torsion structures read successfully." );
1055	–	MPIcheckPoint();
1056	–
1057	–	currentTorsionType = headTorsionType->next;
1058	–	while( currentTorsionType != NULL ){
1059	–	currentTorsionType->duplicate( torsionInfo );
1060	–	sendFrcStruct( &torsionInfo, mpiTorsionStructType );
1061	–	currentTorsionType = currentTorsionType->next;
1062	–	}
1063	–	torsionInfo.last = 1;
1064	–	sendFrcStruct( &torsionInfo, mpiTorsionStructType );
1065	–
1066	–	}
1067	–
1068	–	else{
1069	–
1070	–	// listen for node 0 to send out the force params
1071	–
1072	–	MPIcheckPoint();
1073	–
1074	–	headTorsionType = new LinkedTorsionType;
1075	–	receiveFrcStruct( &torsionInfo, mpiTorsionStructType );
1076	–	while( !torsionInfo.last ){
1077	–
1078	–	headTorsionType->add( torsionInfo );
1079	–	receiveFrcStruct( &torsionInfo, mpiTorsionStructType );
1080	–	}
1081	–	}
1082	–
1083	–	sprintf( checkPointMsg,
1084	–	"DUFF torsion structures broadcast successfully." );
1085	–	MPIcheckPoint();
1086	–
1087	–	#endif // is_mpi
1088	–
1089	–	entry_plug->useLennardJones = 1;
102		}
103
104	<
1093	<
1094	<	void DUFF::initializeAtoms( int nAtoms, Atom** the_atoms ){
1095	<
1096	<
1097	<	//////////////////////////////////////////////////
1098	<	// a quick water fix
1099	<
1100	<	double waterI[3][3];
1101	<	waterI[0][0] = 1.76958347772500;
1102	<	waterI[0][1] = 0.0;
1103	<	waterI[0][2] = 0.0;
1104	<
1105	<	waterI[1][0] = 0.0;
1106	<	waterI[1][1] = 0.614537057924513;
1107	<	waterI[1][2] = 0.0;
1108	<
1109	<	waterI[2][0] = 0.0;
1110	<	waterI[2][1] = 0.0;
1111	<	waterI[2][2] = 1.15504641980049;
1112	<
1113	<
1114	<	double headI[3][3];
1115	<	headI[0][0] = 1125;
1116	<	headI[0][1] = 0.0;
1117	<	headI[0][2] = 0.0;
1118	<
1119	<	headI[1][0] = 0.0;
1120	<	headI[1][1] = 1125;
1121	<	headI[1][2] = 0.0;
1122	<
1123	<	headI[2][0] = 0.0;
1124	<	headI[2][1] = 0.0;
1125	<	headI[2][2] = 250;
1126	<
1127	<	//////////////////////////////////////////////////
1128	<
1129	<
1130	<	// initialize the atoms
1131	<
1132	<	DirectionalAtom* dAtom;
1133	<	double ji[3];
1134	<
1135	<	for(int i=0; i<nAtoms; i++ ){
1136	<
1137	<	currentAtomType = headAtomType->find( the_atoms[i]->getType() );
1138	<	if( currentAtomType == NULL ){
1139	<	sprintf( painCave.errMsg,
1140	<	"AtomType error, %s not found in force file.\n",
1141	<	the_atoms[i]->getType() );
1142	<	painCave.isFatal = 1;
1143	<	simError();
1144	<	}
1145	<
1146	<	the_atoms[i]->setMass( currentAtomType->mass );
1147	<	the_atoms[i]->setIdent( currentAtomType->ident );
1148	<
1149	<	if( bigSigma < currentAtomType->sigma ) bigSigma = currentAtomType->sigma;
1150	<
1151	<	if( currentAtomType->isDipole ){
1152	<	if( the_atoms[i]->isDirectional() ){
1153	<
1154	<	dAtom = (DirectionalAtom *) the_atoms[i];
1155	<	dAtom->setHasDipole( 1 );
1156	<
1157	<	ji[0] = 0.0;
1158	<	ji[1] = 0.0;
1159	<	ji[2] = 0.0;
1160	<
1161	<	dAtom->setJ( ji );
1162	<
1163	<	if(!strcmp("SSD",the_atoms[i]->getType())){
1164	<	dAtom->setI( waterI );
1165	<	}
1166	<	else if(!strcmp("HEAD",the_atoms[i]->getType())){
1167	<	dAtom->setI( headI );
1168	<	}
1169	<	else{
1170	<	sprintf(painCave.errMsg,
1171	<	"AtmType error, %s does not have a moment of inertia set.\n",
1172	<	the_atoms[i]->getType() );
1173	<	painCave.isFatal = 1;
1174	<	simError();
1175	<	}
1176	<	entry_plug->n_dipoles++;
1177	<	}
1178	<	else{
1179	<
1180	<	sprintf( painCave.errMsg,
1181	<	"DUFF error: Atom \"%s\" is a dipole, yet no standard"
1182	<	" orientation was specifed in the meta-data file.\n",
1183	<	currentAtomType->name );
1184	<	painCave.isFatal = 1;
1185	<	simError();
1186	<	}
1187	<	}
1188	<	else{
1189	<	if( the_atoms[i]->isDirectional() ){
1190	<	sprintf( painCave.errMsg,
1191	<	"DUFF error: Atom \"%s\" was given a standard "
1192	<	"orientation in the meta-data file, yet it is not a dipole.\n",
1193	<	currentAtomType->name);
1194	<	painCave.isFatal = 1;
1195	<	simError();
1196	<	}
1197	<	}
1198	<	}
1199	<	}
1200	<
1201	<	void DUFF::initializeBonds( int nBonds, Bond** bondArray,
1202	<	bond_pair* the_bonds ){
1203	<	int i,a,b;
1204	<	char* atomA;
1205	<	char* atomB;
1206	<
1207	<	Atom** the_atoms;
1208	<	the_atoms = entry_plug->atoms;
1209	<
1210	<
1211	<	// initialize the Bonds
1212	<
1213	<	for( i=0; i<nBonds; i++ ){
1214	<
1215	<	a = the_bonds[i].a;
1216	<	b = the_bonds[i].b;
1217	<
1218	<	atomA = the_atoms[a]->getType();
1219	<	atomB = the_atoms[b]->getType();
1220	<	currentBondType = headBondType->find( atomA, atomB );
1221	<	if( currentBondType == NULL ){
1222	<	sprintf( painCave.errMsg,
1223	<	"BondType error, %s - %s not found in force file.\n",
1224	<	atomA, atomB );
1225	<	painCave.isFatal = 1;
1226	<	simError();
1227	<	}
1228	<
1229	<	switch( currentBondType->type ){
1230	<
1231	<	case FIXED_BOND:
1232	<
1233	<	bondArray[i] = new ConstrainedBond( *the_atoms[a],
1234	<	*the_atoms[b],
1235	<	currentBondType->d0 );
1236	<	entry_plug->n_constraints++;
1237	<	break;
1238	<
1239	<	case HARMONIC_BOND:
1240	<
1241	<	bondArray[i] = new HarmonicBond( *the_atoms[a],
1242	<	*the_atoms[b],
1243	<	currentBondType->d0,
1244	<	currentBondType->k0 );
1245	<	break;
1246	<
1247	<	default:
1248	<
1249	<	break;
1250	<	// do nothing
1251	<	}
1252	<	}
1253	<	}
1254	<
1255	<	void DUFF::initializeBends( int nBends, Bend** bendArray,
1256	<	bend_set* the_bends ){
1257	<
1258	<	QuadraticBend* qBend;
1259	<	GhostBend* gBend;
1260	<	Atom** the_atoms;
1261	<	the_atoms = entry_plug->atoms;
1262	<
1263	<	int i, a, b, c;
1264	<	char* atomA;
1265	<	char* atomB;
1266	<	char* atomC;
1267	<
1268	<	// initialize the Bends
1269	<
1270	<	for( i=0; i<nBends; i++ ){
1271	<
1272	<	a = the_bends[i].a;
1273	<	b = the_bends[i].b;
1274	<	c = the_bends[i].c;
1275	<
1276	<	atomA = the_atoms[a]->getType();
1277	<	atomB = the_atoms[b]->getType();
1278	<
1279	<	if( the_bends[i].isGhost ) atomC = "GHOST";
1280	<	else atomC = the_atoms[c]->getType();
1281	<
1282	<	currentBendType = headBendType->find( atomA, atomB, atomC );
1283	<	if( currentBendType == NULL ){
1284	<	sprintf( painCave.errMsg, "BendType error, %s - %s - %s not found"
1285	<	" in force file.\n",
1286	<	atomA, atomB, atomC );
1287	<	painCave.isFatal = 1;
1288	<	simError();
1289	<	}
1290	<
1291	<	if( !strcmp( currentBendType->type, "quadratic" ) ){
1292	<
1293	<	if( the_bends[i].isGhost){
1294	<
1295	<	if( the_bends[i].ghost == b ){
1296	<	// do nothing
1297	<	}
1298	<	else if( the_bends[i].ghost == a ){
1299	<	c = a;
1300	<	a = b;
1301	<	b = c;
1302	<	}
1303	<	else{
1304	<	sprintf( painCave.errMsg,
1305	<	"BendType error, %s - %s - %s,\n"
1306	<	"  --> central atom is not "
1307	<	"correctly identified with the "
1308	<	"\"ghostVectorSource = \" tag.\n",
1309	<	atomA, atomB, atomC );
1310	<	painCave.isFatal = 1;
1311	<	simError();
1312	<	}
1313	<
1314	<	gBend = new GhostBend( *the_atoms[a],
1315	<	*the_atoms[b]);
1316	<
1317	<	gBend->setConstants( currentBendType->k1,
1318	<	currentBendType->k2,
1319	<	currentBendType->k3,
1320	<	currentBendType->t0 );
1321	<	bendArray[i] = gBend;
1322	<	}
1323	<	else{
1324	<	qBend = new QuadraticBend( *the_atoms[a],
1325	<	*the_atoms[b],
1326	<	*the_atoms[c] );
1327	<	qBend->setConstants( currentBendType->k1,
1328	<	currentBendType->k2,
1329	<	currentBendType->k3,
1330	<	currentBendType->t0 );
1331	<	bendArray[i] = qBend;
1332	<	}
1333	<	}
1334	<	}
1335	<	}
1336	<
1337	<	void DUFF::initializeTorsions( int nTorsions, Torsion** torsionArray,
1338	<	torsion_set* the_torsions ){
1339	<
1340	<	int i, a, b, c, d;
1341	<	char* atomA;
1342	<	char* atomB;
1343	<	char* atomC;
1344	<	char* atomD;
1345	<
1346	<	CubicTorsion* cTors;
1347	<	Atom** the_atoms;
1348	<	the_atoms = entry_plug->atoms;
1349	<
1350	<	// initialize the Torsions
1351	<
1352	<	for( i=0; i<nTorsions; i++ ){
1353	<
1354	<	a = the_torsions[i].a;
1355	<	b = the_torsions[i].b;
1356	<	c = the_torsions[i].c;
1357	<	d = the_torsions[i].d;
1358	<
1359	<	atomA = the_atoms[a]->getType();
1360	<	atomB = the_atoms[b]->getType();
1361	<	atomC = the_atoms[c]->getType();
1362	<	atomD = the_atoms[d]->getType();
1363	<	currentTorsionType = headTorsionType->find( atomA, atomB, atomC, atomD );
1364	<	if( currentTorsionType == NULL ){
1365	<	sprintf( painCave.errMsg,
1366	<	"TorsionType error, %s - %s - %s - %s not found"
1367	<	" in force file.\n",
1368	<	atomA, atomB, atomC, atomD );
1369	<	painCave.isFatal = 1;
1370	<	simError();
1371	<	}
1372	<
1373	<	if( !strcmp( currentTorsionType->type, "cubic" ) ){
1374	<
1375	<	cTors = new CubicTorsion( *the_atoms[a], *the_atoms[b],
1376	<	*the_atoms[c], *the_atoms[d] );
1377	<	cTors->setConstants( currentTorsionType->k1, currentTorsionType->k2,
1378	<	currentTorsionType->k3, currentTorsionType->k4 );
1379	<	torsionArray[i] = cTors;
1380	<	}
1381	<	}
1382	<	}
1383	<
1384	<	void DUFF::fastForward( char* stopText, char* searchOwner ){
1385	<
1386	<	int foundText = 0;
1387	<	char* the_token;
1388	<
1389	<	rewind( frcFile );
1390	<	lineNum = 0;
1391	<
1392	<	eof_test = fgets( readLine, sizeof(readLine), frcFile );
1393	<	lineNum++;
1394	<	if( eof_test == NULL ){
1395	<	sprintf( painCave.errMsg, "Error fast forwarding force file for %s: "
1396	<	" file is empty.\n",
1397	<	searchOwner );
1398	<	painCave.isFatal = 1;
1399	<	simError();
1400	<	}
1401	<
1402	<
1403	<	while( !foundText ){
1404	<	while( eof_test != NULL && readLine[0] != '#' ){
1405	<	eof_test = fgets( readLine, sizeof(readLine), frcFile );
1406	<	lineNum++;
1407	<	}
1408	<	if( eof_test == NULL ){
1409	<	sprintf( painCave.errMsg,
1410	<	"Error fast forwarding force file for %s at "
1411	<	"line %d: file ended unexpectedly.\n",
1412	<	searchOwner,
1413	<	lineNum );
1414	<	painCave.isFatal = 1;
1415	<	simError();
1416	<	}
1417	<
1418	<	the_token = strtok( readLine, " ,;\t#\n" );
1419	<	foundText = !strcmp( stopText, the_token );
1420	<
1421	<	if( !foundText ){
1422	<	eof_test = fgets( readLine, sizeof(readLine), frcFile );
1423	<	lineNum++;
1424	<
1425	<	if( eof_test == NULL ){
1426	<	sprintf( painCave.errMsg,
1427	<	"Error fast forwarding force file for %s at "
1428	<	"line %d: file ended unexpectedly.\n",
1429	<	searchOwner,
1430	<	lineNum );
1431	<	painCave.isFatal = 1;
1432	<	simError();
1433	<	}
1434	<	}
1435	<	}
1436	<	}
1437	<
1438	<
1439	<	int DUFF_NS::parseAtom( char *lineBuffer, int lineNum, atomStruct &info ){
1440	<
1441	<	char* the_token;
1442	<
1443	<	the_token = strtok( lineBuffer, " \n\t,;" );
1444	<	if( the_token != NULL ){
1445	<
1446	<	strcpy( info.name, the_token );
1447	<
1448	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1449	<	sprintf( painCave.errMsg,
1450	<	"Error parseing AtomTypes: line %d\n", lineNum );
1451	<	painCave.isFatal = 1;
1452	<	simError();
1453	<	}
1454	<
1455	<	info.isDipole = atoi( the_token );
1456	<
1457	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1458	<	sprintf( painCave.errMsg,
1459	<	"Error parseing AtomTypes: line %d\n", lineNum );
1460	<	painCave.isFatal = 1;
1461	<	simError();
1462	<	}
1463	<
1464	<	info.isSSD = atoi( the_token );
1465	<
1466	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1467	<	sprintf( painCave.errMsg,
1468	<	"Error parseing AtomTypes: line %d\n", lineNum );
1469	<	painCave.isFatal = 1;
1470	<	simError();
1471	<	}
1472	<
1473	<	info.mass = atof( the_token );
1474	<
1475	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1476	<	sprintf( painCave.errMsg,
1477	<	"Error parseing AtomTypes: line %d\n", lineNum );
1478	<	painCave.isFatal = 1;
1479	<	simError();
1480	<	}
1481	<
1482	<	info.epslon = atof( the_token );
1483	<
1484	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1485	<	sprintf( painCave.errMsg,
1486	<	"Error parseing AtomTypes: line %d\n", lineNum );
1487	<	painCave.isFatal = 1;
1488	<	simError();
1489	<	}
1490	<
1491	<	info.sigma = atof( the_token );
1492	<
1493	<	if( info.isDipole ){
1494	<
1495	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1496	<	sprintf( painCave.errMsg,
1497	<	"Error parseing AtomTypes: line %d\n", lineNum );
1498	<	painCave.isFatal = 1;
1499	<	simError();
1500	<	}
1501	<
1502	<	info.dipole = atof( the_token );
1503	<	}
1504	<	else info.dipole = 0.0;
1505	<
1506	<	if( info.isSSD ){
1507	<
1508	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1509	<	sprintf( painCave.errMsg,
1510	<	"Error parseing AtomTypes: line %d\n", lineNum );
1511	<	painCave.isFatal = 1;
1512	<	simError();
1513	<	}
1514	<
1515	<	info.w0 = atof( the_token );
1516	<
1517	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1518	<	sprintf( painCave.errMsg,
1519	<	"Error parseing AtomTypes: line %d\n", lineNum );
1520	<	painCave.isFatal = 1;
1521	<	simError();
1522	<	}
1523	<
1524	<	info.v0 = atof( the_token );
1525	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1526	<	sprintf( painCave.errMsg,
1527	<	"Error parseing AtomTypes: line %d\n", lineNum );
1528	<	painCave.isFatal = 1;
1529	<	simError();
1530	<	}
1531	<
1532	<	info.v0p = atof( the_token );
1533	<
1534	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1535	<	sprintf( painCave.errMsg,
1536	<	"Error parseing AtomTypes: line %d\n", lineNum );
1537	<	painCave.isFatal = 1;
1538	<	simError();
1539	<	}
1540	<
1541	<	info.rl = atof( the_token );
1542	<
1543	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1544	<	sprintf( painCave.errMsg,
1545	<	"Error parseing AtomTypes: line %d\n", lineNum );
1546	<	painCave.isFatal = 1;
1547	<	simError();
1548	<	}
1549	<
1550	<	info.ru = atof( the_token );
1551	<
1552	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1553	<	sprintf( painCave.errMsg,
1554	<	"Error parseing AtomTypes: line %d\n", lineNum );
1555	<	painCave.isFatal = 1;
1556	<	simError();
1557	<	}
1558	<
1559	<	info.rlp = atof( the_token );
1560	<
1561	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1562	<	sprintf( painCave.errMsg,
1563	<	"Error parseing AtomTypes: line %d\n", lineNum );
1564	<	painCave.isFatal = 1;
1565	<	simError();
1566	<	}
1567	<
1568	<	info.rup = atof( the_token );
1569	<	}
1570	<	else info.v0 = info.w0 = info.v0p = info.rl = info.ru = info.rlp = info.rup = 0.0;
1571	<
1572	<	return 1;
1573	<	}
1574	<	else return 0;
1575	<	}
1576	<
1577	<	int DUFF_NS::parseBond( char *lineBuffer, int lineNum, bondStruct &info ){
1578	<
1579	<	char* the_token;
1580	<	char bondType[30];
1581	<
1582	<	the_token = strtok( lineBuffer, " \n\t,;" );
1583	<	if( the_token != NULL ){
1584	<
1585	<	strcpy( info.nameA, the_token );
1586	<
1587	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1588	<	sprintf( painCave.errMsg,
1589	<	"Error parseing BondTypes: line %d\n", lineNum );
1590	<	painCave.isFatal = 1;
1591	<	simError();
1592	<	}
1593	<
1594	<	strcpy( info.nameB, the_token );
1595	<
1596	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1597	<	sprintf( painCave.errMsg,
1598	<	"Error parseing BondTypes: line %d\n", lineNum );
1599	<	painCave.isFatal = 1;
1600	<	simError();
1601	<	}
1602	<
1603	<	strcpy( bondType, the_token );
1604	<
1605	<	if( !strcmp( bondType, "fixed" ) ){
1606	<	info.type = FIXED_BOND;
1607	<
1608	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1609	<	sprintf( painCave.errMsg,
1610	<	"Error parseing BondTypes: line %d\n", lineNum );
1611	<	painCave.isFatal = 1;
1612	<	simError();
1613	<	}
1614	<
1615	<	info.d0 = atof( the_token );
1616	<
1617	<	info.k0=0.0;
1618	<	}
1619	<	else if( !strcmp( bondType, "harmonic" ) ){
1620	<	info.type = HARMONIC_BOND;
1621	<
1622	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1623	<	sprintf( painCave.errMsg,
1624	<	"Error parseing BondTypes: line %d\n", lineNum );
1625	<	painCave.isFatal = 1;
1626	<	simError();
1627	<	}
1628	<
1629	<	info.d0 = atof( the_token );
1630	<
1631	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1632	<	sprintf( painCave.errMsg,
1633	<	"Error parseing BondTypes: line %d\n", lineNum );
1634	<	painCave.isFatal = 1;
1635	<	simError();
1636	<	}
1637	<
1638	<	info.k0 = atof( the_token );
1639	<	}
1640	<
1641	<	else{
1642	<	sprintf( painCave.errMsg,
1643	<	"Unknown DUFF bond type \"%s\" at line %d\n",
1644	<	bondType,
1645	<	lineNum );
1646	<	painCave.isFatal = 1;
1647	<	simError();
1648	<	}
1649	<
1650	<	return 1;
1651	<	}
1652	<	else return 0;
1653	<	}
1654	<
1655	<
1656	<	int DUFF_NS::parseBend( char *lineBuffer, int lineNum, bendStruct &info ){
1657	<
1658	<	char* the_token;
1659	<
1660	<	the_token = strtok( lineBuffer, " \n\t,;" );
1661	<	if( the_token != NULL ){
1662	<
1663	<	strcpy( info.nameA, the_token );
1664	<
1665	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1666	<	sprintf( painCave.errMsg,
1667	<	"Error parseing BendTypes: line %d\n", lineNum );
1668	<	painCave.isFatal = 1;
1669	<	simError();
1670	<	}
1671	<
1672	<	strcpy( info.nameB, the_token );
1673	<
1674	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1675	<	sprintf( painCave.errMsg,
1676	<	"Error parseing BendTypes: line %d\n", lineNum );
1677	<	painCave.isFatal = 1;
1678	<	simError();
1679	<	}
1680	<
1681	<	strcpy( info.nameC, the_token );
1682	<
1683	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1684	<	sprintf( painCave.errMsg,
1685	<	"Error parseing BendTypes: line %d\n", lineNum );
1686	<	painCave.isFatal = 1;
1687	<	simError();
1688	<	}
1689	<
1690	<	strcpy( info.type, the_token );
1691	<
1692	<	if( !strcmp( info.type, "quadratic" ) ){
1693	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1694	<	sprintf( painCave.errMsg,
1695	<	"Error parseing BendTypes: line %d\n", lineNum );
1696	<	painCave.isFatal = 1;
1697	<	simError();
1698	<	}
1699	<
1700	<	info.k1 = atof( the_token );
1701	<
1702	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1703	<	sprintf( painCave.errMsg,
1704	<	"Error parseing BendTypes: line %d\n", lineNum );
1705	<	painCave.isFatal = 1;
1706	<	simError();
1707	<	}
1708	<
1709	<	info.k2 = atof( the_token );
1710	<
1711	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1712	<	sprintf( painCave.errMsg,
1713	<	"Error parseing BendTypes: line %d\n", lineNum );
1714	<	painCave.isFatal = 1;
1715	<	simError();
1716	<	}
1717	<
1718	<	info.k3 = atof( the_token );
1719	<
1720	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1721	<	sprintf( painCave.errMsg,
1722	<	"Error parseing BendTypes: line %d\n", lineNum );
1723	<	painCave.isFatal = 1;
1724	<	simError();
1725	<	}
1726	<
1727	<	info.t0 = atof( the_token );
1728	<	}
1729	<
1730	<	else{
1731	<	sprintf( painCave.errMsg,
1732	<	"Unknown DUFF bend type \"%s\" at line %d\n",
1733	<	info.type,
1734	<	lineNum );
1735	<	painCave.isFatal = 1;
1736	<	simError();
1737	<	}
1738	<
1739	<	return 1;
1740	<	}
1741	<	else return 0;
1742	<	}
1743	<
1744	<	int DUFF_NS::parseTorsion( char *lineBuffer, int lineNum, torsionStruct &info ){
1745	<
1746	<	char*  the_token;
1747	<
1748	<	the_token = strtok( lineBuffer, " \n\t,;" );
1749	<	if( the_token != NULL ){
1750	<
1751	<	strcpy( info.nameA, the_token );
1752	<
1753	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1754	<	sprintf( painCave.errMsg,
1755	<	"Error parseing TorsionTypes: line %d\n", lineNum );
1756	<	painCave.isFatal = 1;
1757	<	simError();
1758	<	}
1759	<
1760	<	strcpy( info.nameB, the_token );
1761	<
1762	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1763	<	sprintf( painCave.errMsg,
1764	<	"Error parseing TorsionTypes: line %d\n", lineNum );
1765	<	painCave.isFatal = 1;
1766	<	simError();
1767	<	}
1768	<
1769	<	strcpy( info.nameC, the_token );
1770	<
1771	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1772	<	sprintf( painCave.errMsg,
1773	<	"Error parseing TorsionTypes: line %d\n", lineNum );
1774	<	painCave.isFatal = 1;
1775	<	simError();
1776	<	}
1777	<
1778	<	strcpy( info.nameD, the_token );
1779	<
1780	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1781	<	sprintf( painCave.errMsg,
1782	<	"Error parseing TorsionTypes: line %d\n", lineNum );
1783	<	painCave.isFatal = 1;
1784	<	simError();
1785	<	}
1786	<
1787	<	strcpy( info.type, the_token );
1788	<
1789	<	if( !strcmp( info.type, "cubic" ) ){
1790	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1791	<	sprintf( painCave.errMsg,
1792	<	"Error parseing TorsionTypes: line %d\n", lineNum );
1793	<	painCave.isFatal = 1;
1794	<	simError();
1795	<	}
1796	<
1797	<	info.k1 = atof( the_token );
1798	<
1799	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1800	<	sprintf( painCave.errMsg,
1801	<	"Error parseing TorsionTypes: line %d\n", lineNum );
1802	<	painCave.isFatal = 1;
1803	<	simError();
1804	<	}
1805	<
1806	<	info.k2 = atof( the_token );
1807	<
1808	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1809	<	sprintf( painCave.errMsg,
1810	<	"Error parseing TorsionTypes: line %d\n", lineNum );
1811	<	painCave.isFatal = 1;
1812	<	simError();
1813	<	}
1814	<
1815	<	info.k3 = atof( the_token );
1816	<
1817	<	if( ( the_token = strtok( NULL, " \n\t,;" ) ) == NULL ){
1818	<	sprintf( painCave.errMsg,
1819	<	"Error parseing TorsionTypes: line %d\n", lineNum );
1820	<	painCave.isFatal = 1;
1821	<	simError();
1822	<	}
1823	<
1824	<	info.k4 = atof( the_token );
1825	<
1826	<	}
1827	<
1828	<	else{
1829	<	sprintf( painCave.errMsg,
1830	<	"Unknown DUFF torsion type \"%s\" at line %d\n",
1831	<	info.type,
1832	<	lineNum );
1833	<	painCave.isFatal = 1;
1834	<	simError();
1835	<	}
1836	<
1837	<	return 1;
1838	<	}
1839	<
1840	<	else return 0;
1841	<	}
104	>	} //end namespace oopse

Diff Legend

–	Removed lines
+	Added lines
<	Changed lines
>	Changed lines