minor fixes in ditribution files
[gromacs/qmmm-gamess-us.git] / src / tools / gmx_dih.c
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35 #ifdef HAVE_CONFIG_H
36 #include <config.h>
37 #endif
38 #include <math.h>
40 #include "sysstuff.h"
41 #include "string2.h"
42 #include "copyrite.h"
43 #include "futil.h"
44 #include "smalloc.h"
45 #include "statutil.h"
46 #include "nrama.h"
47 #include "physics.h"
48 #include "macros.h"
49 #include "xvgr.h"
50 #include "vec.h"
51 #include "gmx_ana.h"
54 #define NOMIN 'X'
56 static void dump_dih(int nframes,char *title,real time[],real dih[])
58 FILE *out;
59 char fname[256];
60 int i;
62 sprintf(fname,"dih.%s",title);
63 printf("A dihedral transition occurred in %s\n",fname);
64 printf("Do you want to plot it to %s ? (y/n) ",fname);
65 fflush(stdout);
66 out=ffopen(fname,"w");
67 for(i=0; (i<nframes); i++)
68 fprintf(out,"%10.3f %12.5e\n",time[i],dih[i]);
69 ffclose(out);
72 static void ana_dih(FILE *out,char *index,int nframes,real dih[],t_dih *dd)
74 int i;
75 real mind,maxd,sum,av,var,prev,width;
76 bool bTrans;
78 mind=5400,maxd=-5400,sum=0,av=0,var=0;
80 prev=dih[0];
81 for(i=0; (i<nframes); i++) {
82 if ((dih[i]-prev) > 180) {
83 /* PBC.. */
84 dih[i]-=360;
86 else if ((dih[i]-prev) < -180)
87 dih[i]+=360;
88 prev=dih[i];
90 sum+=dih[i];
91 mind=min(mind,dih[i]);
92 maxd=max(maxd,dih[i]);
94 av=sum/nframes;
95 for(i=0; (i<nframes); i++)
96 var+=sqr(dih[i]-av);
97 var/=nframes;
98 width=(360.0/dd->mult);
99 bTrans=((maxd - mind) > width);
101 fprintf(out,"%-10s %10.3f %10.3f %10.3f %10.3f %10.3f %-10s%3.0f\n",
102 index,mind,av,maxd,var,sqrt(var),
103 bTrans ? "Yep" : "",width);
106 static int find_min(real phi,int ntab,real phitab[])
108 int i,imin;
109 real mind,mm;
110 real width;
112 /* Set closest minimum to the first one */
113 width=360.0/ntab;
114 mind=fabs(phi-phitab[0]);
115 imin=0;
116 for(i=1; (i<ntab); i++) {
117 mm=fabs(phi-phitab[i]);
118 if (mm < mind) {
119 imin=i;
120 mind=mm;
123 if (mind < width*0.5 )
124 return imin;
125 else
126 return -1;
129 static int vphi(t_dih *dih,real phi,int mult)
131 static real m2[] = { 90, 270 };
132 static real m3[] = { 60, 180, 300 };
133 static real m4[] = { 45, 135, 225, 315 };
134 static real m6[] = { 30, 90, 150, 210, 270, 330 };
136 real phiref;
137 int vpp=0;
139 phiref=RAD2DEG*(phi-dih->phi0);
140 while (phiref < 0)
141 phiref+=360;
142 while (phiref > 360)
143 phiref-=360;
145 switch(mult) {
146 case 2:
147 vpp=find_min(phiref,2,m2);
148 break;
149 case 3:
150 vpp=find_min(phiref,3,m3);
151 break;
152 case 4:
153 vpp=find_min(phiref,4,m4);
154 break;
155 case 6:
156 vpp=find_min(phiref,6,m6);
157 break;
158 default:
159 gmx_fatal(FARGS,"No such multiplicity %d",dih->mult);
162 if (vpp == -1)
163 return NOMIN;
164 else
165 return vpp+'0';
168 typedef struct t_cluster {
169 int ndih;
170 int freq;
171 char *minimum;
172 struct t_cluster *next;
173 } t_cluster;
175 static t_cluster *search_cluster(t_cluster *cl,char *minimum)
177 t_cluster *ccl=cl;
179 while (ccl != NULL) {
180 if (strcmp(minimum,ccl->minimum)==0)
181 return ccl;
182 ccl=ccl->next;
184 return NULL;
187 static void add_cluster(t_cluster **cl,int ndih,char *minimum)
189 t_cluster *loper;
190 t_cluster *ccl;
192 snew(ccl,1);
193 ccl->ndih=ndih;
194 ccl->freq=1;
195 ccl->minimum=strdup(minimum);
196 ccl->next=NULL;
198 if (*cl == NULL)
199 *cl=ccl;
200 else {
201 loper=*cl;
202 while (loper->next != NULL)
203 loper=loper->next;
204 loper->next=ccl;
208 static void p_cluster(FILE *out,t_cluster *cl)
210 t_cluster *loper;
212 fprintf(out,"* * * C L U S T E R A N A L Y S I S * * *\n\n");
213 fprintf(out," Frequency Dihedral minima\n");
214 loper=cl;
215 while (loper != NULL) {
216 fprintf(out,"%10d %s\n",loper->freq,loper->minimum);
217 loper=loper->next;
221 static void ana_cluster(FILE *out, t_xrama *xr,real **dih,real time[],
222 t_topology *top,int nframes,int mult)
224 t_cluster *cl=NULL,*scl;
225 char *minimum;
226 int i,j,nx;
228 /* Number of dihedrals + terminating NULL
229 * this allows for using string routines
231 snew(minimum,xr->ndih+1);
233 for(i=0; (i<nframes); i++) {
234 nx=0;
235 for(j=0; (j<xr->ndih); j++) {
236 minimum[j] = vphi(&xr->dih[j],dih[j][i],
237 mult == -1 ? xr->dih[j].mult : mult);
238 if (minimum[j] == NOMIN)
239 nx++;
241 if (nx == 0) {
242 if ((scl=search_cluster(cl,minimum)) == NULL)
243 add_cluster(&cl,xr->ndih,minimum);
244 else
245 scl->freq++;
248 p_cluster(out,cl);
250 sfree(minimum);
253 static void ana_trans(FILE *out, t_xrama *xr,real **dih,real time[],
254 t_topology *top,int nframes, const output_env_t oenv)
256 FILE *outd;
257 real prev_phi,prev_psi;
258 int i,j,phi,psi;
259 char buf[10];
261 fprintf(out,"\n\t* * * D I H E D R A L S T A T I S T I C S * * *\n\n");
262 fprintf(out,"%-10s %10s %10s %10s %10s %10s %10s\n",
263 "index","minimum","average","maximum","variance","std.dev",
264 "transition");
265 for(i=0; (i>xr->ndih); i++) {
266 sprintf(buf,"dih-%d",i);
267 ana_dih(out,buf,nframes,dih[i],&(xr->dih[i]));
269 for(i=0; (i<xr->npp); i++) {
270 sprintf(buf,"%s",xr->pp[i].label);
271 outd=xvgropen(buf,"Dihedral Angles","Time (ps)","Degrees",oenv);
273 phi=xr->pp[i].iphi;
274 psi=xr->pp[i].ipsi;
275 prev_phi=dih[phi][0];
276 prev_psi=dih[psi][0];
277 for(j=0; (j<nframes); j++) {
278 /* PBC.. */
279 if ((dih[phi][j]-prev_phi) > 180)
280 dih[phi][j]-=360;
281 else if ((dih[phi][j]-prev_phi) < -180)
282 dih[phi][j]+=360;
283 prev_phi=dih[phi][j];
284 if ((dih[psi][j]-prev_psi) > 180)
285 dih[psi][j]-=360;
286 else if ((dih[psi][j]-prev_psi) < -180)
287 dih[psi][j]+=360;
288 prev_psi=dih[psi][j];
289 fprintf(outd,"%10g %10g %10g\n",time[j],prev_phi,prev_psi);
291 ffclose(outd);
295 int gmx_dih(int argc,char *argv[])
297 const char *desc[] = {
298 "g_dih can do two things. The default is to analyze dihedral transitions",
299 "by merely computing all the dihedral angles defined in your topology",
300 "for the whole trajectory. When a dihedral flips over to another minimum",
301 "an angle/time plot is made.[PAR]",
302 "The opther option is to discretize the dihedral space into a number of",
303 "bins, and group each conformation in dihedral space in the",
304 "appropriate bin. The output is then given as a number of dihedral",
305 "conformations sorted according to occupancy."
307 static int mult = -1;
308 static bool bSA = FALSE;
309 t_pargs pa[] = {
310 { "-sa", FALSE, etBOOL, {&bSA},
311 "Perform cluster analysis in dihedral space instead of analysing dihedral transitions." },
312 { "-mult", FALSE, etINT, {&mult},
313 "mulitiplicity for dihedral angles (by default read from topology)" }
315 FILE *out;
316 t_xrama *xr;
317 t_topology *top;
318 real **dih,*time;
319 real dd;
320 int i,nframes,maxframes=1000;
321 output_env_t oenv;
322 t_filenm fnm[] = {
323 { efTRX, "-f", NULL, ffREAD },
324 { efTPX, NULL, NULL, ffREAD },
325 { efOUT, NULL, NULL, ffWRITE }
327 #define NFILE asize(fnm)
329 CopyRight(stderr,argv[0]);
330 parse_common_args(&argc,argv,PCA_CAN_VIEW | PCA_CAN_TIME | PCA_BE_NICE,
331 NFILE,fnm,asize(pa),pa,asize(desc),desc,0,NULL,&oenv);
333 if (mult != -1)
334 fprintf(stderr,"Using %d for dihedral multiplicity rather than topology values\n",mult);
336 snew(xr,1);
337 init_rama(oenv,ftp2fn(efTRX,NFILE,fnm),
338 ftp2fn(efTPX,NFILE,fnm),xr,3);
339 top=read_top(ftp2fn(efTPX,NFILE,fnm),NULL);
341 /* Brute force malloc, may be too big... */
342 snew(dih,xr->ndih);
343 for(i=0; (i<xr->ndih); i++)
344 snew(dih[i],maxframes);
345 snew(time,maxframes);
347 fprintf(stderr,"\n");
348 nframes = 0;
349 while (new_data(xr)) {
350 for(i=0; (i<xr->ndih); i++) {
351 dd=xr->dih[i].ang*RAD2DEG;
352 while (dd < 0)
353 dd+=360;
354 while (dd > 360)
355 dd-=360;
356 dih[i][nframes]=dd;
358 time[nframes]=xr->t;
359 nframes++;
360 if (nframes > maxframes) {
361 maxframes += 1000;
362 for(i=0; (i<xr->ndih); i++)
363 srenew(dih[i],maxframes);
364 srenew(time,maxframes);
368 fprintf(stderr,"\nCalculated all dihedrals, now analysing...\n");
370 out=ftp2FILE(efOUT,NFILE,fnm,"w");
372 if (bSA) {
373 /* Cluster and structure analysis */
374 ana_cluster(out,xr,dih,time,top,nframes,mult);
376 else {
377 /* Analyse transitions... */
378 ana_trans(out,xr,dih,time,top,nframes,oenv);
380 ffclose(out);
382 thanx(stderr);
384 return 0;