Parallel vs. sequentiual code: I get binary identical result (apart from comment...
[gromacs/qmmm-gamess-us.git] / src / tools / gmx_density.c
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35 #ifdef HAVE_CONFIG_H
36 #include <config.h>
37 #endif
38 #include <math.h>
39 #include <ctype.h>
41 #include "sysstuff.h"
42 #include "string.h"
43 #include "string2.h"
44 #include "typedefs.h"
45 #include "smalloc.h"
46 #include "macros.h"
47 #include "gstat.h"
48 #include "vec.h"
49 #include "xvgr.h"
50 #include "pbc.h"
51 #include "copyrite.h"
52 #include "futil.h"
53 #include "statutil.h"
54 #include "index.h"
55 #include "tpxio.h"
56 #include "physics.h"
57 #include "gmx_ana.h"
59 typedef struct {
60 char *atomname;
61 int nr_el;
62 } t_electron;
64 /****************************************************************************/
65 /* This program calculates the partial density across the box. */
66 /* Peter Tieleman, Mei 1995 */
67 /****************************************************************************/
69 /* used for sorting the list */
70 int compare(void *a, void *b)
72 t_electron *tmp1,*tmp2;
73 tmp1 = (t_electron *)a; tmp2 = (t_electron *)b;
75 return strcmp(tmp1->atomname,tmp2->atomname);
78 int get_electrons(t_electron **eltab, const char *fn)
80 char buffer[256]; /* to read in a line */
81 char tempname[80]; /* buffer to hold name */
82 int tempnr;
84 FILE *in;
85 int nr; /* number of atomstypes to read */
86 int i;
88 if ( !(in = ffopen(fn,"r")))
89 gmx_fatal(FARGS,"Couldn't open %s. Exiting.\n",fn);
91 if(NULL==fgets(buffer, 255, in))
93 gmx_fatal(FARGS,"Error reading from file %s",fn);
96 if (sscanf(buffer, "%d", &nr) != 1)
97 gmx_fatal(FARGS,"Invalid number of atomtypes in datafile\n");
99 snew(*eltab,nr);
101 for (i=0;i<nr;i++) {
102 if (fgets(buffer, 255, in) == NULL)
103 gmx_fatal(FARGS,"reading datafile. Check your datafile.\n");
104 if (sscanf(buffer, "%s = %d", tempname, &tempnr) != 2)
105 gmx_fatal(FARGS,"Invalid line in datafile at line %d\n",i+1);
106 (*eltab)[i].nr_el = tempnr;
107 (*eltab)[i].atomname = strdup(tempname);
109 ffclose(in);
111 /* sort the list */
112 fprintf(stderr,"Sorting list..\n");
113 qsort ((void*)*eltab, nr, sizeof(t_electron),
114 (int(*)(const void*, const void*))compare);
116 return nr;
119 void center_coords(t_atoms *atoms,matrix box,rvec x0[],int axis)
121 int i,m;
122 real tmass,mm;
123 rvec com,shift,box_center;
125 tmass = 0;
126 clear_rvec(com);
127 for(i=0; (i<atoms->nr); i++) {
128 mm = atoms->atom[i].m;
129 tmass += mm;
130 for(m=0; (m<DIM); m++)
131 com[m] += mm*x0[i][m];
133 for(m=0; (m<DIM); m++)
134 com[m] /= tmass;
135 calc_box_center(ecenterDEF,box,box_center);
136 rvec_sub(box_center,com,shift);
137 shift[axis] -= box_center[axis];
139 for(i=0; (i<atoms->nr); i++)
140 rvec_dec(x0[i],shift);
143 void calc_electron_density(const char *fn, atom_id **index, int gnx[],
144 real ***slDensity, int *nslices, t_topology *top,
145 int ePBC,
146 int axis, int nr_grps, real *slWidth,
147 t_electron eltab[], int nr,bool bCenter,
148 const output_env_t oenv)
150 rvec *x0; /* coordinates without pbc */
151 matrix box; /* box (3x3) */
152 int natoms, /* nr. atoms in trj */
153 status,
154 i,n, /* loop indices */
155 ax1=0, ax2=0,
156 nr_frames = 0, /* number of frames */
157 slice; /* current slice */
158 t_electron *found; /* found by bsearch */
159 t_electron sought; /* thingie thought by bsearch */
161 real t,
164 switch(axis) {
165 case 0:
166 ax1 = 1; ax2 = 2;
167 break;
168 case 1:
169 ax1 = 0; ax2 = 2;
170 break;
171 case 2:
172 ax1 = 0; ax2 = 1;
173 break;
174 default:
175 gmx_fatal(FARGS,"Invalid axes. Terminating\n");
178 if ((natoms = read_first_x(oenv,&status,fn,&t,&x0,box)) == 0)
179 gmx_fatal(FARGS,"Could not read coordinates from statusfile\n");
181 if (! *nslices)
182 *nslices = (int)(box[axis][axis] * 10); /* default value */
183 fprintf(stderr,"\nDividing the box in %d slices\n",*nslices);
185 snew(*slDensity, nr_grps);
186 for (i = 0; i < nr_grps; i++)
187 snew((*slDensity)[i], *nslices);
189 /*********** Start processing trajectory ***********/
190 do {
191 rm_pbc(&(top->idef),ePBC,top->atoms.nr,box,x0,x0);
193 if (bCenter)
194 center_coords(&top->atoms,box,x0,axis);
196 *slWidth = box[axis][axis]/(*nslices);
197 for (n = 0; n < nr_grps; n++) {
198 for (i = 0; i < gnx[n]; i++) { /* loop over all atoms in index file */
199 z = x0[index[n][i]][axis];
200 while (z < 0)
201 z += box[axis][axis];
202 while (z > box[axis][axis])
203 z -= box[axis][axis];
205 /* determine which slice atom is in */
206 slice = (z / (*slWidth));
207 sought.nr_el = 0;
208 sought.atomname = strdup(*(top->atoms.atomname[index[n][i]]));
210 /* now find the number of electrons. This is not efficient. */
211 found = (t_electron *)
212 bsearch((const void *)&sought,
213 (const void *)eltab, nr, sizeof(t_electron),
214 (int(*)(const void*, const void*))compare);
216 if (found == NULL)
217 fprintf(stderr,"Couldn't find %s. Add it to the .dat file\n",
218 *(top->atoms.atomname[index[n][i]]));
219 else
220 (*slDensity)[n][slice] += found->nr_el -
221 top->atoms.atom[index[n][i]].q;
222 free(sought.atomname);
225 nr_frames++;
226 } while (read_next_x(oenv,status,&t,natoms,x0,box));
228 /*********** done with status file **********/
229 close_trj(status);
231 /* slDensity now contains the total number of electrons per slice, summed
232 over all frames. Now divide by nr_frames and volume of slice
235 fprintf(stderr,"\nRead %d frames from trajectory. Counting electrons\n",
236 nr_frames);
238 for (n =0; n < nr_grps; n++) {
239 for (i = 0; i < *nslices; i++)
240 (*slDensity)[n][i] = (*slDensity)[n][i] * (*nslices) /
241 ( nr_frames * box[axis][axis] * box[ax1][ax1] * box[ax2][ax2]);
244 sfree(x0); /* free memory used by coordinate array */
247 void calc_density(const char *fn, atom_id **index, int gnx[],
248 real ***slDensity, int *nslices, t_topology *top, int ePBC,
249 int axis, int nr_grps, real *slWidth, bool bCenter,
250 const output_env_t oenv)
252 rvec *x0; /* coordinates without pbc */
253 matrix box; /* box (3x3) */
254 int natoms, /* nr. atoms in trj */
255 status,
256 **slCount, /* nr. of atoms in one slice for a group */
257 i,j,n, /* loop indices */
258 teller = 0,
259 ax1=0, ax2=0,
260 nr_frames = 0, /* number of frames */
261 slice; /* current slice */
262 real t,
264 char *buf; /* for tmp. keeping atomname */
266 switch(axis) {
267 case 0:
268 ax1 = 1; ax2 = 2;
269 break;
270 case 1:
271 ax1 = 0; ax2 = 2;
272 break;
273 case 2:
274 ax1 = 0; ax2 = 1;
275 break;
276 default:
277 gmx_fatal(FARGS,"Invalid axes. Terminating\n");
280 if ((natoms = read_first_x(oenv,&status,fn,&t,&x0,box)) == 0)
281 gmx_fatal(FARGS,"Could not read coordinates from statusfile\n");
283 if (! *nslices) {
284 *nslices = (int)(box[axis][axis] * 10); /* default value */
285 fprintf(stderr,"\nDividing the box in %d slices\n",*nslices);
288 snew(*slDensity, nr_grps);
289 for (i = 0; i < nr_grps; i++)
290 snew((*slDensity)[i], *nslices);
292 /*********** Start processing trajectory ***********/
293 do {
294 rm_pbc(&(top->idef),ePBC,top->atoms.nr,box,x0,x0);
296 if (bCenter)
297 center_coords(&top->atoms,box,x0,axis);
299 *slWidth = box[axis][axis]/(*nslices);
300 teller++;
302 for (n = 0; n < nr_grps; n++) {
303 for (i = 0; i < gnx[n]; i++) { /* loop over all atoms in index file */
304 z = x0[index[n][i]][axis];
305 while (z < 0)
306 z += box[axis][axis];
307 while (z > box[axis][axis])
308 z -= box[axis][axis];
310 /* determine which slice atom is in */
311 slice = (int)(z / (*slWidth));
312 (*slDensity)[n][slice] += top->atoms.atom[index[n][i]].m;
316 nr_frames++;
317 } while (read_next_x(oenv,status,&t,natoms,x0,box));
319 /*********** done with status file **********/
320 close_trj(status);
322 /* slDensity now contains the total mass per slice, summed over all
323 frames. Now divide by nr_frames and volume of slice
326 fprintf(stderr,"\nRead %d frames from trajectory. Calculating density\n",
327 nr_frames);
329 for (n =0; n < nr_grps; n++) {
330 for (i = 0; i < *nslices; i++) {
331 (*slDensity)[n][i] = (*slDensity)[n][i] * (*nslices) /
332 (nr_frames * box[axis][axis] * box[ax1][ax1] * box[ax2][ax2]);
336 sfree(x0); /* free memory used by coordinate array */
339 void plot_density(real *slDensity[], const char *afile, int nslices,
340 int nr_grps, char *grpname[], real slWidth,
341 const char **dens_opt,
342 bool bSymmetrize, const output_env_t oenv)
344 FILE *den;
345 const char *ylabel=NULL;
346 int slice, n;
347 real ddd;
349 switch (dens_opt[0][0]) {
350 case 'm': ylabel = "Density (kg m\\S-3\\N)"; break;
351 case 'n': ylabel = "Number density (nm\\S-3\\N)"; break;
352 case 'c': ylabel = "Charge density (e nm\\S-3\\N)"; break;
353 case 'e': ylabel = "Electron density (e nm\\S-3\\N)"; break;
356 den = xvgropen(afile, "Partial densities", "Box (nm)", ylabel,oenv);
358 xvgr_legend(den,nr_grps,grpname,oenv);
360 for (slice = 0; (slice < nslices); slice++) {
361 fprintf(den,"%12g ", slice * slWidth);
362 for (n = 0; (n < nr_grps); n++) {
363 if (bSymmetrize)
364 ddd = (slDensity[n][slice]+slDensity[n][nslices-slice-1])*0.5;
365 else
366 ddd = slDensity[n][slice];
367 if (dens_opt[0][0] == 'm')
368 fprintf(den," %12g", ddd*AMU/(NANO*NANO*NANO));
369 else
370 fprintf(den," %12g", ddd);
372 fprintf(den,"\n");
375 ffclose(den);
378 int gmx_density(int argc,char *argv[])
380 const char *desc[] = {
381 "Compute partial densities across the box, using an index file. Densities",
382 "in kg/m^3, number densities or electron densities can be",
383 "calculated. For electron densities, a file describing the number of",
384 "electrons for each type of atom should be provided using [TT]-ei[tt].",
385 "It should look like:[BR]",
386 " 2[BR]",
387 " atomname = nrelectrons[BR]",
388 " atomname = nrelectrons[BR]",
389 "The first line contains the number of lines to read from the file.",
390 "There should be one line for each unique atom name in your system.",
391 "The number of electrons for each atom is modified by its atomic",
392 "partial charge."
395 output_env_t oenv;
396 static const char *dens_opt[] =
397 { NULL, "mass", "number", "charge", "electron", NULL };
398 static int axis = 2; /* normal to memb. default z */
399 static const char *axtitle="Z";
400 static int nslices = 50; /* nr of slices defined */
401 static int ngrps = 1; /* nr. of groups */
402 static bool bSymmetrize=FALSE;
403 static bool bCenter=FALSE;
404 t_pargs pa[] = {
405 { "-d", FALSE, etSTR, {&axtitle},
406 "Take the normal on the membrane in direction X, Y or Z." },
407 { "-sl", FALSE, etINT, {&nslices},
408 "Divide the box in #nr slices." },
409 { "-dens", FALSE, etENUM, {dens_opt},
410 "Density"},
411 { "-ng", FALSE, etINT, {&ngrps},
412 "Number of groups to compute densities of" },
413 { "-symm", FALSE, etBOOL, {&bSymmetrize},
414 "Symmetrize the density along the axis, with respect to the center. Useful for bilayers." },
415 { "-center", FALSE, etBOOL, {&bCenter},
416 "Shift the center of mass along the axis to zero. This means if your axis is Z and your box is bX, bY, bZ, the center of mass will be at bX/2, bY/2, 0."}
419 const char *bugs[] = {
420 "When calculating electron densities, atomnames are used instead of types. This is bad.",
423 real **density; /* density per slice */
424 real slWidth; /* width of one slice */
425 char **grpname; /* groupnames */
426 int nr_electrons; /* nr. electrons */
427 int *ngx; /* sizes of groups */
428 t_electron *el_tab; /* tabel with nr. of electrons*/
429 t_topology *top; /* topology */
430 int ePBC;
431 atom_id **index; /* indices for all groups */
432 int i;
434 t_filenm fnm[] = { /* files for g_density */
435 { efTRX, "-f", NULL, ffREAD },
436 { efNDX, NULL, NULL, ffOPTRD },
437 { efTPX, NULL, NULL, ffREAD },
438 { efDAT, "-ei", "electrons", ffOPTRD }, /* file with nr. of electrons */
439 { efXVG,"-o","density",ffWRITE },
442 #define NFILE asize(fnm)
444 CopyRight(stderr,argv[0]);
446 parse_common_args(&argc,argv,PCA_CAN_VIEW | PCA_CAN_TIME | PCA_BE_NICE,
447 NFILE,fnm,asize(pa),pa,asize(desc),desc,asize(bugs),bugs,
448 &oenv);
450 if (bSymmetrize && !bCenter) {
451 fprintf(stderr,"Can not symmetrize without centering. Turning on -center\n");
452 bCenter = TRUE;
454 /* Calculate axis */
455 axis = toupper(axtitle[0]) - 'X';
457 top = read_top(ftp2fn(efTPX,NFILE,fnm),&ePBC); /* read topology file */
458 if (dens_opt[0][0] == 'n') {
459 for(i=0; (i<top->atoms.nr); i++)
460 top->atoms.atom[i].m = 1;
461 } else if (dens_opt[0][0] == 'c') {
462 for(i=0; (i<top->atoms.nr); i++)
463 top->atoms.atom[i].m = top->atoms.atom[i].q;
466 snew(grpname,ngrps);
467 snew(index,ngrps);
468 snew(ngx,ngrps);
470 get_index(&top->atoms,ftp2fn_null(efNDX,NFILE,fnm),ngrps,ngx,index,grpname);
472 if (dens_opt[0][0] == 'e') {
473 nr_electrons = get_electrons(&el_tab,ftp2fn(efDAT,NFILE,fnm));
474 fprintf(stderr,"Read %d atomtypes from datafile\n", nr_electrons);
476 calc_electron_density(ftp2fn(efTRX,NFILE,fnm),index, ngx, &density,
477 &nslices, top, ePBC, axis, ngrps, &slWidth, el_tab,
478 nr_electrons,bCenter,oenv);
479 } else
480 calc_density(ftp2fn(efTRX,NFILE,fnm),index, ngx, &density, &nslices, top,
481 ePBC, axis, ngrps, &slWidth, bCenter,oenv);
483 plot_density(density, opt2fn("-o",NFILE,fnm),
484 nslices, ngrps, grpname, slWidth, dens_opt,
485 bSymmetrize,oenv);
487 do_view(oenv,opt2fn("-o",NFILE,fnm), "-nxy"); /* view xvgr file */
488 thanx(stderr);
489 return 0;