void calc_principal_axes(t_topology * top, rvec * x, atom_id * index, int n, matrix axes, rvec inertia) { rvec xcm; sub_xcm(x,n,index,top->atoms.atom,xcm,FALSE); principal_comp(n,index,top->atoms.atom,x,axes,inertia); }
real calc_gyro(rvec x[], int gnx, atom_id index[], t_atom atom[], real tm, rvec gvec, rvec d, gmx_bool bQ, gmx_bool bRot, gmx_bool bMOI, matrix trans) { int i, ii, m; real gyro, dx2, m0, Itot; rvec comp; if (bRot) { principal_comp(gnx, index, atom, x, trans, d); Itot = norm(d); if (bMOI) { return Itot; } for (m = 0; (m < DIM); m++) { d[m] = std::sqrt(d[m]/tm); } #ifdef DEBUG pr_rvecs(stderr, 0, "trans", trans, DIM); #endif /* rotate_atoms(gnx,index,x,trans); */ } clear_rvec(comp); for (i = 0; (i < gnx); i++) { ii = index[i]; if (bQ) { m0 = std::abs(atom[ii].q); } else { m0 = atom[ii].m; } for (m = 0; (m < DIM); m++) { dx2 = x[ii][m]*x[ii][m]; comp[m] += dx2*m0; } } gyro = comp[XX]+comp[YY]+comp[ZZ]; for (m = 0; (m < DIM); m++) { gvec[m] = std::sqrt((gyro-comp[m])/tm); } return std::sqrt(gyro/tm); }
void orient_princ(t_atoms *atoms, int isize, atom_id *index, int natoms, rvec x[], rvec *v, rvec d) { int i, m; rvec xcm, prcomp; matrix trans; calc_xcm(x, isize, index, atoms->atom, xcm, FALSE); for (i = 0; i < natoms; i++) { rvec_dec(x[i], xcm); } principal_comp(isize, index, atoms->atom, x, trans, prcomp); if (d) { copy_rvec(prcomp, d); } /* Check whether this trans matrix mirrors the molecule */ if (det(trans) < 0) { for (m = 0; (m < DIM); m++) { trans[ZZ][m] = -trans[ZZ][m]; } } rotate_atoms(natoms, NULL, x, trans); if (v) { rotate_atoms(natoms, NULL, v, trans); } for (i = 0; i < natoms; i++) { rvec_inc(x[i], xcm); } }
int gmx_editconf(int argc, char *argv[]) { const char *desc[] = { "editconf converts generic structure format to [TT].gro[tt], [TT].g96[tt]", "or [TT].pdb[tt].", "[PAR]", "The box can be modified with options [TT]-box[tt], [TT]-d[tt] and", "[TT]-angles[tt]. Both [TT]-box[tt] and [TT]-d[tt]", "will center the system in the box, unless [TT]-noc[tt] is used.", "[PAR]", "Option [TT]-bt[tt] determines the box type: [TT]triclinic[tt] is a", "triclinic box, [TT]cubic[tt] is a rectangular box with all sides equal", "[TT]dodecahedron[tt] represents a rhombic dodecahedron and", "[TT]octahedron[tt] is a truncated octahedron.", "The last two are special cases of a triclinic box.", "The length of the three box vectors of the truncated octahedron is the", "shortest distance between two opposite hexagons.", "The volume of a dodecahedron is 0.71 and that of a truncated octahedron", "is 0.77 of that of a cubic box with the same periodic image distance.", "[PAR]", "Option [TT]-box[tt] requires only", "one value for a cubic box, dodecahedron and a truncated octahedron.", "[PAR]", "With [TT]-d[tt] and a [TT]triclinic[tt] box the size of the system in the x, y", "and z directions is used. With [TT]-d[tt] and [TT]cubic[tt],", "[TT]dodecahedron[tt] or [TT]octahedron[tt] boxes, the dimensions are set", "to the diameter of the system (largest distance between atoms) plus twice", "the specified distance.", "[PAR]", "Option [TT]-angles[tt] is only meaningful with option [TT]-box[tt] and", "a triclinic box and can not be used with option [TT]-d[tt].", "[PAR]", "When [TT]-n[tt] or [TT]-ndef[tt] is set, a group", "can be selected for calculating the size and the geometric center,", "otherwise the whole system is used.", "[PAR]", "[TT]-rotate[tt] rotates the coordinates and velocities.", "[PAR]", "[TT]-princ[tt] aligns the principal axes of the system along the", "coordinate axes, this may allow you to decrease the box volume,", "but beware that molecules can rotate significantly in a nanosecond.", "[PAR]", "Scaling is applied before any of the other operations are", "performed. Boxes and coordinates can be scaled to give a certain density (option", "[TT]-density[tt]). Note that this may be inaccurate in case a gro", "file is given as input. A special feature of the scaling option, when the", "factor -1 is given in one dimension, one obtains a mirror image,", "mirrored in one of the plains, when one uses -1 in three dimensions", "a point-mirror image is obtained.[PAR]", "Groups are selected after all operations have been applied.[PAR]", "Periodicity can be removed in a crude manner.", "It is important that the box sizes at the bottom of your input file", "are correct when the periodicity is to be removed.", "[PAR]", "When writing [TT].pdb[tt] files, B-factors can be", "added with the [TT]-bf[tt] option. B-factors are read", "from a file with with following format: first line states number of", "entries in the file, next lines state an index", "followed by a B-factor. The B-factors will be attached per residue", "unless an index is larger than the number of residues or unless the", "[TT]-atom[tt] option is set. Obviously, any type of numeric data can", "be added instead of B-factors. [TT]-legend[tt] will produce", "a row of CA atoms with B-factors ranging from the minimum to the", "maximum value found, effectively making a legend for viewing.", "[PAR]", "With the option -mead a special pdb (pqr) file for the MEAD electrostatics", "program (Poisson-Boltzmann solver) can be made. A further prerequisite", "is that the input file is a run input file.", "The B-factor field is then filled with the Van der Waals radius", "of the atoms while the occupancy field will hold the charge.", "[PAR]", "The option -grasp is similar, but it puts the charges in the B-factor", "and the radius in the occupancy.", "[PAR]", "Option [TT]-align[tt] allows alignment", "of the principal axis of a specified group against the given vector, ", "with an optional center of rotation specified by [TT]-aligncenter[tt].", "[PAR]", "Finally with option [TT]-label[tt] editconf can add a chain identifier", "to a pdb file, which can be useful for analysis with e.g. rasmol.", "[PAR]", "To convert a truncated octrahedron file produced by a package which uses", "a cubic box with the corners cut off (such as Gromos) use:[BR]", "[TT]editconf -f <in> -rotate 0 45 35.264 -bt o -box <veclen> -o <out>[tt][BR]", "where [TT]veclen[tt] is the size of the cubic box times sqrt(3)/2." }; const char *bugs[] = { "For complex molecules, the periodicity removal routine may break down, ", "in that case you can use trjconv." }; static real dist = 0.0, rbox = 0.0, to_diam = 0.0; static gmx_bool bNDEF = FALSE, bRMPBC = FALSE, bCenter = FALSE, bReadVDW = FALSE, bCONECT = FALSE; static gmx_bool peratom = FALSE, bLegend = FALSE, bOrient = FALSE, bMead = FALSE, bGrasp = FALSE, bSig56 = FALSE; static rvec scale = { 1, 1, 1 }, newbox = { 0, 0, 0 }, newang = { 90, 90, 90 }; static real rho = 1000.0, rvdw = 0.12; static rvec center = { 0, 0, 0 }, translation = { 0, 0, 0 }, rotangles = { 0, 0, 0 }, aligncenter = { 0, 0, 0 }, targetvec = { 0, 0, 0 }; static const char *btype[] = { NULL, "triclinic", "cubic", "dodecahedron", "octahedron", NULL }, *label = "A"; static rvec visbox = { 0, 0, 0 }; t_pargs pa[] = { { "-ndef", FALSE, etBOOL, { &bNDEF }, "Choose output from default index groups" }, { "-visbox", FALSE, etRVEC, { visbox }, "HIDDENVisualize a grid of boxes, -1 visualizes the 14 box images" }, { "-bt", FALSE, etENUM, { btype }, "Box type for -box and -d" }, { "-box", FALSE, etRVEC, { newbox }, "Box vector lengths (a,b,c)" }, { "-angles", FALSE, etRVEC, { newang }, "Angles between the box vectors (bc,ac,ab)" }, { "-d", FALSE, etREAL, { &dist }, "Distance between the solute and the box" }, { "-c", FALSE, etBOOL, { &bCenter }, "Center molecule in box (implied by -box and -d)" }, { "-center", FALSE, etRVEC, { center }, "Coordinates of geometrical center" }, { "-aligncenter", FALSE, etRVEC, { aligncenter }, "Center of rotation for alignment" }, { "-align", FALSE, etRVEC, { targetvec }, "Align to target vector" }, { "-translate", FALSE, etRVEC, { translation }, "Translation" }, { "-rotate", FALSE, etRVEC, { rotangles }, "Rotation around the X, Y and Z axes in degrees" }, { "-princ", FALSE, etBOOL, { &bOrient }, "Orient molecule(s) along their principal axes" }, { "-scale", FALSE, etRVEC, { scale }, "Scaling factor" }, { "-density", FALSE, etREAL, { &rho }, "Density (g/l) of the output box achieved by scaling" }, { "-pbc", FALSE, etBOOL, { &bRMPBC }, "Remove the periodicity (make molecule whole again)" }, { "-grasp", FALSE, etBOOL, { &bGrasp }, "Store the charge of the atom in the B-factor field and the radius of the atom in the occupancy field" }, { "-rvdw", FALSE, etREAL, { &rvdw }, "Default Van der Waals radius (in nm) if one can not be found in the database or if no parameters are present in the topology file" }, { "-sig56", FALSE, etREAL, { &bSig56 }, "Use rmin/2 (minimum in the Van der Waals potential) rather than sigma/2 " }, { "-vdwread", FALSE, etBOOL, { &bReadVDW }, "Read the Van der Waals radii from the file vdwradii.dat rather than computing the radii based on the force field" }, { "-atom", FALSE, etBOOL, { &peratom }, "Force B-factor attachment per atom" }, { "-legend", FALSE, etBOOL, { &bLegend }, "Make B-factor legend" }, { "-label", FALSE, etSTR, { &label }, "Add chain label for all residues" }, { "-conect", FALSE, etBOOL, { &bCONECT }, "Add CONECT records to a pdb file when written. Can only be done when a topology is present" } }; #define NPA asize(pa) FILE *out; const char *infile, *outfile; char title[STRLEN]; int outftp, inftp, natom, i, j, n_bfac, itype, ntype; double *bfac = NULL, c6, c12; int *bfac_nr = NULL; t_topology *top = NULL; t_atoms atoms; char *grpname, *sgrpname, *agrpname; int isize, ssize, tsize, asize; atom_id *index, *sindex, *tindex, *aindex; rvec *x, *v, gc, min, max, size; int ePBC; matrix box,rotmatrix,trans; rvec princd,tmpvec; gmx_bool bIndex, bSetSize, bSetAng, bCubic, bDist, bSetCenter, bAlign; gmx_bool bHaveV, bScale, bRho, bTranslate, bRotate, bCalcGeom, bCalcDiam; real xs, ys, zs, xcent, ycent, zcent, diam = 0, mass = 0, d, vdw; gmx_atomprop_t aps; gmx_conect conect; output_env_t oenv; t_filenm fnm[] = { { efSTX, "-f", NULL, ffREAD }, { efNDX, "-n", NULL, ffOPTRD }, { efSTO, NULL, NULL, ffOPTWR }, { efPQR, "-mead", "mead", ffOPTWR }, { efDAT, "-bf", "bfact", ffOPTRD } }; #define NFILE asize(fnm) CopyRight(stderr, argv[0]); parse_common_args(&argc, argv, PCA_CAN_VIEW, NFILE, fnm, NPA, pa, asize(desc), desc, asize(bugs), bugs, &oenv); bIndex = opt2bSet("-n", NFILE, fnm) || bNDEF; bMead = opt2bSet("-mead", NFILE, fnm); bSetSize = opt2parg_bSet("-box", NPA, pa); bSetAng = opt2parg_bSet("-angles", NPA, pa); bSetCenter = opt2parg_bSet("-center", NPA, pa); bDist = opt2parg_bSet("-d", NPA, pa); bAlign = opt2parg_bSet("-align", NPA, pa); /* Only automatically turn on centering without -noc */ if ((bDist || bSetSize || bSetCenter) && !opt2parg_bSet("-c", NPA, pa)) { bCenter = TRUE; } bScale = opt2parg_bSet("-scale", NPA, pa); bRho = opt2parg_bSet("-density", NPA, pa); bTranslate = opt2parg_bSet("-translate", NPA, pa); bRotate = opt2parg_bSet("-rotate", NPA, pa); if (bScale && bRho) fprintf(stderr, "WARNING: setting -density overrides -scale\n"); bScale = bScale || bRho; bCalcGeom = bCenter || bRotate || bOrient || bScale; bCalcDiam = btype[0][0] == 'c' || btype[0][0] == 'd' || btype[0][0] == 'o'; infile = ftp2fn(efSTX, NFILE, fnm); if (bMead) outfile = ftp2fn(efPQR, NFILE, fnm); else outfile = ftp2fn(efSTO, NFILE, fnm); outftp = fn2ftp(outfile); inftp = fn2ftp(infile); aps = gmx_atomprop_init(); if (bMead && bGrasp) { printf("Incompatible options -mead and -grasp. Turning off -grasp\n"); bGrasp = FALSE; } if (bGrasp && (outftp != efPDB)) gmx_fatal(FARGS, "Output file should be a .pdb file" " when using the -grasp option\n"); if ((bMead || bGrasp) && !((fn2ftp(infile) == efTPR) || (fn2ftp(infile) == efTPA) || (fn2ftp(infile) == efTPB))) gmx_fatal(FARGS,"Input file should be a .tp[abr] file" " when using the -mead option\n"); get_stx_coordnum(infile,&natom); init_t_atoms(&atoms,natom,TRUE); snew(x,natom); snew(v,natom); read_stx_conf(infile,title,&atoms,x,v,&ePBC,box); if (fn2ftp(infile) == efPDB) { get_pdb_atomnumber(&atoms,aps); } printf("Read %d atoms\n",atoms.nr); /* Get the element numbers if available in a pdb file */ if (fn2ftp(infile) == efPDB) get_pdb_atomnumber(&atoms,aps); if (ePBC != epbcNONE) { real vol = det(box); printf("Volume: %g nm^3, corresponds to roughly %d electrons\n", vol,100*((int)(vol*4.5))); } if (bMead || bGrasp || bCONECT) top = read_top(infile,NULL); if (bMead || bGrasp) { if (atoms.nr != top->atoms.nr) gmx_fatal(FARGS,"Atom numbers don't match (%d vs. %d)",atoms.nr,top->atoms.nr); snew(atoms.pdbinfo,top->atoms.nr); ntype = top->idef.atnr; for(i=0; (i<atoms.nr); i++) { /* Determine the Van der Waals radius from the force field */ if (bReadVDW) { if (!gmx_atomprop_query(aps,epropVDW, *top->atoms.resinfo[top->atoms.atom[i].resind].name, *top->atoms.atomname[i],&vdw)) vdw = rvdw; } else { itype = top->atoms.atom[i].type; c12 = top->idef.iparams[itype*ntype+itype].lj.c12; c6 = top->idef.iparams[itype*ntype+itype].lj.c6; if ((c6 != 0) && (c12 != 0)) { real sig6; if (bSig56) sig6 = 2*c12/c6; else sig6 = c12/c6; vdw = 0.5*pow(sig6,1.0/6.0); } else vdw = rvdw; } /* Factor of 10 for nm -> Angstroms */ vdw *= 10; if (bMead) { atoms.pdbinfo[i].occup = top->atoms.atom[i].q; atoms.pdbinfo[i].bfac = vdw; } else { atoms.pdbinfo[i].occup = vdw; atoms.pdbinfo[i].bfac = top->atoms.atom[i].q; } } } bHaveV=FALSE; for (i=0; (i<natom) && !bHaveV; i++) for (j=0; (j<DIM) && !bHaveV; j++) bHaveV=bHaveV || (v[i][j]!=0); printf("%selocities found\n",bHaveV?"V":"No v"); if (visbox[0] > 0) { if (bIndex) gmx_fatal(FARGS,"Sorry, can not visualize box with index groups"); if (outftp != efPDB) gmx_fatal(FARGS,"Sorry, can only visualize box with a pdb file"); } else if (visbox[0] == -1) visualize_images("images.pdb",ePBC,box); /* remove pbc */ if (bRMPBC) rm_gropbc(&atoms,x,box); if (bCalcGeom) { if (bIndex) { fprintf(stderr,"\nSelect a group for determining the system size:\n"); get_index(&atoms,ftp2fn_null(efNDX,NFILE,fnm), 1,&ssize,&sindex,&sgrpname); } else { ssize = atoms.nr; sindex = NULL; } diam=calc_geom(ssize,sindex,x,gc,min,max,bCalcDiam); rvec_sub(max, min, size); printf(" system size :%7.3f%7.3f%7.3f (nm)\n", size[XX], size[YY], size[ZZ]); if (bCalcDiam) printf(" diameter :%7.3f (nm)\n",diam); printf(" center :%7.3f%7.3f%7.3f (nm)\n", gc[XX], gc[YY], gc[ZZ]); printf(" box vectors :%7.3f%7.3f%7.3f (nm)\n", norm(box[XX]), norm(box[YY]), norm(box[ZZ])); printf(" box angles :%7.2f%7.2f%7.2f (degrees)\n", norm2(box[ZZ])==0 ? 0 : RAD2DEG*acos(cos_angle_no_table(box[YY],box[ZZ])), norm2(box[ZZ])==0 ? 0 : RAD2DEG*acos(cos_angle_no_table(box[XX],box[ZZ])), norm2(box[YY])==0 ? 0 : RAD2DEG*acos(cos_angle_no_table(box[XX],box[YY]))); printf(" box volume :%7.2f (nm^3)\n",det(box)); } if (bRho || bOrient || bAlign) mass = calc_mass(&atoms,!fn2bTPX(infile),aps); if (bOrient) { atom_id *index; char *grpnames; /* Get a group for principal component analysis */ fprintf(stderr,"\nSelect group for the determining the orientation\n"); get_index(&atoms,ftp2fn_null(efNDX,NFILE,fnm),1,&isize,&index,&grpnames); /* Orient the principal axes along the coordinate axes */ orient_princ(&atoms,isize,index,natom,x,bHaveV ? v : NULL, NULL); sfree(index); sfree(grpnames); } if ( bScale ) { /* scale coordinates and box */ if (bRho) { /* Compute scaling constant */ real vol,dens; vol = det(box); dens = (mass*AMU)/(vol*NANO*NANO*NANO); fprintf(stderr,"Volume of input %g (nm^3)\n",vol); fprintf(stderr,"Mass of input %g (a.m.u.)\n",mass); fprintf(stderr,"Density of input %g (g/l)\n",dens); if (vol==0 || mass==0) gmx_fatal(FARGS,"Cannot scale density with " "zero mass (%g) or volume (%g)\n",mass,vol); scale[XX] = scale[YY] = scale[ZZ] = pow(dens/rho,1.0/3.0); fprintf(stderr,"Scaling all box vectors by %g\n",scale[XX]); } scale_conf(atoms.nr,x,box,scale); } if (bAlign) { if (bIndex) { fprintf(stderr,"\nSelect a group that you want to align:\n"); get_index(&atoms,ftp2fn_null(efNDX,NFILE,fnm), 1,&asize,&aindex,&agrpname); } else { asize = atoms.nr; snew(aindex,asize); for (i=0;i<asize;i++) aindex[i]=i; } printf("Aligning %d atoms (out of %d) to %g %g %g, center of rotation %g %g %g\n",asize,natom, targetvec[XX],targetvec[YY],targetvec[ZZ], aligncenter[XX],aligncenter[YY],aligncenter[ZZ]); /*subtract out pivot point*/ for(i=0; i<asize; i++) rvec_dec(x[aindex[i]],aligncenter); /*now determine transform and rotate*/ /*will this work?*/ principal_comp(asize,aindex,atoms.atom,x, trans,princd); unitv(targetvec,targetvec); printf("Using %g %g %g as principal axis\n", trans[0][2],trans[1][2],trans[2][2]); tmpvec[XX]=trans[0][2]; tmpvec[YY]=trans[1][2]; tmpvec[ZZ]=trans[2][2]; calc_rotmatrix(tmpvec, targetvec, rotmatrix); /* rotmatrix finished */ for (i=0;i<asize;++i) { mvmul(rotmatrix,x[aindex[i]],tmpvec); copy_rvec(tmpvec,x[aindex[i]]); } /*add pivot point back*/ for(i=0; i<asize; i++) rvec_inc(x[aindex[i]],aligncenter); if (!bIndex) sfree(aindex); } if (bTranslate) { if (bIndex) { fprintf(stderr,"\nSelect a group that you want to translate:\n"); get_index(&atoms,ftp2fn_null(efNDX,NFILE,fnm), 1,&ssize,&sindex,&sgrpname); } else { ssize = atoms.nr; sindex = NULL; } printf("Translating %d atoms (out of %d) by %g %g %g nm\n",ssize,natom, translation[XX],translation[YY],translation[ZZ]); if (sindex) { for(i=0; i<ssize; i++) rvec_inc(x[sindex[i]],translation); } else { for(i=0; i<natom; i++) rvec_inc(x[i],translation); } } if (bRotate) { /* Rotate */ printf("Rotating %g, %g, %g degrees around the X, Y and Z axis respectively\n",rotangles[XX],rotangles[YY],rotangles[ZZ]); for(i=0; i<DIM; i++) rotangles[i] *= DEG2RAD; rotate_conf(natom,x,v,rotangles[XX],rotangles[YY],rotangles[ZZ]); } if (bCalcGeom) { /* recalc geometrical center and max and min coordinates and size */ calc_geom(ssize,sindex,x,gc,min,max,FALSE); rvec_sub(max, min, size); if (bScale || bOrient || bRotate) printf("new system size : %6.3f %6.3f %6.3f\n", size[XX],size[YY],size[ZZ]); } if (bSetSize || bDist || (btype[0][0]=='t' && bSetAng)) { ePBC = epbcXYZ; if (!(bSetSize || bDist)) for (i=0; i<DIM; i++) newbox[i] = norm(box[i]); clear_mat(box); /* calculate new boxsize */ switch(btype[0][0]){ case 't': if (bDist) for(i=0; i<DIM; i++) newbox[i] = size[i]+2*dist; if (!bSetAng) { box[XX][XX] = newbox[XX]; box[YY][YY] = newbox[YY]; box[ZZ][ZZ] = newbox[ZZ]; } else { matrix_convert(box,newbox,newang); } break; case 'c': case 'd': case 'o': if (bSetSize) d = newbox[0]; else d = diam+2*dist; if (btype[0][0] == 'c') for(i=0; i<DIM; i++) box[i][i] = d; else if (btype[0][0] == 'd') { box[XX][XX] = d; box[YY][YY] = d; box[ZZ][XX] = d/2; box[ZZ][YY] = d/2; box[ZZ][ZZ] = d*sqrt(2)/2; } else { box[XX][XX] = d; box[YY][XX] = d/3; box[YY][YY] = d*sqrt(2)*2/3; box[ZZ][XX] = -d/3; box[ZZ][YY] = d*sqrt(2)/3; box[ZZ][ZZ] = d*sqrt(6)/3; } break; } } /* calculate new coords for geometrical center */ if (!bSetCenter) calc_box_center(ecenterDEF,box,center); /* center molecule on 'center' */ if (bCenter) center_conf(natom,x,center,gc); /* print some */ if (bCalcGeom) { calc_geom(ssize,sindex,x, gc, min, max, FALSE); printf("new center :%7.3f%7.3f%7.3f (nm)\n",gc[XX],gc[YY],gc[ZZ]); } if (bOrient || bScale || bDist || bSetSize) { printf("new box vectors :%7.3f%7.3f%7.3f (nm)\n", norm(box[XX]), norm(box[YY]), norm(box[ZZ])); printf("new box angles :%7.2f%7.2f%7.2f (degrees)\n", norm2(box[ZZ])==0 ? 0 : RAD2DEG*acos(cos_angle_no_table(box[YY],box[ZZ])), norm2(box[ZZ])==0 ? 0 : RAD2DEG*acos(cos_angle_no_table(box[XX],box[ZZ])), norm2(box[YY])==0 ? 0 : RAD2DEG*acos(cos_angle_no_table(box[XX],box[YY]))); printf("new box volume :%7.2f (nm^3)\n",det(box)); } if (check_box(epbcXYZ,box)) printf("\nWARNING: %s\n",check_box(epbcXYZ,box)); if (bDist && btype[0][0]=='t') { if(TRICLINIC(box)) { printf("\nWARNING: Your box is triclinic with non-orthogonal axes. In this case, the\n" "distance from the solute to a box surface along the corresponding normal\n" "vector might be somewhat smaller than your specified value %f.\n" "You can check the actual value with g_mindist -pi\n",dist); } else { printf("\nWARNING: No boxtype specified - distance condition applied in each dimension.\n" "If the molecule rotates the actual distance will be smaller. You might want\n" "to use a cubic box instead, or why not try a dodecahedron today?\n"); } } if (bCONECT && (outftp == efPDB) && (inftp == efTPR)) conect = gmx_conect_generate(top); else conect = NULL; if (bIndex) { fprintf(stderr,"\nSelect a group for output:\n"); get_index(&atoms,opt2fn_null("-n",NFILE,fnm), 1,&isize,&index,&grpname); if (opt2parg_bSet("-label",NPA,pa)) { for(i=0; (i<atoms.nr); i++) atoms.resinfo[atoms.atom[i].resind].chainid=label[0]; } if (opt2bSet("-bf",NFILE,fnm) || bLegend) { gmx_fatal(FARGS,"Sorry, cannot do bfactors with an index group."); } if (outftp == efPDB) { out=ffopen(outfile,"w"); write_pdbfile_indexed(out,title,&atoms,x,ePBC,box,' ',1,isize,index,conect,TRUE); ffclose(out); } else { write_sto_conf_indexed(outfile,title,&atoms,x,bHaveV?v:NULL,ePBC,box,isize,index); } } else { if ((outftp == efPDB) || (outftp == efPQR)) { out=ffopen(outfile,"w"); if (bMead) { set_pdb_wide_format(TRUE); fprintf(out,"REMARK " "The B-factors in this file hold atomic radii\n"); fprintf(out,"REMARK " "The occupancy in this file hold atomic charges\n"); } else if (bGrasp) { fprintf(out,"GRASP PDB FILE\nFORMAT NUMBER=1\n"); fprintf(out,"REMARK " "The B-factors in this file hold atomic charges\n"); fprintf(out,"REMARK " "The occupancy in this file hold atomic radii\n"); } else if (opt2bSet("-bf",NFILE,fnm)) { read_bfac(opt2fn("-bf",NFILE,fnm),&n_bfac,&bfac,&bfac_nr); set_pdb_conf_bfac(atoms.nr,atoms.nres,&atoms, n_bfac,bfac,bfac_nr,peratom); } if (opt2parg_bSet("-label",NPA,pa)) { for(i=0; (i<atoms.nr); i++) atoms.resinfo[atoms.atom[i].resind].chainid=label[0]; } write_pdbfile(out,title,&atoms,x,ePBC,box,' ',-1,conect,TRUE); if (bLegend) pdb_legend(out,atoms.nr,atoms.nres,&atoms,x); if (visbox[0] > 0) visualize_box(out,bLegend ? atoms.nr+12 : atoms.nr, bLegend? atoms.nres=12 : atoms.nres,box,visbox); ffclose(out); } else write_sto_conf(outfile,title,&atoms,x,bHaveV?v:NULL,ePBC,box); } gmx_atomprop_destroy(aps); do_view(oenv,outfile,NULL); thanx(stderr); return 0; }