/* * reax.c * * A new auto-indexer * * (c) 2011 Thomas White * * Part of CrystFEL - crystallography with a FEL * */ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #include #include #include #include #include #include #include #include "image.h" #include "utils.h" #include "peaks.h" #include "cell.h" #include "index.h" #include "index-priv.h" struct dvec { double x; double y; double z; double th; double ph; }; struct reax_private { IndexingPrivate base; struct dvec *directions; int n_dir; double angular_inc; double *fft_in; fftw_complex *fft_out; fftw_plan plan; int nel; fftw_complex *r_fft_in; fftw_complex *r_fft_out; fftw_plan r_plan; int ch; int cw; }; static double check_dir(struct dvec *dir, ImageFeatureList *flist, int nel, double pmax, double *fft_in, fftw_complex *fft_out, fftw_plan plan, int smin, int smax, const char *rg, struct detector *det) { int n, i; double tot; for ( i=0; ifs, f->ss); assert(p != NULL); if ( p->rigid_group != rg ) continue; } val = f->rx*dir->x + f->ry*dir->y + f->rz*dir->z; idx = nel/2 + nel*val/(2.0*pmax); fft_in[idx]++; } fftw_execute_dft_r2c(plan, fft_in, fft_out); tot = 0.0; for ( i=smin; i<=smax; i++ ) { double re, im; re = fft_out[i][0]; im = fft_out[i][1]; tot += sqrt(re*re + im*im); } return tot; } /* Refine a direct space vector. From Clegg (1984) */ static double iterate_refine_vector(double *x, double *y, double *z, ImageFeatureList *flist) { int fi, n, err; gsl_matrix *C; gsl_vector *A; gsl_vector *t; gsl_matrix *s_vec; gsl_vector *s_val; double dtmax; A = gsl_vector_calloc(3); C = gsl_matrix_calloc(3, 3); n = image_feature_count(flist); fesetround(1); for ( fi=0; firx*(*x) + f->ry*(*y) + f->rz*(*z); /* Sorry ... */ kn = nearbyint(kno); if ( kn - kno > 0.3 ) continue; xv[0] = f->rx; xv[1] = f->ry; xv[2] = f->rz; for ( i=0; i<3; i++ ) { val = gsl_vector_get(A, i); gsl_vector_set(A, i, val+xv[i]*kn); for ( j=0; j<3; j++ ) { val = gsl_matrix_get(C, i, j); gsl_matrix_set(C, i, j, val+xv[i]*xv[j]); } } } s_val = gsl_vector_calloc(3); s_vec = gsl_matrix_calloc(3, 3); err = gsl_linalg_SV_decomp_jacobi(C, s_vec, s_val); if ( err ) { ERROR("SVD failed: %s\n", gsl_strerror(err)); gsl_matrix_free(s_vec); gsl_vector_free(s_val); gsl_matrix_free(C); gsl_vector_free(A); return 0.0; } t = gsl_vector_calloc(3); err = gsl_linalg_SV_solve(C, s_vec, s_val, A, t); if ( err ) { ERROR("Matrix solution failed: %s\n", gsl_strerror(err)); gsl_matrix_free(s_vec); gsl_vector_free(s_val); gsl_matrix_free(C); gsl_vector_free(A); gsl_vector_free(t); return 0.0; } gsl_matrix_free(s_vec); gsl_vector_free(s_val); dtmax = fabs(*x - gsl_vector_get(t, 0)); dtmax += fabs(*y - gsl_vector_get(t, 1)); dtmax += fabs(*z - gsl_vector_get(t, 2)); *x = gsl_vector_get(t, 0); *y = gsl_vector_get(t, 1); *z = gsl_vector_get(t, 2); gsl_matrix_free(C); gsl_vector_free(A); return dtmax; } static void refine_cell(struct image *image, UnitCell *cell, ImageFeatureList *flist) { double ax, ay, az; double bx, by, bz; double cx, cy, cz; int i; double sm; cell_get_cartesian(cell, &ax, &ay, &az, &bx, &by, &bz, &cx, &cy, &cz); i = 0; do { sm = iterate_refine_vector(&ax, &ay, &az, flist); sm += iterate_refine_vector(&bx, &by, &bz, flist); sm += iterate_refine_vector(&cx, &cy, &cz, flist); i++; } while ( (sm > 0.001e-9) && (i<10) ); cell_set_cartesian(cell, ax, ay, az, bx, by, bz, cx, cy, cz); if ( i == 10 ) { cell_free(image->indexed_cell); image->indexed_cell = NULL; } } static void fine_search(struct reax_private *p, ImageFeatureList *flist, int nel, double pmax, double *fft_in, fftw_complex *fft_out, fftw_plan plan, int smin, int smax, double th_cen, double ph_cen, double *x, double *y, double *z) { double fom = 0.0; double th, ph; double inc; struct dvec dir; int i, s; double max, modv; inc = p->angular_inc / 100.0; for ( th=th_cen-p->angular_inc; th<=th_cen+p->angular_inc; th+=inc ) { for ( ph=ph_cen-p->angular_inc; ph<=ph_cen+p->angular_inc; ph+=inc ) { double new_fom; dir.x = cos(ph) * sin(th); dir.y = sin(ph) * sin(th); dir.z = cos(th); new_fom = check_dir(&dir, flist, nel, pmax, fft_in, fft_out, plan, smin, smax, NULL, NULL); if ( new_fom > fom ) { fom = new_fom; *x = dir.x; *y = dir.y; *z = dir.z; } } } s = -1; max = 0.0; for ( i=smin; i<=smax; i++ ) { double re, im, m; re = fft_out[i][0]; im = fft_out[i][1]; m = sqrt(re*re + im*im); if ( m > max ) { max = m; s = i; } } assert(s>0); modv = (double)s / (2.0*pmax); *x *= modv; *y *= modv; *z *= modv; } static double get_model_phase(double x, double y, double z, ImageFeatureList *f, int nel, double pmax, double *fft_in, fftw_complex *fft_out, fftw_plan plan, int smin, int smax, const char *rg, struct detector *det) { struct dvec dir; int s, i; double max; double re, im; dir.x = x; dir.y = y; dir.z = z; check_dir(&dir, f, nel, pmax, fft_in,fft_out, plan, smin, smax, rg, det); s = -1; max = 0.0; for ( i=smin; i<=smax; i++ ) { double re, im, m; re = fft_out[i][0]; im = fft_out[i][1]; m = sqrt(re*re + im*im); if ( m > max ) { max = m; s = i; } } re = fft_out[s][0]; im = fft_out[s][1]; return atan2(im, re); } static void refine_rigid_group(struct image *image, UnitCell *cell, const char *rg, int nel, double pmax, double *fft_in, fftw_complex *fft_out, fftw_plan plan, int smin, int smax, struct detector *det, struct reax_private *pr) { double ax, ay, az, ma; double bx, by, bz, mb; double cx, cy, cz, mc; double pha, phb, phc; struct panel *p; int i, j; fftw_complex *r_fft_in; fftw_complex *r_fft_out; double m2m; signed int aix, aiy; signed int bix, biy; signed int cix, ciy; double max; int max_i, max_j; cell_get_cartesian(cell, &ax, &ay, &az, &bx, &by, &bz, &cx, &cy, &cz); ma = modulus(ax, ay, az); mb = modulus(bx, by, bz); mc = modulus(cx, cy, cz); pha = get_model_phase(ax/ma, ay/ma, az/ma, image->features, nel, pmax, fft_in, fft_out, plan, smin, smax, rg, det); phb = get_model_phase(bx/mb, by/mb, bz/mb, image->features, nel, pmax, fft_in, fft_out, plan, smin, smax, rg, det); phc = get_model_phase(cx/mc, cy/mc, cz/mc, image->features, nel, pmax, fft_in, fft_out, plan, smin, smax, rg, det); for ( i=0; in_panels; i++ ) { if ( det->panels[i].rigid_group == rg ) { p = &det->panels[i]; break; } } r_fft_in = fftw_malloc(pr->cw*pr->ch*sizeof(fftw_complex)); r_fft_out = fftw_malloc(pr->cw*pr->ch*sizeof(fftw_complex)); for ( i=0; icw; i++ ) { for ( j=0; jch; j++ ) { r_fft_in[i+pr->cw*j][0] = 0.0; r_fft_in[i+pr->cw*j][1] = 0.0; } } ma = modulus(ax, ay, 0.0); mb = modulus(bx, by, 0.0); mc = modulus(cx, cy, 0.0); m2m = ma; if ( mb > m2m ) m2m = mb; if ( mc > m2m ) m2m = mc; aix = (pr->cw/2)*ax/m2m; aiy = (pr->ch/2)*ay/m2m; bix = (pr->cw/2)*bx/m2m; biy = (pr->ch/2)*by/m2m; cix = (pr->cw/2)*cx/m2m; ciy = (pr->ch/2)*cy/m2m; if ( aix < 0 ) aix += pr->cw/2; if ( bix < 0 ) bix += pr->cw/2; if ( cix < 0 ) cix += pr->cw/2; if ( aiy < 0 ) aiy += pr->ch/2; if ( biy < 0 ) biy += pr->ch/2; if ( ciy < 0 ) ciy += pr->ch/2; r_fft_in[aix + pr->cw*aiy][0] = cos(pha); r_fft_in[aix + pr->cw*aiy][1] = sin(pha); r_fft_in[pr->cw-aix + pr->cw*(pr->ch-aiy)][0] = cos(pha); r_fft_in[pr->cw-aix + pr->cw*(pr->ch-aiy)][1] = -sin(pha); r_fft_in[bix + pr->cw*biy][0] = cos(phb); r_fft_in[bix + pr->cw*biy][1] = sin(phb); r_fft_in[pr->cw-bix + pr->cw*(pr->ch-biy)][0] = cos(phb); r_fft_in[pr->cw-bix + pr->cw*(pr->ch-biy)][1] = -sin(phb); r_fft_in[cix + pr->cw*ciy][0] = cos(phc); r_fft_in[cix + pr->cw*ciy][1] = sin(phc); r_fft_in[pr->cw-cix + pr->cw*(pr->ch-ciy)][0] = cos(phc); r_fft_in[pr->cw-cix + pr->cw*(pr->ch-ciy)][1] = -sin(phc); const int tidx = 1; r_fft_in[tidx][0] = 1.0; r_fft_in[tidx][1] = 0.0; // STATUS("%i %i\n", aix, aiy); // STATUS("%i %i\n", bix, biy); // STATUS("%i %i\n", cix, ciy); fftw_execute_dft(pr->r_plan, r_fft_in, r_fft_out); // max = 0.0; // FILE *fh = fopen("centering.dat", "w"); // for ( i=0; icw; i++ ) { // for ( j=0; jch; j++ ) { // // double re, im, am, ph; // // re = r_fft_out[i + pr->cw*j][0]; // im = r_fft_out[i + pr->cw*j][1]; // am = sqrt(re*re + im*im); // ph = atan2(im, re); // // if ( am > max ) { // max = am; // max_i = i; // max_j = j; // } // // fprintf(fh, "%f ", am); // // } // fprintf(fh, "\n"); // } // STATUS("Max at %i, %i\n", max_i, max_j); // fclose(fh); // exit(1); // STATUS("Offsets for '%s': %.2f, %.2f pixels\n", rg, dx, dy); } static void refine_all_rigid_groups(struct image *image, UnitCell *cell, int nel, double pmax, double *fft_in, fftw_complex *fft_out, fftw_plan plan, int smin, int smax, struct detector *det, struct reax_private *p) { int i; for ( i=0; idet->num_rigid_groups; i++ ) { refine_rigid_group(image, cell, image->det->rigid_groups[i], nel, pmax, fft_in, fft_out, plan, smin, smax, det, p); } } void reax_index(IndexingPrivate *pp, struct image *image, UnitCell *cell) { int i; struct reax_private *p; double fom; double ax, ay, az; double bx, by, bz; double cx, cy, cz; double mod_a, mod_b, mod_c; double al, be, ga; double th, ph; double *fft_in; fftw_complex *fft_out; int smin, smax; double amin, amax; double bmin, bmax; double cmin, cmax; double pmax; int n; const double ltol = 5.0; /* Direct space axis length * tolerance in percent */ const double angtol = deg2rad(1.5); /* Direct space angle tolerance * in radians */ assert(pp->indm == INDEXING_REAX); p = (struct reax_private *)pp; fft_in = fftw_malloc(p->nel*sizeof(double)); fft_out = fftw_malloc((p->nel/2 + 1)*sizeof(fftw_complex)); cell_get_cartesian(cell, &ax, &ay, &az, &bx, &by, &bz, &cx, &cy, &cz); mod_a = modulus(ax, ay, az); amin = mod_a * (1.0-ltol/100.0); amax = mod_a * (1.0+ltol/100.0); mod_b = modulus(bx, by, bz); bmin = mod_b * (1.0-ltol/100.0); bmax = mod_b * (1.0+ltol/100.0); mod_c = modulus(cx, cy, cz); cmin = mod_c * (1.0-ltol/100.0); cmax = mod_c * (1.0+ltol/100.0); al = angle_between(bx, by, bz, cx, cy, cz); be = angle_between(ax, ay, az, cx, cy, cz); ga = angle_between(ax, ay, az, bx, by, bz); pmax = 0.0; n = image_feature_count(image->features); for ( i=0; ifeatures, i); if ( f == NULL ) continue; val = modulus(f->rx, f->ry, f->rz); if ( val > pmax ) pmax = val; } /* Sanity check */ if ( pmax < 1e4 ) return; /* Search for a */ smin = 2.0*pmax * amin; smax = 2.0*pmax * amax; fom = 0.0; th = 0.0; ph = 0.0; for ( i=0; in_dir; i++ ) { double new_fom; new_fom = check_dir(&p->directions[i], image->features, p->nel, pmax, fft_in, fft_out, p->plan, smin, smax, NULL, NULL); if ( new_fom > fom ) { fom = new_fom; th = p->directions[i].th; ph = p->directions[i].ph; } } fine_search(p, image->features, p->nel, pmax, fft_in, fft_out, p->plan, smin, smax, th, ph, &ax, &ay, &az); /* Search for b */ smin = 2.0*pmax * bmin; smax = 2.0*pmax * bmax; fom = 0.0; th = 0.0; ph = 0.0; for ( i=0; in_dir; i++ ) { double new_fom, ang; ang = angle_between(p->directions[i].x, p->directions[i].y, p->directions[i].z, ax, ay, az); if ( fabs(ang-ga) > angtol ) continue; new_fom = check_dir(&p->directions[i], image->features, p->nel, pmax, fft_in, fft_out, p->plan, smin, smax, NULL, NULL); if ( new_fom > fom ) { fom = new_fom; th = p->directions[i].th; ph = p->directions[i].ph; } } fine_search(p, image->features, p->nel, pmax, fft_in, fft_out, p->plan, smin, smax, th, ph, &bx, &by, &bz); /* Search for c */ smin = 2.0*pmax * cmin; smax = 2.0*pmax * cmax; fom = 0.0; th = 0.0; ph = 0.0; for ( i=0; in_dir; i++ ) { double new_fom, ang; ang = angle_between(p->directions[i].x, p->directions[i].y, p->directions[i].z, ax, ay, az); if ( fabs(ang-be) > angtol ) continue; ang = angle_between(p->directions[i].x, p->directions[i].y, p->directions[i].z, bx, by, bz); if ( fabs(ang-al) > angtol ) continue; new_fom = check_dir(&p->directions[i], image->features, p->nel, pmax, fft_in, fft_out, p->plan, smin, smax, NULL, NULL); if ( new_fom > fom ) { fom = new_fom; th = p->directions[i].th; ph = p->directions[i].ph; } } fine_search(p, image->features, p->nel, pmax, fft_in, fft_out, p->plan, smin, smax, th, ph, &cx, &cy, &cz); image->candidate_cells[0] = cell_new(); cell_set_cartesian(image->candidate_cells[0], ax, ay, az, bx, by, bz, cx, cy, cz); refine_all_rigid_groups(image, image->candidate_cells[0], p->nel, pmax, fft_in, fft_out, p->plan, smin, smax, image->det, p); map_all_peaks(image); refine_cell(image, image->candidate_cells[0], image->features); fftw_free(fft_in); fftw_free(fft_out); image->ncells = 1; } IndexingPrivate *reax_prepare() { struct reax_private *p; int samp; double th; p = calloc(1, sizeof(*p)); if ( p == NULL ) return NULL; p->base.indm = INDEXING_REAX; p->angular_inc = deg2rad(1.7); /* From Steller (1997) */ /* Reserve memory, over-estimating the number of directions */ samp = 2.0*M_PI / p->angular_inc; p->directions = malloc(samp*samp*sizeof(struct dvec)); if ( p == NULL) { free(p); return NULL; } STATUS("Allocated space for %i directions\n", samp*samp); /* Generate vectors for 1D Fourier transforms */ fesetround(1); /* Round to nearest */ p->n_dir = 0; for ( th=0.0; thangular_inc ) { double ph, phstep, n_phstep; n_phstep = 2.0*M_PI*sin(th)/p->angular_inc; n_phstep = nearbyint(n_phstep); phstep = 2.0*M_PI/n_phstep; for ( ph=0.0; ph<2.0*M_PI; ph+=phstep ) { struct dvec *dir; assert(p->n_dirdirections[p->n_dir++]; dir->x = cos(ph) * sin(th); dir->y = sin(ph) * sin(th); dir->z = cos(th); dir->th = th; dir->ph = ph; } } STATUS("Generated %i directions (angular increment %.3f deg)\n", p->n_dir, rad2deg(p->angular_inc)); p->nel = 1024; /* These arrays are not actually used */ p->fft_in = fftw_malloc(p->nel*sizeof(double)); p->fft_out = fftw_malloc((p->nel/2 + 1)*sizeof(fftw_complex)); p->plan = fftw_plan_dft_r2c_1d(p->nel, p->fft_in, p->fft_out, FFTW_MEASURE); p->cw = 128; p->ch = 128; /* Also not used */ p->r_fft_in = fftw_malloc(p->cw*p->ch*sizeof(fftw_complex)); p->r_fft_out = fftw_malloc(p->cw*p->ch*sizeof(fftw_complex)); p->r_plan = fftw_plan_dft_2d(p->cw, p->ch, p->r_fft_in, p->r_fft_out, 1, FFTW_MEASURE); return (IndexingPrivate *)p; } void reax_cleanup(IndexingPrivate *pp) { struct reax_private *p; assert(pp->indm == INDEXING_REAX); p = (struct reax_private *)pp; fftw_destroy_plan(p->plan); fftw_free(p->fft_in); fftw_free(p->fft_out); fftw_destroy_plan(p->r_plan); fftw_free(p->r_fft_in); fftw_free(p->r_fft_out); free(p); }