diff options
author | Thomas White <taw@physics.org> | 2011-07-11 16:55:35 +0200 |
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committer | Thomas White <taw@physics.org> | 2012-02-22 15:27:32 +0100 |
commit | 623939fb6bd9475935546b9539f404eaaff41a3f (patch) | |
tree | 8d8e77b07903bbb36df60646b4127dec18397d3f /src/hrs-scaling.c | |
parent | 1bd043203f25a26d5d806ed847f87a4fd7df5f22 (diff) |
Use new Kabsch algorithm for faster scaling
Diffstat (limited to 'src/hrs-scaling.c')
-rw-r--r-- | src/hrs-scaling.c | 444 |
1 files changed, 108 insertions, 336 deletions
diff --git a/src/hrs-scaling.c b/src/hrs-scaling.c index 45bbd591..cff0b90c 100644 --- a/src/hrs-scaling.c +++ b/src/hrs-scaling.c @@ -31,344 +31,142 @@ #include "reflist.h" -/* Maximum number of iterations of NLSq scaling per macrocycle. */ +/* Maximum number of iterations of scaling per macrocycle. */ #define MAX_CYCLES (50) +/* ESD of restraint driving scale factors to unity */ +#define SCALING_RESTRAINT (1.0) -static char *find_common_reflections(struct image *images, int n) + +static double iterate_scale(struct image *images, int n, RefList *reference) { - int i; - char *cref; + double max_shift = 0.0; + int frame; - cref = calloc(n*n, sizeof(char)); + assert(reference != NULL); - for ( i=0; i<n; i++ ) { + for ( frame=0; frame<n; frame++ ) { + struct image *image = &images[frame]; Reflection *refl; RefListIterator *iter; + double num = 0.0; + double den = 0.0; + double corr; - for ( refl = first_refl(images[i].reflections, &iter); + for ( refl = first_refl(image->reflections, &iter); refl != NULL; - refl = next_refl(refl, iter) ) { - + refl = next_refl(refl, iter) ) + { signed int h, k, l; - int j; + double Ih, Ihl, esd; + Reflection *r; if ( !get_scalable(refl) ) continue; - get_indices(refl, &h, &k, &l); - - for ( j=0; j<i; j++ ) { - Reflection *r2; - r2 = find_refl(images[j].reflections, h, k, l); - if ( r2 != NULL ) { - cref[i+n*j] = 1; - cref[j+n*i] = 1; - break; - } - } - - } - - } - - return cref; -} - - -static void s_uhavha(signed int hat, signed int kat, signed int lat, - struct image *image, double *uha, double *vha) -{ - double uha_val = 0.0; - double vha_val = 0.0; - RefList *reflections = image->reflections; - Reflection *refl; - - for ( refl = find_refl(reflections, hat, kat, lat); - refl != NULL; - refl = next_found_refl(refl) ) - { - double ic, sigi; - - if ( !get_scalable(refl) ) continue; - - ic = get_intensity(refl) / get_partiality(refl); - - /* Get the error in the estimated full intensity */ - sigi = get_esd_intensity(refl) / get_partiality(refl); - - uha_val += 1.0 / pow(sigi, 2.0); - vha_val += ic / pow(sigi, 2.0); - } - - *uha = uha_val; - *vha = vha_val; -} - - -static void s_uhvh(struct image *images, int n, - signed int h, signed int k, signed int l, - double *uhp, double *vhp) -{ - int a; - double uh = 0.0; - double vh = 0.0; - - for ( a=0; a<n; a++ ) { - - double uha, vha; - - s_uhavha(h, k, l, &images[a], &uha, &vha); - - uh += pow(images[a].osf, 2.0) * uha; - vh += images[a].osf * vha; - - } - - *uhp = uh; - *vhp = vh; -} - - -static gsl_vector *solve_diagonal(gsl_vector *v, gsl_vector *M) -{ - gsl_vector *shifts; - int n, frame; - - n = v->size; - if ( v->size != M->size ) return NULL; - - shifts = gsl_vector_alloc(n); - if ( shifts == NULL ) return NULL; - - for ( frame=0; frame<n; frame++ ) { - - double num, den, sh; - - num = gsl_vector_get(v, frame); - den = gsl_vector_get(M, frame); - sh = num/den; - - if ( isnan(sh) ) { - gsl_vector_set(shifts, frame, 0.0); - } else { - gsl_vector_set(shifts, frame, sh); - } - - } - - return shifts; -} - - -static double iterate_scale(struct image *images, int n, RefList *scalable, - char *cref, RefList *reference) -{ - gsl_vector *M; - gsl_vector *v; - gsl_vector *shifts; - double max_shift; - int frame; - Reflection *refl; - RefListIterator *iter; - - M = gsl_vector_calloc(n); - v = gsl_vector_calloc(n); - - for ( refl = first_refl(scalable, &iter); - refl != NULL; - refl = next_refl(refl, iter) ) - { - int a; - signed int h, k, l; - double uh, vh, Ih; - - get_indices(refl, &h, &k, &l); - - s_uhvh(images, n, h, k, l, &uh, &vh); - - if ( !reference ) { - Ih = vh / uh; - /* 0 / 0 = 0, not NaN */ - if ( isnan(Ih) ) Ih = 0.0; - } else { /* Look up by asymmetric indices */ - Reflection *r = find_refl(reference, h, k, l); + get_indices(refl, &h, &k, &l); + r = find_refl(reference, h, k, l); if ( r == NULL ) { ERROR("%3i %3i %3i isn't in the " "reference list, so why is it " "marked as scalable?\n", h, k, l); Ih = 0.0; } else { + if ( get_redundancy(r) < 2 ) continue; Ih = get_intensity(r); } - } - - for ( a=0; a<n; a++ ) { - - struct image *image = &images[a]; - double vc, rha, vha, uha; - double vval; - /* Determine the "solution" vector component */ - s_uhavha(h, k, l, image, &uha, &vha); - rha = vha - image->osf * uha * Ih; - vc = Ih * rha; - vval = gsl_vector_get(v, a); - gsl_vector_set(v, a, vval+vc); + Ihl = get_intensity(refl) / get_partiality(refl); + esd = get_esd_intensity(refl) / get_partiality(refl); - vval = gsl_vector_get(M, a); - gsl_vector_set(M, a, vval+(pow(Ih, 2.0) * uha)); + num += Ih * (Ihl/image->osf) / pow(esd/image->osf, 2.0); + den += pow(Ih, 2.0)/pow(esd/image->osf, 2.0); } - } - - shifts = solve_diagonal(v, M); - gsl_vector_free(M); - gsl_vector_free(v); - if ( shifts == NULL ) return 0.0; + //num += image->osf / pow(SCALING_RESTRAINT, 2.0); + //den += pow(image->osf, 2.0)/pow(SCALING_RESTRAINT, 2.0); - /* Apply shifts */ - max_shift = 0.0; - for ( frame=0; frame<n; frame++ ) { - - double shift = gsl_vector_get(shifts, frame); - - images[frame].osf += shift; - - //STATUS("Shift %i: %5.2f: -> %5.2f\n", - // frame, shift, images[frame].osf); - - if ( fabs(shift) > fabs(max_shift) ) { - max_shift = fabs(shift); + corr = num / den; + if ( !isnan(corr) && !isinf(corr) ) { + image->osf *= corr; } + if ( fabs(corr-1.0) > max_shift ) max_shift = fabs(corr-1.0); } - gsl_vector_free(shifts); - return max_shift; } -static void lsq_intensities(struct image *images, int n, RefList *full) +static RefList *lsq_intensities(struct image *images, int n) { + RefList *full; + int frame; Reflection *refl; RefListIterator *iter; - for ( refl = first_refl(full, &iter); - refl != NULL; - refl = next_refl(refl, iter) ) - { - double num = 0.0; - double den = 0.0; - int m; - int redundancy = 0; - signed int h, k, l; - - get_indices(refl, &h, &k, &l); - - /* For each frame */ - for ( m=0; m<n; m++ ) { + full = reflist_new(); - double G; - Reflection *f; - - /* Don't scale intensities from this image if - * post refinement failed on the last step. */ - if ( images[m].pr_dud ) continue; - - G = images[m].osf; + for ( frame=0; frame<n; frame++ ) { - for ( f = find_refl(images[m].reflections, h, k, l); - f != NULL; f = next_found_refl(refl) ) - { + double G; - double p; + if ( images[frame].pr_dud ) continue; + G = images[frame].osf; - if ( !get_scalable(f) ) continue; - p = get_partiality(f); + for ( refl = first_refl(images[frame].reflections, &iter); + refl != NULL; + refl = next_refl(refl, iter) ) + { + Reflection *f; + signed int h, k, l; + double num, den; + int red; + double Ihl, esd; - num += get_intensity(f) * p * G; - den += pow(p, 2.0) * pow(G, 2.0); - redundancy++; + if ( !get_scalable(refl) ) continue; + get_indices(refl, &h, &k, &l); + f = find_refl(full, h, k, l); + if ( f == NULL ) { + f = add_refl(full, h, k, l); + num = 0.0; + den = 0.0; + red = 0; + } else { + num = get_temp1(f); + den = get_temp2(f); + red = get_redundancy(f); } - } - - set_int(refl, num/den); + Ihl = get_intensity(refl) / get_partiality(refl); + esd = get_esd_intensity(refl) / get_partiality(refl); - //STATUS("%3i %3i %3i %i %i\n", h, k, l, - // redundancy, get_redundancy(refl)); + num += (Ihl/G) / pow(esd/G, 2.0); + den += 1.0 / pow(esd/G, 2.0); + red++; - if ( get_redundancy(refl) != redundancy ) { - ERROR("Didn't find all the expected parts for" - " %3i %3i %3i\n", h, k, l); + set_temp1(f, num); + set_temp2(f, den); + set_redundancy(f, red); } } -} - - -static void normalise_osfs(struct image *images, int n) -{ - int m; - double tot = 0.0; - double norm; - - for ( m=0; m<n; m++ ) { - tot += images[m].osf; - } - norm = n / tot; - - for ( m=0; m<n; m++ ) { - images[m].osf *= norm; - } -} - - -static RefList *guess_scaled_reflections(struct image *images, int n) -{ - RefList *scalable; - int i; - - scalable = reflist_new(); - for ( i=0; i<n; i++ ) { - - Reflection *refl; - RefListIterator *iter; - /* Don't scale intensities from this image if - * post refinement failed on the last step. */ - if ( images[i].pr_dud ) continue; - - for ( refl = first_refl(images[i].reflections, &iter); - refl != NULL; - refl = next_refl(refl, iter) ) - { - if ( get_scalable(refl) ) { - - signed int h, k, l; - Reflection *f; - int red; - - get_indices(refl, &h, &k, &l); - f = find_refl(scalable, h, k, l); - if ( f == NULL ) { - f = add_refl(scalable, h, k, l); - } - - red = get_redundancy(f); - set_redundancy(f, red+1); + for ( refl = first_refl(full, &iter); + refl != NULL; + refl = next_refl(refl, iter) ) + { + double Ih; - } - } + Ih = get_temp1(refl) / get_temp2(refl); + set_int(refl, Ih); } - return scalable; + return full; } @@ -438,80 +236,54 @@ static UNUSED void plot_graph(struct image *image, RefList *reference) } -static void scale_matrix(struct image *images, int n, RefList *scalable, - RefList *reference) -{ - int i, m; - double max_shift; - char *cref; - - /* Start with all scale factors equal */ - for ( m=0; m<n; m++ ) images[m].osf = 1.0; - - cref = find_common_reflections(images, n); - - /* Iterate */ - i = 0; - do { - - max_shift = iterate_scale(images, n, scalable, cref, reference); - STATUS("Scaling iteration %2i: max shift = %5.2f\n", - i+1, max_shift); - i++; - if ( reference == NULL ) normalise_osfs(images, n); - - } while ( (max_shift > 0.01) && (i < MAX_CYCLES) ); - - free(cref); -} - - -static void scale_megatron(struct image *images, int n, RefList *scalable) +/* Scale the stack of images */ +RefList *scale_intensities(struct image *images, int n, RefList *gref) { - int i, m; - double max_shift; - double *old_osfs; - - old_osfs = calloc(n, sizeof(double)); + int i; + double max_corr; + RefList *full = NULL; - /* Start with all scale factors equal */ - for ( m=0; m<n; m++ ) { - images[m].osf = 1.0; - old_osfs[m] = images[m].osf; + for ( i=0; i<n; i++ ) { + images[i].osf = 1.0; } - lsq_intensities(images, n, scalable); + /* No reference -> create an initial list to refine against */ + if ( gref == NULL ) { + full = lsq_intensities(images, n); + } /* Iterate */ i = 0; do { - max_shift = iterate_scale(images, n, scalable, NULL, scalable); - STATUS("Scaling iteration %2i: max shift = %5.2f\n", - i+1, max_shift); - i++; + RefList *reference; - for ( m=0; m<n; m++ ) { - images[m].osf *= old_osfs[m]; + /* Refine against reference or current "full" estimates */ + if ( gref != NULL ) { + reference = gref; + } else { + reference = full; } - } while ( (max_shift > 0.01) && (i < MAX_CYCLES) ); -} + max_corr = iterate_scale(images, n, reference); + STATUS("Scaling iteration %2i: max correction = %5.2f\n", + i+1, max_corr); + /* No reference -> generate list for next iteration */ + if ( gref == NULL ) { + reflist_free(full); + full = lsq_intensities(images, n); + } -/* Scale the stack of images */ -RefList *scale_intensities(struct image *images, int n, RefList *reference) -{ - RefList *full; + //show_scale_factors(images, n); - full = guess_scaled_reflections(images, n); + i++; - if ( reference != NULL ) { - scale_matrix(images, n, full, reference); - } else { - scale_megatron(images, n, full); - } + } while ( (max_corr > 0.01) && (i < MAX_CYCLES) ); + + if ( gref != NULL ) { + full = lsq_intensities(images, n); + } /* else we already did it */ - lsq_intensities(images, n, full); return full; } |