/* * post-refinement.c * * Post refinement * * Copyright © 2012-2018 Deutsches Elektronen-Synchrotron DESY, * a research centre of the Helmholtz Association. * * Authors: * 2010-2018 Thomas White * * This file is part of CrystFEL. * * CrystFEL is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * CrystFEL is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with CrystFEL. If not, see . * */ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #include "image.h" #include "post-refinement.h" #include "peaks.h" #include "symmetry.h" #include "geometry.h" #include "cell.h" #include "cell-utils.h" #include "reflist-utils.h" #include "scaling.h" #include "merge.h" struct prdata { int refined; }; const char *str_prflag(enum prflag flag) { switch ( flag ) { case PRFLAG_OK : return "OK"; case PRFLAG_FEWREFL : return "not enough reflections"; case PRFLAG_SOLVEFAIL : return "PR solve failed"; case PRFLAG_EARLY : return "early rejection"; case PRFLAG_DELTACCHALF : return "negative delta CC½"; case PRFLAG_BIGB : return "B too big"; case PRFLAG_SCALEBAD : return "bad scaling"; default : return "Unknown flag"; } } static void rotate_cell_xy(UnitCell *cell, double ang1, double ang2) { double asx, asy, asz; double bsx, bsy, bsz; double csx, csy, csz; double xnew, ynew, znew; cell_get_reciprocal(cell, &asx, &asy, &asz, &bsx, &bsy, &bsz, &csx, &csy, &csz); /* "a" around x */ xnew = asx; ynew = asy*cos(ang1) + asz*sin(ang1); znew = -asy*sin(ang1) + asz*cos(ang1); asx = xnew; asy = ynew; asz = znew; /* "b" around x */ xnew = bsx; ynew = bsy*cos(ang1) + bsz*sin(ang1); znew = -bsy*sin(ang1) + bsz*cos(ang1); bsx = xnew; bsy = ynew; bsz = znew; /* "c" around x */ xnew = csx; ynew = csy*cos(ang1) + csz*sin(ang1); znew = -csy*sin(ang1) + csz*cos(ang1); csx = xnew; csy = ynew; csz = znew; /* "a" around y */ xnew = asx*cos(ang2) + asz*sin(ang2); ynew = asy; znew = -asx*sin(ang2) + asz*cos(ang2); asx = xnew; asy = ynew; asz = znew; /* "b" around y */ xnew = bsx*cos(ang2) + bsz*sin(ang2); ynew = bsy; znew = -bsx*sin(ang2) + bsz*cos(ang2); bsx = xnew; bsy = ynew; bsz = znew; /* "c" around y */ xnew = csx*cos(ang2) + csz*sin(ang2); ynew = csy; znew = -csx*sin(ang2) + csz*cos(ang2); csx = xnew; csy = ynew; csz = znew; cell_set_reciprocal(cell, asx, asy, asz, bsx, bsy, bsz, csx, csy, csz); } static const char *get_label(enum gparam p) { switch ( p ) { case GPARAM_ANG1 : return "First angle (radians)"; case GPARAM_ANG2 : return "Second angle (radians)"; case GPARAM_R : return "Profile radius (m^-1)"; case GPARAM_WAVELENGTH : return "Wavelength (Angstroms)"; default : return "unknown"; } } /* We set all the step sizes to 1, then scale them. * This way, the size of the simplex stays meaningful and we possibly also * avoid some roundoff errors */ static double get_scale(enum gparam p) { switch ( p ) { case GPARAM_ANG1 : return deg2rad(0.05); case GPARAM_ANG2 : return deg2rad(0.05); case GPARAM_R : return 0.0005e9; case GPARAM_WAVELENGTH : return 0.001e-10; default : return 0.0; } } struct rf_priv { const Crystal *cr; const RefList *full; enum gparam rv[32]; int verbose; int serial; gsl_vector *initial; int scaleflags; /* For freeing later */ gsl_vector *vals; gsl_vector *step; /* So that it stays around until the end of minimisation */ gsl_multimin_function f; }; static double get_actual_val(const gsl_vector *v, const gsl_vector *initial, enum gparam *rv, int i) { return gsl_vector_get(v, i) * get_scale(rv[i]) + gsl_vector_get(initial, i); } static void apply_parameters(const gsl_vector *v, const gsl_vector *initial, enum gparam *rv, Crystal *cr) { int i; double ang1, ang2, R, lambda; /* Default parameters if not used in refinement */ ang1 = 0.0; ang2 = 0.0; R = crystal_get_profile_radius(cr); lambda = crystal_get_image(cr)->lambda; for ( i=0; isize; i++ ) { double val; val = get_actual_val(v, initial, rv, i); switch ( rv[i] ) { case GPARAM_ANG1 : ang1 = val; break; case GPARAM_ANG2 : ang2 = val; break; case GPARAM_R : R = val; break; case GPARAM_WAVELENGTH : lambda = val; break; default : ERROR("Don't understand parameter %i\n", rv[i]); break; } } rotate_cell_xy(crystal_get_cell(cr), ang1, ang2); crystal_set_profile_radius(cr, R); crystal_get_image(cr)->lambda = lambda; } static double residual_f(const gsl_vector *v, void *pp) { struct rf_priv *pv = pp; RefList *list; struct image im; Crystal *cr; double res; int i; for ( i=0; isize; i++ ) { if ( gsl_vector_get(v, i) > 100.0 ) return GSL_NAN; } cr = crystal_copy(pv->cr); im = *crystal_get_image(cr); crystal_set_image(cr, &im); crystal_set_cell(cr, cell_new_from_cell(crystal_get_cell(cr))); apply_parameters(v, pv->initial, pv->rv, cr); if ( fabs(crystal_get_profile_radius(cr)) > 5e9 ) { cell_free(crystal_get_cell(cr)); crystal_free(cr); if ( pv->verbose ) STATUS("radius > 5e9\n"); return GSL_NAN; } /* Can happen with grid scans and certain --force-radius values */ if ( fabs(crystal_get_profile_radius(cr)) < 0.0000001e9 ) { cell_free(crystal_get_cell(cr)); crystal_free(cr); if ( pv->verbose ) STATUS("radius very small\n"); return GSL_NAN; } if ( im.lambda <= 0.0 ) { cell_free(crystal_get_cell(cr)); crystal_free(cr); if ( pv->verbose ) STATUS("lambda < 0\n"); return GSL_NAN; } list = copy_reflist(crystal_get_reflections(cr)); crystal_set_reflections(cr, list); update_predictions(cr); calculate_partialities(cr, PMODEL_XSPHERE); if ( scale_one_crystal(cr, pv->full, pv->scaleflags) ) { cell_free(crystal_get_cell(cr)); reflist_free(crystal_get_reflections(cr)); crystal_free(cr); if ( pv->verbose ) STATUS("Bad scaling\n"); return GSL_NAN; } res = residual(cr, pv->full, 0, NULL, NULL); cell_free(crystal_get_cell(cr)); reflist_free(crystal_get_reflections(cr)); crystal_free(cr); return res; } static double get_initial_param(Crystal *cr, enum gparam p) { switch ( p ) { case GPARAM_ANG1 : return 0.0; case GPARAM_ANG2 : return 0.0; case GPARAM_R : return crystal_get_profile_radius(cr); case GPARAM_WAVELENGTH : return crystal_get_image(cr)->lambda; default: return 0.0; } } static int check_angle_shifts(gsl_vector *cur, const gsl_vector *initial, enum gparam *rv, struct rf_priv *residual_f_priv) { int i = 0; double ang = 0.0; while ( rv[i] != GPARAM_EOL ) { if ( (rv[i] == GPARAM_ANG1) || (rv[i] == GPARAM_ANG2) ) { ang += fabs(get_actual_val(cur, initial, rv, i)); } rv++; } if ( rad2deg(ang) > 5.0 ) { ERROR("More than 5 degrees total rotation!\n"); residual_f_priv->verbose = 1; double res = residual_f(cur, residual_f_priv); STATUS("residual after rotation = %e\n", res); residual_f_priv->verbose = 2; res = residual_f(initial, residual_f_priv); STATUS("residual before rotation = %e\n", res); return 1; } return 0; } static RefList *reindex_reflections(RefList *input, SymOpList *amb, SymOpList *sym, int idx) { RefList *n; Reflection *refl; RefListIterator *iter; n = reflist_new(); for ( refl = first_refl(input, &iter); refl != NULL; refl = next_refl(refl, iter) ) { signed int h, k, l; Reflection *rn; get_indices(refl, &h, &k, &l); get_equiv(amb, NULL, idx, h, k, l, &h, &k, &l); get_asymm(sym, h, k, l, &h, &k, &l); rn = add_refl(n, h, k, l); copy_data(rn, refl); get_symmetric_indices(rn, &h, &k, &l); get_equiv(amb, NULL, idx, h, k, l, &h, &k, &l); set_symmetric_indices(rn, h, k, l); } return n; } static void reindex_cell(UnitCell *cell, SymOpList *amb, int idx) { signed int h, k, l; struct rvec na, nb, nc; struct rvec as, bs, cs; cell_get_reciprocal(cell, &as.u, &as.v, &as.w, &bs.u, &bs.v, &bs.w, &cs.u, &cs.v, &cs.w); get_equiv(amb, NULL, idx, 1, 0, 0, &h, &k, &l); na.u = as.u*h + bs.u*k + cs.u*l; na.v = as.v*h + bs.v*k + cs.v*l; na.w = as.w*h + bs.w*k + cs.w*l; get_equiv(amb, NULL, idx, 0, 1, 0, &h, &k, &l); nb.u = as.u*h + bs.u*k + cs.u*l; nb.v = as.v*h + bs.v*k + cs.v*l; nb.w = as.w*h + bs.w*k + cs.w*l; get_equiv(amb, NULL, idx, 0, 0, 1, &h, &k, &l); nc.u = as.u*h + bs.u*k + cs.u*l; nc.v = as.v*h + bs.v*k + cs.v*l; nc.w = as.w*h + bs.w*k + cs.w*l; cell_set_reciprocal(cell, na.u, na.v, na.w, nb.u, nb.v, nb.w, nc.u, nc.v, nc.w); } static void try_reindex(Crystal *crin, const RefList *full, SymOpList *sym, SymOpList *amb, int scaleflags) { RefList *list; Crystal *cr; UnitCell *cell; double residual_original, residual_flipped; int idx, n; if ( sym == NULL || amb == NULL ) return; if ( scale_one_crystal(crin, full, scaleflags) ) return; residual_original = residual(crin, full, 0, NULL, NULL); cr = crystal_copy(crin); n = num_equivs(amb, NULL); for ( idx=0; idxfilename, get_event_string(image->event)); } if ( cycle >= 0 ) { snprintf(ins, 4, "%i", cycle); } else { ins[0] = 'F'; ins[1] = '\0'; } fprintf(fh, "%s rlp_size = %e\n", ins, crystal_get_profile_radius(crystal)/1e10); fprintf(fh, "%s mosaicity = %e\n", ins, crystal_get_mosaicity(crystal)); fprintf(fh, "%s wavelength = %f A\n", ins, image->lambda*1e10); fprintf(fh, "%s bandwidth = %f\n", ins, image->bw); fprintf(fh, "%s my scale factor = %e\n", ins, crystal_get_osf(crystal)); double asx, asy, asz, bsx, bsy, bsz, csx, csy, csz; cell_get_reciprocal(crystal_get_cell(crystal), &asx, &asy, &asz, &bsx, &bsy, &bsz, &csx, &csy, &csz); fprintf(fh, "%s %f, %f, %f, %f, %f, %f, %f, %f, %f\n", ins, asx/1e10, bsx/1e10, csx/1e10, asy/1e10, bsy/1e10, csy/1e10, asz/1e10, bsz/1e10, csz/1e10); fclose(fh); } void write_specgraph(Crystal *crystal, const RefList *full, signed int cycle, int serial) { FILE *fh; char tmp[256]; Reflection *refl; RefListIterator *iter; double G = crystal_get_osf(crystal); double B = crystal_get_Bfac(crystal); UnitCell *cell; struct image *image = crystal_get_image(crystal); char ins[5]; snprintf(tmp, 256, "pr-logs/specgraph-crystal%i.dat", serial); if ( cycle == 0 ) { fh = fopen(tmp, "w"); } else { fh = fopen(tmp, "a"); } if ( fh == NULL ) { ERROR("Failed to open '%s'\n", tmp); return; } if ( cycle == 0 ) { fprintf(fh, "Image: %s %s\n", image->filename, get_event_string(image->event)); fprintf(fh, "khalf/m 1/d(m) pcalc pobs iteration h k l\n"); } cell = crystal_get_cell(crystal); if ( cycle >= 0 ) { snprintf(ins, 4, "%i", cycle); } else { ins[0] = 'F'; ins[1] = '\0'; } for ( refl = first_refl(crystal_get_reflections(crystal), &iter); refl != NULL; refl = next_refl(refl, iter) ) { double Ipart, Ifull, pobs, pcalc; double res; signed int h, k, l; Reflection *match; get_indices(refl, &h, &k, &l); res = resolution(cell, h, k, l); match = find_refl(full, h, k, l); if ( match == NULL ) continue; /* Don't calculate pobs if reference reflection is weak */ if ( fabs(get_intensity(match)) / get_esd_intensity(match) < 3.0 ) continue; Ipart = correct_reflection_nopart(refl, G, B, res); Ifull = get_intensity(match); pobs = Ipart / Ifull; pcalc = get_partiality(refl); fprintf(fh, "%e %e %f %f %s %4i %4i %4i\n", get_khalf(refl), 2.0*res, pcalc, pobs, ins, h, k, l); } fclose(fh); } static gsl_multimin_fminimizer *setup_minimiser(Crystal *cr, const RefList *full, int verbose, int serial, int scaleflags, struct rf_priv *priv) { gsl_multimin_fminimizer *min; int n_params = 0; int i, r; /* The parameters to be refined */ priv->rv[n_params++] = GPARAM_ANG1; priv->rv[n_params++] = GPARAM_ANG2; priv->rv[n_params++] = GPARAM_R; priv->rv[n_params++] = GPARAM_WAVELENGTH; priv->rv[n_params] = GPARAM_EOL; /* End of list */ priv->cr = cr; priv->full = full; priv->verbose = verbose; priv->serial = serial; priv->scaleflags = scaleflags; priv->f.f = residual_f; priv->f.n = n_params; priv->f.params = priv; priv->initial = gsl_vector_alloc(n_params); priv->vals = gsl_vector_alloc(n_params); priv->step = gsl_vector_alloc(n_params); for ( i=0; iinitial, i, get_initial_param(cr, priv->rv[i])); gsl_vector_set(priv->vals, i, 0.0); gsl_vector_set(priv->step, i, 1.0); } min = gsl_multimin_fminimizer_alloc(gsl_multimin_fminimizer_nmsimplex2, n_params); if ( min == NULL ) { ERROR("Failed to allocate minimiser\n"); gsl_vector_free(priv->vals); gsl_vector_free(priv->step); gsl_vector_free(priv->initial); return NULL; } r = gsl_multimin_fminimizer_set(min, &priv->f, priv->vals, priv->step); if ( r != 0 ) { gsl_multimin_fminimizer_free(min); gsl_vector_free(priv->vals); gsl_vector_free(priv->step); gsl_vector_free(priv->initial); ERROR("Failed to set up minimiser: %s\n", gsl_strerror(r)); return NULL; } return min; } static void write_grid(Crystal *cr, const RefList *full, signed int cycle, int serial, int scaleflags, const enum gparam par1, const enum gparam par2, const char *name) { FILE *fh; char fn[16]; char ins[5]; gsl_multimin_fminimizer *min; struct rf_priv priv; int idx1, idx2; int i; min = setup_minimiser(cr, full, 0, serial, scaleflags, &priv); idx1 = 99; idx2 = 99; for ( i=0; i= 0 ) { snprintf(ins, 12, "%i", cycle); } else { ins[0] = 'F'; ins[1] = '\0'; } snprintf(fn, 63, "pr-logs/grid-crystal%i-cycle%s-%s.dat", serial, ins, name); fh = fopen(fn, "w"); if ( fh != NULL ) { double v1, v2; fprintf(fh, "%e %e %e %s\n", -5.0*get_scale(par1)+get_initial_param(cr, par1), 5.0*get_scale(par1)+get_initial_param(cr, par1), get_initial_param(cr, par1), get_label(par1)); fprintf(fh, "%e %e %e %s\n", -5.0*get_scale(par2)+get_initial_param(cr, par2), 5.0*get_scale(par2)+get_initial_param(cr, par2), get_initial_param(cr, par2), get_label(par2)); for ( v2=-5.0; v2<=5.0; v2+=0.25 ) { int first=1; for ( v1=-5.0; v1<=5.0; v1+=0.25 ) { double res; gsl_vector_set(min->x, idx1, v1); gsl_vector_set(min->x, idx2, v2); res = residual_f(min->x, &priv); if ( !first ) fprintf(fh, " "); first = 0; fprintf(fh, "%e", res); } fprintf(fh, "\n"); } } fclose(fh); gsl_multimin_fminimizer_free(min); gsl_vector_free(priv.initial); gsl_vector_free(priv.vals); gsl_vector_free(priv.step); } void write_gridscan(Crystal *cr, const RefList *full, signed int cycle, int serial, int scaleflags) { write_grid(cr, full, cycle, serial, scaleflags, GPARAM_ANG1, GPARAM_ANG2, "ang1-ang2"); write_grid(cr, full, cycle, serial, scaleflags, GPARAM_ANG1, GPARAM_WAVELENGTH, "ang1-wave"); write_grid(cr, full, cycle, serial, scaleflags, GPARAM_R, GPARAM_WAVELENGTH, "R-wave"); } static void do_pr_refine(Crystal *cr, const RefList *full, PartialityModel pmodel, int verbose, int serial, int cycle, int write_logs, SymOpList *sym, SymOpList *amb, int scaleflags) { gsl_multimin_fminimizer *min; struct rf_priv priv; int n_iter = 0; int status; double residual_start, residual_free_start; FILE *fh = NULL; try_reindex(cr, full, sym, amb, scaleflags); if ( scale_one_crystal(cr, full, scaleflags | SCALE_VERBOSE_ERRORS) ) { ERROR("Bad scaling at start of refinement.\n"); return; } residual_start = residual(cr, full, 0, NULL, NULL); residual_free_start = residual(cr, full, 1, NULL, NULL); if ( verbose ) { STATUS("\nPR initial: dev = %10.5e, free dev = %10.5e\n", residual_start, residual_free_start); } min = setup_minimiser(cr, full, verbose, serial, scaleflags, &priv); if ( min == NULL ) return; if ( verbose ) { double res = residual_f(min->x, &priv); double size = gsl_multimin_fminimizer_size(min); STATUS("At start: %f %f %f %f ----> %f %f %e %f residual = %e size %f\n", gsl_vector_get(min->x, 0), gsl_vector_get(min->x, 1), gsl_vector_get(min->x, 2), gsl_vector_get(min->x, 3), rad2deg(get_actual_val(min->x, priv.initial, priv.rv, 0)), rad2deg(get_actual_val(min->x, priv.initial, priv.rv, 1)), get_actual_val(min->x, priv.initial, priv.rv, 2), get_actual_val(min->x, priv.initial, priv.rv, 3)*1e10, res, size); } if ( write_logs ) { char fn[64]; snprintf(fn, 63, "pr-logs/crystal%i-cycle%i.log", serial, cycle); fh = fopen(fn, "w"); if ( fh != NULL ) { fprintf(fh, "iteration RtoReference CCtoReference nref " "ang1 ang2 radius wavelength"); double res = residual_f(min->x, &priv); fprintf(fh, "%5i %10.8f %10.8f %5i %10.8f %10.8f %e %e\n", n_iter, res, 0.0, 0, rad2deg(get_actual_val(min->x, priv.initial, priv.rv, 0)), rad2deg(get_actual_val(min->x, priv.initial, priv.rv, 1)), get_actual_val(min->x, priv.initial, priv.rv, 2), get_actual_val(min->x, priv.initial, priv.rv, 3)*1e10); } } do { double res; n_iter++; status = gsl_multimin_fminimizer_iterate(min); if ( status ) break; res = residual_f(min->x, &priv); if ( isnan(res) ) { status = GSL_ENOPROG; break; } if ( verbose ) { double res = residual_f(min->x, &priv); double size = gsl_multimin_fminimizer_size(min); STATUS("%f %f %f %f ----> %f %f %e %f residual = %e size %f\n", gsl_vector_get(min->x, 0), gsl_vector_get(min->x, 1), gsl_vector_get(min->x, 2), gsl_vector_get(min->x, 3), rad2deg(get_actual_val(min->x, priv.initial, priv.rv, 0)), rad2deg(get_actual_val(min->x, priv.initial, priv.rv, 1)), get_actual_val(min->x, priv.initial, priv.rv, 2), get_actual_val(min->x, priv.initial, priv.rv, 3)*1e10, res, size); } if ( fh != NULL ) { fprintf(fh, "%5i %10.8f %10.8f %5i %10.8f %10.8f %e %e\n", n_iter, res, 0.0, 0, rad2deg(get_actual_val(min->x, priv.initial, priv.rv, 0)), rad2deg(get_actual_val(min->x, priv.initial, priv.rv, 1)), get_actual_val(min->x, priv.initial, priv.rv, 2), get_actual_val(min->x, priv.initial, priv.rv, 3)*1e10); } status = gsl_multimin_test_size(min->size, 0.005); } while ( status == GSL_CONTINUE && n_iter < 1000 ); if ( verbose ) { STATUS("Done with refinement after %i iter\n", n_iter); STATUS("status = %i (%s)\n", status, gsl_strerror(status)); } if ( status == GSL_SUCCESS ) { if ( check_angle_shifts(min->x, priv.initial, priv.rv, &priv) ) return; if ( verbose ) { double res = residual_f(min->x, &priv); double size = gsl_multimin_fminimizer_size(min); STATUS("At end: %f %f %f %f ----> %f %f %e %f residual = %e size %f\n", gsl_vector_get(min->x, 0), gsl_vector_get(min->x, 1), gsl_vector_get(min->x, 2), gsl_vector_get(min->x, 3), rad2deg(get_actual_val(min->x, priv.initial, priv.rv, 0)), rad2deg(get_actual_val(min->x, priv.initial, priv.rv, 1)), get_actual_val(min->x, priv.initial, priv.rv, 2), get_actual_val(min->x, priv.initial, priv.rv, 3)*1e10, res, size); } if ( fh != NULL ) { double res = residual_f(min->x, &priv); fprintf(fh, "%5i %10.8f %10.8f %5i %10.8f %10.8f %e %e\n", n_iter, res, 0.0, 0, rad2deg(get_actual_val(min->x, priv.initial, priv.rv, 0)), rad2deg(get_actual_val(min->x, priv.initial, priv.rv, 1)), get_actual_val(min->x, priv.initial, priv.rv, 2), get_actual_val(min->x, priv.initial, priv.rv, 3)*1e10); } /* Apply the final shifts */ apply_parameters(min->x, priv.initial, priv.rv, cr); update_predictions(cr); calculate_partialities(cr, PMODEL_XSPHERE); scale_one_crystal(cr, full, scaleflags); if ( verbose ) { STATUS("After applying final shifts:\n"); STATUS("PR final: dev = %10.5e, free dev = %10.5e\n", residual(cr, full, 0, NULL, NULL), residual(cr, full, 1, NULL, NULL)); STATUS("Final R = %e m^-1\n", crystal_get_profile_radius(cr)); } } else { ERROR("Bad refinement: crystal %i\n", serial); } if ( write_logs ) { write_gridscan(cr, full, cycle, serial, scaleflags); write_specgraph(cr, full, cycle, serial); write_test_logs(cr, full, cycle, serial); } if ( crystal_get_profile_radius(cr) > 5e9 ) { ERROR("Very large radius: crystal %i\n", serial); } if ( fh != NULL ) { fclose(fh); } gsl_multimin_fminimizer_free(min); gsl_vector_free(priv.initial); gsl_vector_free(priv.vals); gsl_vector_free(priv.step); } struct refine_args { RefList *full; Crystal *crystal; PartialityModel pmodel; int serial; struct prdata prdata; int verbose; int cycle; int no_logs; SymOpList *sym; SymOpList *amb; int scaleflags; }; struct queue_args { int n_started; int n_done; Crystal **crystals; int n_crystals; struct refine_args task_defaults; }; static void refine_image(void *task, int id) { struct refine_args *pargs = task; Crystal *cr = pargs->crystal; int write_logs = 0; write_logs = !pargs->no_logs && (pargs->serial % 20 == 0); pargs->prdata.refined = 0; do_pr_refine(cr, pargs->full, pargs->pmodel, pargs->verbose, pargs->serial, pargs->cycle, write_logs, pargs->sym, pargs->amb, pargs->scaleflags); if ( crystal_get_user_flag(cr) == 0 ) { pargs->prdata.refined = 1; } } static void *get_image(void *vqargs) { struct refine_args *task; struct queue_args *qargs = vqargs; task = malloc(sizeof(struct refine_args)); memcpy(task, &qargs->task_defaults, sizeof(struct refine_args)); task->crystal = qargs->crystals[qargs->n_started]; task->serial = qargs->n_started; qargs->n_started++; return task; } static void done_image(void *vqargs, void *task) { struct queue_args *qa = vqargs; qa->n_done++; progress_bar(qa->n_done, qa->n_crystals, "Refining"); free(task); } void refine_all(Crystal **crystals, int n_crystals, RefList *full, int nthreads, PartialityModel pmodel, int verbose, int cycle, int no_logs, SymOpList *sym, SymOpList *amb, int scaleflags) { struct refine_args task_defaults; struct queue_args qargs; task_defaults.full = full; task_defaults.crystal = NULL; task_defaults.pmodel = pmodel; task_defaults.prdata.refined = 0; task_defaults.verbose = verbose; task_defaults.cycle = cycle; task_defaults.no_logs = no_logs; task_defaults.sym = sym; task_defaults.amb = amb; task_defaults.scaleflags = scaleflags; qargs.task_defaults = task_defaults; qargs.n_started = 0; qargs.n_done = 0; qargs.n_crystals = n_crystals; qargs.crystals = crystals; /* Don't have threads which are doing nothing */ if ( n_crystals < nthreads ) nthreads = n_crystals; run_threads(nthreads, refine_image, get_image, done_image, &qargs, n_crystals, 0, 0, 0); }