/* * pr_p_gradient_check.c * * Check partiality gradients for post refinement * * Copyright © 2012-2014 Deutsches Elektronen-Synchrotron DESY, * a research centre of the Helmholtz Association. * * Authors: * 2012-2014 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 #include #include #include #include #include "../src/post-refinement.h" static void scan_partialities(RefList *reflections, RefList *compare, int *valid, long double *vals[3], int idx) { int i; Reflection *refl; RefListIterator *iter; i = 0; for ( refl = first_refl(reflections, &iter); refl != NULL; refl = next_refl(refl, iter) ) { signed int h, k, l; Reflection *refl2; double r1, r2, p; int clamp_low, clamp_high; get_indices(refl, &h, &k, &l); refl2 = find_refl(compare, h, k, l); if ( refl2 == NULL ) { valid[i] = 0; i++; continue; } get_partial(refl2, &r1, &r2, &p, &clamp_low, &clamp_high); if ( clamp_low && clamp_high ) { if ( !within_tolerance(p, 1.0, 0.001) ) { signed int h, k, l; get_indices(refl, &h, &k, &l); ERROR("%3i %3i %3i - double clamped but" " partiality not close to 1.0 (%5.2f)\n", h, k, l, p); } valid[i] = 0; } vals[idx][i] = p * get_lorentz(refl2); i++; } } static UnitCell *new_shifted_cell(UnitCell *input, int k, double shift) { UnitCell *cell; double asx, asy, asz; double bsx, bsy, bsz; double csx, csy, csz; cell = cell_new(); cell_get_reciprocal(input, &asx, &asy, &asz, &bsx, &bsy, &bsz, &csx, &csy, &csz); switch ( k ) { case REF_ASX : asx += shift; break; case REF_ASY : asy += shift; break; case REF_ASZ : asz += shift; break; case REF_BSX : bsx += shift; break; case REF_BSY : bsy += shift; break; case REF_BSZ : bsz += shift; break; case REF_CSX : csx += shift; break; case REF_CSY : csy += shift; break; case REF_CSZ : csz += shift; break; } cell_set_reciprocal(cell, asx, asy, asz, bsx, bsy, bsz, csx, csy, csz); return cell; } static void shift_parameter(struct image *image, int k, double shift) { switch ( k ) { case REF_DIV : image->div += shift; break; } } static Crystal *new_shifted_crystal(Crystal *cr, int refine, double incr_val) { Crystal *cr_new; double r; UnitCell *cell; cr_new = crystal_copy(cr); if ( cr_new == NULL ) { ERROR("Failed to allocate crystal.\n"); return NULL; } crystal_set_image(cr_new, crystal_get_image(cr)); r = crystal_get_profile_radius(cr_new); switch ( refine ) { case REF_ASX : case REF_ASY : case REF_ASZ : case REF_BSX : case REF_BSY : case REF_BSZ : case REF_CSX : case REF_CSY : case REF_CSZ : cell = new_shifted_cell(crystal_get_cell(cr), refine, incr_val); crystal_set_cell(cr_new, cell); break; case REF_R : cell = cell_new_from_cell(crystal_get_cell(cr)); crystal_set_cell(cr_new, cell); crystal_set_profile_radius(cr_new, r + incr_val); break; default : ERROR("Can't shift %i\n", refine); break; } return cr_new; } static void calc_either_side(Crystal *cr, double incr_val, int *valid, long double *vals[3], int refine, PartialityModel pmodel) { RefList *compare; struct image *image = crystal_get_image(cr); if ( (refine != REF_DIV) ) { Crystal *cr_new; /* Crystal properties */ cr_new = new_shifted_crystal(cr, refine, -incr_val); compare = find_intersections(image, cr_new, pmodel); scan_partialities(crystal_get_reflections(cr), compare, valid, vals, 0); cell_free(crystal_get_cell(cr_new)); crystal_free(cr_new); reflist_free(compare); cr_new = new_shifted_crystal(cr, refine, +incr_val); compare = find_intersections(image, cr_new, pmodel); scan_partialities(crystal_get_reflections(cr), compare, valid, vals, 2); cell_free(crystal_get_cell(cr_new)); crystal_free(cr_new); reflist_free(compare); } else { struct image im_moved; /* "Image" properties */ im_moved = *image; shift_parameter(&im_moved, refine, -incr_val); compare = find_intersections(&im_moved, cr, pmodel); scan_partialities(crystal_get_reflections(cr), compare, valid, vals, 0); reflist_free(compare); im_moved = *image; shift_parameter(&im_moved, refine, +incr_val); compare = find_intersections(&im_moved, cr, pmodel); scan_partialities(crystal_get_reflections(cr), compare, valid, vals, 2); reflist_free(compare); } } static double test_gradients(Crystal *cr, double incr_val, int refine, const char *str, const char *file, PartialityModel pmodel, int quiet, int plot) { Reflection *refl; RefListIterator *iter; long double *vals[3]; int i; int *valid; int nref; int n_good, n_invalid, n_small, n_nan, n_bad; RefList *reflections; FILE *fh; int ntot = 0; double total = 0.0; char tmp[32]; double *vec1; double *vec2; int n_line; double cc; reflections = find_intersections(crystal_get_image(cr), cr, pmodel); crystal_set_reflections(cr, reflections); nref = num_reflections(reflections); if ( nref < 10 ) { ERROR("Too few reflections found. Failing test by default.\n"); return 0.0; } vals[0] = malloc(nref*sizeof(long double)); vals[1] = malloc(nref*sizeof(long double)); vals[2] = malloc(nref*sizeof(long double)); if ( (vals[0] == NULL) || (vals[1] == NULL) || (vals[2] == NULL) ) { ERROR("Couldn't allocate memory.\n"); return 0.0; } valid = malloc(nref*sizeof(int)); if ( valid == NULL ) { ERROR("Couldn't allocate memory.\n"); return 0.0; } for ( i=0; ipanels[0].res = 13333.3; image.det->panels[0].clen = 80e-3; image.det->panels[0].coffset = 0.0; image.lambda = ph_en_to_lambda(eV_to_J(8000.0)); image.div = 1e-3; image.bw = 0.01; image.filename = malloc(256); cr = crystal_new(); if ( cr == NULL ) { ERROR("Failed to allocate crystal.\n"); return 1; } crystal_set_mosaicity(cr, 0.0); crystal_set_profile_radius(cr, 0.005e9); crystal_set_image(cr, &image); cell = cell_new_from_parameters(10.0e-9, 10.0e-9, 10.0e-9, deg2rad(90.0), deg2rad(90.0), deg2rad(90.0)); rng = gsl_rng_alloc(gsl_rng_mt19937); for ( i=0; i<2; i++ ) { UnitCell *rot; double val; PartialityModel pmodel; if ( i == 0 ) { pmodel = PMODEL_SPHERE; STATUS("Testing flat sphere model:\n"); } else { pmodel = PMODEL_GAUSSIAN; STATUS("Testing Gaussian model:\n"); } /* No point testing TES model */ orientation = random_quaternion(rng); rot = cell_rotate(cell, orientation); crystal_set_cell(cr, rot); cell_get_reciprocal(rot, &ax, &ay, &az, &bx, &by, &bz, &cx, &cy, &cz); incr_val = incr_frac * image.div; val = test_gradients(cr, incr_val, REF_DIV, "div", "div", pmodel, quiet, plot); if ( val < 0.99 ) fail = 1; incr_val = incr_frac * crystal_get_profile_radius(cr); val = test_gradients(cr, incr_val, REF_R, "R", "R", pmodel, quiet, plot); if ( val < 0.99 ) fail = 1; incr_val = incr_frac * ax; val = test_gradients(cr, incr_val, REF_ASX, "ax*", "x", pmodel, quiet, plot); if ( val < 0.99 ) fail = 1; incr_val = incr_frac * bx; val = test_gradients(cr, incr_val, REF_BSX, "bx*", "x", pmodel, quiet, plot); if ( val < 0.99 ) fail = 1; incr_val = incr_frac * cx; val = test_gradients(cr, incr_val, REF_CSX, "cx*", "x", pmodel, quiet, plot); if ( val < 0.99 ) fail = 1; incr_val = incr_frac * ay; val = test_gradients(cr, incr_val, REF_ASY, "ay*", "y", pmodel, quiet, plot); if ( val < 0.99 ) fail = 1; incr_val = incr_frac * by; val = test_gradients(cr, incr_val, REF_BSY, "by*", "y", pmodel, quiet, plot); if ( val < 0.99 ) fail = 1; incr_val = incr_frac * cy; val = test_gradients(cr, incr_val, REF_CSY, "cy*", "y", pmodel, quiet, plot); if ( val < 0.99 ) fail = 1; incr_val = incr_frac * az; val = test_gradients(cr, incr_val, REF_ASZ, "az*", "z", pmodel, quiet, plot); if ( val < 0.99 ) fail = 1; incr_val = incr_frac * bz; val = test_gradients(cr, incr_val, REF_BSZ, "bz*", "z", pmodel, quiet, plot); if ( val < 0.99 ) fail = 1; incr_val = incr_frac * cz; val = test_gradients(cr, incr_val, REF_CSZ, "cz*", "z", pmodel, quiet, plot); if ( val < 0.99 ) fail = 1; } gsl_rng_free(rng); return fail; }