diff options
author | Thomas White <taw@physics.org> | 2017-07-24 11:41:40 +0200 |
---|---|---|
committer | Thomas White <taw@physics.org> | 2017-07-24 11:41:40 +0200 |
commit | 86d1ad63431c33019f1c6214588eddc83be7be70 (patch) | |
tree | 6ce8dba53fe5a57aca1aa8e390813c16352edb4d | |
parent | 1585396d6bbe3375d21b2906251ee6762a6fcca4 (diff) |
Formatting/copyright dates
-rw-r--r-- | libcrystfel/src/taketwo.c | 172 |
1 files changed, 86 insertions, 86 deletions
diff --git a/libcrystfel/src/taketwo.c b/libcrystfel/src/taketwo.c index ecd2c447..7d934ceb 100644 --- a/libcrystfel/src/taketwo.c +++ b/libcrystfel/src/taketwo.c @@ -3,13 +3,13 @@ * * Rewrite of TakeTwo algorithm (Acta D72 (8) 956-965) for CrystFEL * - * Copyright © 2016 Helen Ginn - * Copyright © 2016 Deutsches Elektronen-Synchrotron DESY, - * a research centre of the Helmholtz Association. + * Copyright © 2016-2017 Helen Ginn + * Copyright © 2016-2017 Deutsches Elektronen-Synchrotron DESY, + * a research centre of the Helmholtz Association. * * Authors: - * 2016 Helen Ginn <helen@strubi.ox.ac.uk> - * 2016 Thomas White <taw@physics.org> + * 2016-2017 Helen Ginn <helen@strubi.ox.ac.uk> + * 2016-2017 Thomas White <taw@physics.org> * * This file is part of CrystFEL. * @@ -382,7 +382,7 @@ static char *get_chiral_holohedry(UnitCell *cell) default: break; } - + return pgout; } @@ -394,13 +394,13 @@ static SymOpList *sym_ops_for_cell(UnitCell *cell) char *pg = get_chiral_holohedry(cell); rawList = get_pointgroup(pg); free(pg); - + return rawList; } static int rot_mats_are_similar(gsl_matrix *rot1, gsl_matrix *rot2, - gsl_matrix *sub, gsl_matrix *mul, - double *score, struct TakeTwoCell *cell) + gsl_matrix *sub, gsl_matrix *mul, + double *score, struct TakeTwoCell *cell) { double tr; @@ -419,30 +419,30 @@ static int symm_rot_mats_are_similar(gsl_matrix *rot1, gsl_matrix *rot2, struct TakeTwoCell *cell) { int i; - + gsl_matrix *sub = gsl_matrix_calloc(3, 3); gsl_matrix *mul = gsl_matrix_calloc(3, 3); for (i = 0; i < cell->numOps; i++) { gsl_matrix *testRot = gsl_matrix_alloc(3, 3); gsl_matrix *symOp = cell->rotSymOps[i]; - + gsl_blas_dgemm(CblasNoTrans, CblasNoTrans, 1.0, rot1, symOp, 0.0, testRot); - + if (rot_mats_are_similar(testRot, rot2, sub, mul, NULL, cell)) { gsl_matrix_free(testRot); gsl_matrix_free(sub); gsl_matrix_free(mul); return 1; } - - gsl_matrix_free(testRot); + + gsl_matrix_free(testRot); } - + gsl_matrix_free(sub); gsl_matrix_free(mul); - + return 0; } @@ -536,7 +536,7 @@ static int obs_shares_spot_w_array(struct SpotVec *obs_vecs, int test_idx, int *members, int num) { int i; - + struct SpotVec *her_obs = &obs_vecs[test_idx]; for ( i=0; i<num; i++ ) { @@ -581,11 +581,11 @@ static int obs_vecs_match_angles(struct SpotVec *her_obs, double angle_diff = fabs(theory_angle - obs_angle); if ( angle_diff < cell->options->angle_tol ) { - // in the case of a brief check only + // in the case of a brief check only if (!her_match_idxs || !his_match_idxs) { return 1; } - + /* If the angles are too close to 0 or 180, one axis ill-determined */ if (theory_angle < min_angle || @@ -594,11 +594,11 @@ static int obs_vecs_match_angles(struct SpotVec *her_obs, } // check the third vector - + struct rvec theory_diff = diff_vec(*his_match, *her_match); struct rvec obs_diff = diff_vec(his_obs->obsvec, her_obs->obsvec); - + theory_angle = rvec_angle(*her_match, theory_diff); obs_angle = rvec_angle(her_obs->obsvec, obs_diff); @@ -606,15 +606,15 @@ static int obs_vecs_match_angles(struct SpotVec *her_obs, if (fabs(obs_angle - theory_angle) > ANGLE_TOLERANCE) { continue; } - + theory_angle = rvec_angle(*his_match, theory_diff); obs_angle = rvec_angle(his_obs->obsvec, obs_diff); - + if (fabs(obs_angle - theory_angle) > ANGLE_TOLERANCE) { continue; } - + size_t new_size = (*match_count + 1) * sizeof(int); if (her_match_idxs && his_match_idxs) @@ -654,7 +654,7 @@ static signed int finish_solution(gsl_matrix *rot, struct SpotVec *obs_vecs, { gsl_matrix *sub = gsl_matrix_calloc(3, 3); gsl_matrix *mul = gsl_matrix_calloc(3, 3); - + gsl_matrix **rotations = malloc(sizeof(*rotations)* pow(member_num, 2) - member_num); @@ -720,7 +720,7 @@ static int weed_duplicate_matches(struct SpotVec *her_obs, { int num_occupied = 0; gsl_matrix **old_mats = calloc(*match_count, sizeof(gsl_matrix *)); - + if (old_mats == NULL) { apologise(); @@ -729,11 +729,11 @@ static int weed_duplicate_matches(struct SpotVec *her_obs, signed int i, j; int duplicates = 0; - + for (i = *match_count - 1; i >= 0; i--) { int her_match = (*her_match_idxs)[i]; int his_match = (*his_match_idxs)[i]; - + struct rvec i_obsvec = her_obs->obsvec; struct rvec j_obsvec = his_obs->obsvec; struct rvec i_cellvec = her_obs->matches[her_match]; @@ -743,7 +743,7 @@ static int weed_duplicate_matches(struct SpotVec *her_obs, i_cellvec, j_cellvec, cell); int found = 0; - + for (j = 0; j < num_occupied; j++) { if (old_mats[j] && mat && symm_rot_mats_are_similar(old_mats[j], mat, cell)) @@ -752,21 +752,21 @@ static int weed_duplicate_matches(struct SpotVec *her_obs, (*her_match_idxs)[i] = -1; (*his_match_idxs)[i] = -1; found = 1; - + duplicates++; gsl_matrix_free(mat); break; } } - + if (!found) { // we have not found a duplicate, add to list. old_mats[num_occupied] = mat; num_occupied++; } } - + for (i = 0; i < num_occupied; i++) { if (old_mats[i]) { gsl_matrix_free(old_mats[i]); @@ -774,7 +774,7 @@ static int weed_duplicate_matches(struct SpotVec *her_obs, } free(old_mats); - + return 1; } @@ -786,9 +786,9 @@ static signed int find_next_index(gsl_matrix *rot, int *obs_members, int obs_vec_count = cell->obs_vec_count; gsl_matrix *sub = gsl_matrix_calloc(3, 3); gsl_matrix *mul = gsl_matrix_calloc(3, 3); - + int i, j, k; - + for ( i=start; i<obs_vec_count; i++ ) { /* first we check for a shared spot - harshest condition */ @@ -796,23 +796,23 @@ static signed int find_next_index(gsl_matrix *rot, int *obs_members, member_num); if ( !shared ) continue; - + int skip = 0; for ( j=0; j<member_num && skip == 0; j++ ) { if (i == obs_members[j]) { skip = 1; } } - + if (skip) { continue; } int all_ok = 1; int matched = -1; - + for ( j=0; j<member_num && all_ok; j++ ) { - + struct SpotVec *me = &obs_vecs[i]; struct SpotVec *you = &obs_vecs[obs_members[j]]; struct rvec you_cell = you->matches[match_members[j]]; @@ -823,24 +823,24 @@ static signed int find_next_index(gsl_matrix *rot, int *obs_members, int one_is_okay = 0; for ( k=0; k<me->match_num; k++ ) { - + gsl_matrix *test_rot; - - struct rvec me_cell = me->matches[k]; + + struct rvec me_cell = me->matches[k]; test_rot = generate_rot_mat(me_obs, you_obs, me_cell, you_cell, - cell); + cell); double trace = 0; int ok = rot_mats_are_similar(rot, test_rot, sub, mul, &trace, cell); - + gsl_matrix_free(test_rot); if (ok) { one_is_okay = 1; - + if (matched >= 0 && k == matched) { *match_found = k; } else if (matched < 0) { @@ -848,10 +848,10 @@ static signed int find_next_index(gsl_matrix *rot, int *obs_members, } else { one_is_okay = 0; break; - } + } } } - + if (!one_is_okay) { all_ok = 0; break; @@ -860,12 +860,12 @@ static signed int find_next_index(gsl_matrix *rot, int *obs_members, if (all_ok) { - + for ( j=0; j<member_num; j++ ) { // STATUS("%i ", obs_members[j]); } //STATUS("%i\n", i); - + return i; } } @@ -943,7 +943,7 @@ static int grow_network(gsl_matrix *rot, int obs_idx1, int obs_idx2, match_members[member_num] = match_found; member_num++; - + if (member_num > *max_members) { *max_members = member_num; } @@ -954,7 +954,7 @@ static int grow_network(gsl_matrix *rot, int obs_idx1, int obs_idx2, finish_solution(rot, obs_vecs, obs_members, match_members, member_num, cell); - + return ( member_num > cell->options->member_thresh ); } @@ -966,7 +966,7 @@ static int start_seed(int i, int j, int i_match, int j_match, struct SpotVec *obs_vecs = *(cell->obs_vecs); gsl_matrix *rot_mat; - + rot_mat = generate_rot_mat(obs_vecs[i].obsvec, obs_vecs[j].obsvec, obs_vecs[i].matches[i_match], @@ -988,7 +988,7 @@ static int find_seed(gsl_matrix **rotation, struct TakeTwoCell *cell) { struct SpotVec *obs_vecs = *(cell->obs_vecs); int obs_vec_count = cell->obs_vec_count; - + /* META: Maximum achieved maximum network membership */ int max_max_members = 0; gsl_matrix *best_rotation = NULL; @@ -1017,7 +1017,7 @@ static int find_seed(gsl_matrix **rotation, struct TakeTwoCell *cell) int *i_idx = 0; int *j_idx = 0; int matches; - + /* Check to see if any angles match from the cell vectors */ obs_vecs_match_angles(&obs_vecs[i], &obs_vecs[j], &i_idx, &j_idx, &matches, cell); @@ -1097,7 +1097,7 @@ static int generate_rotation_sym_ops(struct TakeTwoCell *ttCell) /* Now we must convert these into rotation matrices rather than hkl * transformations (affects triclinic, monoclinic, rhombohedral and * hexagonal space groups only) */ - + double asx, asy, asz; double bsx, bsy, bsz; double csx, csy, csz; @@ -1111,59 +1111,59 @@ static int generate_rotation_sym_ops(struct TakeTwoCell *ttCell) cell_get_cartesian(ttCell->cell, &asx, &asy, &asz, &bsx, &bsy, &bsz, &csx, &csy, &csz); - + set_gsl_matrix(cart, asx, asy, asz, bsx, bsy, bsz, csx, csy, csz); int i, j, k; int numOps = num_equivs(rawList, NULL); - + ttCell->rotSymOps = malloc(numOps * sizeof(gsl_matrix *)); ttCell->numOps = numOps; - + if (ttCell->rotSymOps == NULL) { apologise(); return 0; } - + for (i = 0; i < numOps; i++) { gsl_matrix *symOp = gsl_matrix_alloc(3, 3); IntegerMatrix *op = get_symop(rawList, NULL, i); - + for (j = 0; j < 3; j++) { for (k = 0; k < 3; k++) { gsl_matrix_set(symOp, j, k, intmat_get(op, j, k)); } } - + gsl_matrix *first = gsl_matrix_calloc(3, 3); gsl_matrix *second = gsl_matrix_calloc(3, 3); - + /* Each equivalence is of the form: - cartesian * symOp * reciprocal. - First multiplication: symOp * reciprocal */ - + cartesian * symOp * reciprocal. + First multiplication: symOp * reciprocal */ + gsl_blas_dgemm(CblasNoTrans, CblasNoTrans, 1.0, symOp, recip, 0.0, first); - + /* Second multiplication: cartesian * first */ - + gsl_blas_dgemm(CblasNoTrans, CblasNoTrans, 1.0, cart, first, 0.0, second); - + ttCell->rotSymOps[i] = second; - + gsl_matrix_free(symOp); gsl_matrix_free(first); } gsl_matrix_free(cart); gsl_matrix_free(recip); - + free_symoplist(rawList); - + return 1; } @@ -1192,7 +1192,7 @@ static int match_obs_to_cell_vecs(struct rvec *cell_vecs, int cell_vec_count, int count = 0; struct sortme *for_sort = NULL; - + for ( j=0; j<cell_vec_count; j++ ) { /* get distance for unit cell vector */ double cell_length = rvec_length(cell_vecs[j]); @@ -1217,16 +1217,16 @@ static int match_obs_to_cell_vecs(struct rvec *cell_vecs, int cell_vec_count, } /* Pointers to relevant things */ - + struct rvec **match_array; int *match_count; - + if (!is_asymmetric) { match_array = &(obs_vecs[i].matches); match_count = &(obs_vecs[i].match_num); } else { match_array = &(obs_vecs[i].asym_matches); - match_count = &(obs_vecs[i].asym_match_num); + match_count = &(obs_vecs[i].asym_match_num); } /* Sort in order to get most agreeable matches first */ @@ -1235,7 +1235,7 @@ static int match_obs_to_cell_vecs(struct rvec *cell_vecs, int cell_vec_count, *match_count = count; for ( j=0; j<count; j++ ) { (*match_array)[j] = for_sort[j].v; - + } free(for_sort); } @@ -1347,12 +1347,12 @@ static int gen_theoretical_vecs(UnitCell *cell, struct rvec **cell_vecs, int asymmetric = 0; get_asymm(rawList, h, k, l, &_h, &_k, &_l); - + if (h == _h && k == _k && l == _l) { asymmetric = 1; asym_count++; } - + cell_vec.u = h*asx + k*bsx + l*csx; cell_vec.v = h*asy + k*bsy + l*csy; cell_vec.w = h*asz + k*bsz + l*csz; @@ -1376,11 +1376,11 @@ static int gen_theoretical_vecs(UnitCell *cell, struct rvec **cell_vecs, } else { *cell_vecs = temp_cell_vecs; (*cell_vecs)[count - 1] = cell_vec; - + if (!asymmetric) { continue; } - + *asym_vecs = temp_asym_vecs; (*asym_vecs)[asym_count - 1] = cell_vec; } @@ -1390,7 +1390,7 @@ static int gen_theoretical_vecs(UnitCell *cell, struct rvec **cell_vecs, *vec_count = count; *asym_vec_count = asym_count; - + free_symoplist(rawList); @@ -1401,7 +1401,7 @@ static int gen_theoretical_vecs(UnitCell *cell, struct rvec **cell_vecs, /* ------------------------------------------------------------------------ * cleanup functions - called from run_taketwo(). * ------------------------------------------------------------------------*/ - + static void cleanup_taketwo_obs_vecs(struct SpotVec *obs_vecs, int obs_vec_count) { @@ -1453,7 +1453,7 @@ static UnitCell *run_taketwo(UnitCell *cell, struct taketwo_options *opts, struct SpotVec *obs_vecs = NULL; int success = 0; gsl_matrix *solution = NULL; - + struct TakeTwoCell ttCell; ttCell.cell = cell; ttCell.options = opts; @@ -1498,7 +1498,7 @@ static UnitCell *run_taketwo(UnitCell *cell, struct taketwo_options *opts, gsl_matrix_free(solution); cleanup_taketwo_obs_vecs(obs_vecs, obs_vec_count); cleanup_taketwo_cell(&ttCell); - + return result; } @@ -1523,7 +1523,7 @@ int taketwo_index(struct image *image, struct taketwo_options *opts, void *priv) if (opts->len_tol < 0) { opts->len_tol = RECIP_TOLERANCE; } - + if (opts->angle_tol < 0) { opts->angle_tol = ANGLE_TOLERANCE; } @@ -1531,7 +1531,7 @@ int taketwo_index(struct image *image, struct taketwo_options *opts, void *priv) if (opts->trace_tol < 0) { opts->trace_tol = TRACE_TOLERANCE; } - + opts->trace_tol = sqrt(4.0*(1.0-cos(opts->trace_tol))); rlps = malloc((image_feature_count(image->features)+1)*sizeof(struct rvec)); |