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|
/*
* reax.c
*
* A new auto-indexer
*
* Copyright © 2012 Deutsches Elektronen-Synchrotron DESY,
* a research centre of the Helmholtz Association.
*
* Authors:
* 2011-2012 Thomas White <taw@physics.org>
*
* 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 <http://www.gnu.org/licenses/>.
*
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <stdlib.h>
#include <stdio.h>
#include <math.h>
#include <assert.h>
#include <fftw3.h>
#include <fenv.h>
#include <gsl/gsl_matrix.h>
#include <gsl/gsl_vector.h>
#include <gsl/gsl_linalg.h>
#include <gsl/gsl_eigen.h>
#include "image.h"
#include "utils.h"
#include "peaks.h"
#include "cell.h"
#include "cell-utils.h"
#include "index.h"
#include "index-priv.h"
/* Minimum number of standard deviations above the mean a peak must be in the
* 1D FT to qualify as a candidate vector */
#define MIN_SIGMAS (3.0)
/* Maximum number of times the angular tolerance that vectors are permitted to
* be together before they get merged by squash_vectors() */
#define INC_TOL_MULTIPLIER (3.0)
/* Maximum number of candidate vectors to find (we will take the best ones) */
#define MAX_CANDIDATES (1024)
struct dvec
{
double x;
double y;
double z;
double th;
double ph;
};
struct reax_candidate
{
struct dvec v; /* This is the vector for the candidate */
double fom;
};
struct reax_search_v
{
unsigned int smin;
unsigned int smax; /* Search for vector in this range */
struct reax_candidate *cand; /* Candidate vectors go here */
int n_cand; /* There are this many candidates */
int max_warned;
};
struct reax_search
{
struct reax_search_v *search; /* Search for these vectors */
int n_search; /* There are this many vectors to find */
double pmax; /* The maximum feature resolution */
};
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 void fill_and_transform(struct dvec *dir, ImageFeatureList *flist,
int nel, double pmax, double *fft_in,
fftw_complex *fft_out, fftw_plan plan,
const char *rg, struct detector *det)
{
int n, i;
for ( i=0; i<nel; i++ ) {
fft_in[i] = 0.0;
}
n = image_feature_count(flist);
for ( i=0; i<n; i++ ) {
struct imagefeature *f;
double val;
int idx;
f = image_get_feature(flist, i);
if ( f == NULL ) continue;
if ( rg != NULL ) {
struct panel *p;
p = find_panel(det, f->fs, 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);
}
static void add_candidate(struct reax_search_v *s, struct reax_candidate *c)
{
int idx;
if ( s->n_cand == MAX_CANDIDATES ) {
if ( !s->max_warned ) {
ERROR("Warning: Too many candidates.\n");
s->max_warned = 1;
}
return;
}
idx = s->n_cand++;
s->cand[idx].v = c->v;
s->cand[idx].fom = c->fom;
}
static double check_dir(struct dvec *dir, ImageFeatureList *flist,
int nel, double pmax, double *fft_in,
fftw_complex *fft_out, fftw_plan plan,
struct reax_search *s,
const char *rg, struct detector *det)
{
int i;
double tot;
fill_and_transform(dir, flist, nel, pmax, fft_in, fft_out,
plan, rg, det);
tot = 0.0;
for ( i=0; i<s->n_search; i++ ) {
double tot = 0.0;
double peak = 0.0;
double peak_mod = 0.0;
double mean;
double sd = 0.0;
int j;
int n = 0;
for ( j=0; j<nel/2+1; j++ ) {
double re, im, am;
re = fft_out[j][0];
im = fft_out[j][1];
am = sqrt(re*re + im*im);
tot += am;
n++;
if ( ( j >= s->search[i].smin )
&& ( j <= s->search[i].smax ) ) {
if ( am > peak ) {
peak = am;
peak_mod = (double)j/(2.0*pmax);
}
}
}
mean = tot/(double)n;
for ( j=0; j<nel/2+1; j++ ) {
double re, im, am;
re = fft_out[j][0];
im = fft_out[j][1];
am = sqrt(re*re + im*im);
sd += pow(am - mean, 2.0);
}
sd = sqrt(sd/(double)n);
/* If sufficiently strong, add to list of candidates */
if ( peak > mean+MIN_SIGMAS*sd ) {
struct reax_candidate c;
c.v.x = dir->x * peak_mod;
c.v.y = dir->y * peak_mod;
c.v.z = dir->z * peak_mod;
c.fom = peak;
add_candidate(&s->search[i], &c);
}
}
return tot;
}
/* Refine a direct space vector. From Clegg (1984)
* with added iteration because more reflections might get included as the
* refinement proceeds. */
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; fi<n; fi++ ) {
struct imagefeature *f;
double val;
double kn, kno;
double xv[3];
int i, j;
f = image_get_feature(flist, fi);
if ( f == NULL ) continue;
kno = f->rx*(*x) + f->ry*(*y) + f->rz*(*z); /* Sorry ... */
kn = nearbyint(kno);
if ( fabs(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);
gsl_vector_free(t);
return dtmax;
}
static void refine_vector(ImageFeatureList *flist, struct dvec *dir)
{
int i;
double sm;
i = 0;
do {
sm = iterate_refine_vector(&dir->x, &dir->y, &dir->z, flist);
i++;
} while ( (sm > 0.001e-9) && (i<10) );
}
static void squash_vectors(struct reax_search *s, double tol)
{
int i;
for ( i=0; i<s->n_search; i++ ) {
struct reax_search_v *sv;
struct reax_candidate *new;
int j, k;
int n_invalid = 0;
int n_copied;
sv = &s->search[i];
for ( j=0; j<sv->n_cand; j++ ) {
for ( k=0; k<sv->n_cand; k++ ) {
struct reax_candidate *v1, *v2;
if ( j == k ) continue;
v1 = &sv->cand[j];
v2 = &sv->cand[k];
if ( angle_between(v1->v.x, v1->v.y, v1->v.z,
v2->v.x, v2->v.y, v2->v.z) < tol )
{
if ( !isnan(v1->fom) && !isnan(v2->fom ) ) {
if ( v1->fom > v2->fom ) {
v2->fom = NAN;
} else {
v1->fom = NAN;
}
n_invalid++;
}
}
}
}
new = calloc(sv->n_cand - n_invalid,
sizeof(struct reax_candidate));
if ( new == NULL ) {
ERROR("Failed to allocate memory for squashed"
" candidate list.\n");
return;
}
n_copied = 0;
for ( j=0; j<sv->n_cand; j++ ) {
if ( !isnan(sv->cand[j].fom) ) {
new[n_copied] = sv->cand[j];
n_copied++;
}
}
assert(sv->n_cand - n_invalid == n_copied);
free(sv->cand);
//STATUS("Search vector %i:", i);
//STATUS(" squashed %i candidates down to %i\n",
// sv->n_cand, n_copied);
sv->n_cand = n_copied;
sv->cand = new;
}
}
static UNUSED void show_vectors(struct reax_search *s, const char *pre)
{
int i;
/* For each direction being searched for */
for ( i=0; i<s->n_search; i++ ) {
int j;
for ( j=0; j<s->search[i].n_cand; j++ ) {
STATUS("%s: %i/%i: %+6.2f %+6.2f %+6.2f nm %.2f\n", pre,
i, j, s->search[i].cand[j].v.x*1e9,
s->search[i].cand[j].v.y*1e9,
s->search[i].cand[j].v.z*1e9,
s->search[i].cand[j].fom);
}
}
}
static void find_candidates(struct reax_private *p,
ImageFeatureList *flist, double pmax,
double *fft_in, fftw_complex *fft_out,
struct reax_search *s,
const char *rg, struct detector *det)
{
int i;
for ( i=0; i<s->n_search; i++ ) {
s->search[i].cand = calloc(MAX_CANDIDATES,
sizeof(struct reax_candidate));
s->search[i].n_cand = 0;
}
for ( i=0; i<p->n_dir; i++ ) {
check_dir(&p->directions[i], flist,
p->nel, pmax, fft_in, fft_out, p->plan,
s, NULL, NULL);
}
squash_vectors(s, INC_TOL_MULTIPLIER*p->angular_inc);
//show_vectors(s, "BEFORE");
for ( i=0; i<s->n_search; i++ ) {
struct reax_search_v *sv;
int j;
sv = &s->search[i];
for ( j=0; j<sv->n_cand; j++ ) {
refine_vector(flist, &sv->cand[j].v);
}
}
//show_vectors(s, "FINAL");
}
/* Set up search parameters to look for all three cell axes */
static struct reax_search *search_all_axes(UnitCell *cell, double pmax)
{
double ax, ay, az;
double bx, by, bz;
double cx, cy, cz;
double mod_a, mod_b, mod_c;
double amin, amax;
double bmin, bmax;
double cmin, cmax;
unsigned int smin, smax;
const double ltol = 10.0; /* Direct space axis length tolerance in % */
struct reax_search *s;
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);
s = malloc(3*sizeof(*s));
s->pmax = pmax;
s->n_search = 3;
s->search = malloc(3*sizeof(struct reax_search_v));
smin = 2.0*pmax * amin; smax = 2.0*pmax * amax;
s->search[0].smin = smin; s->search[0].smax = smax;
s->search[0].max_warned = 0;
smin = 2.0*pmax * bmin; smax = 2.0*pmax * bmax;
s->search[1].smin = smin; s->search[1].smax = smax;
s->search[1].max_warned = 0;
smin = 2.0*pmax * cmin; smax = 2.0*pmax * cmax;
s->search[2].smin = smin; s->search[2].smax = smax;
s->search[2].max_warned = 0;
return s;
}
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;
fill_and_transform(&dir, f, nel, pmax, fft_in, fft_out, plan, 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, 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;
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;
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,
pr->nel, pmax, fft_in, fft_out, plan,
smin, smax, rg, det);
phb = get_model_phase(bx/mb, by/mb, bz/mb, image->features,
pr->nel, pmax, fft_in, fft_out, plan,
smin, smax, rg, det);
phc = get_model_phase(cx/mc, cy/mc, cz/mc, image->features,
pr->nel, pmax, fft_in, fft_out, plan,
smin, smax, rg, det);
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; i<pr->cw; i++ ) {
for ( j=0; j<pr->ch; 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; i<pr->cw; i++ ) {
// for ( j=0; j<pr->ch; 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 UNUSED void refine_all_rigid_groups(struct image *image, UnitCell *cell,
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; i<image->det->num_rigid_groups; i++ ) {
refine_rigid_group(image, cell, image->det->rigid_groups[i],
pmax, fft_in, fft_out, plan, smin, smax,
det, p);
}
}
static double max_feature_resolution(ImageFeatureList *flist)
{
double pmax;
int i, n;
pmax = 0.0;
n = image_feature_count(flist);
for ( i=0; i<n; i++ ) {
struct imagefeature *f;
double val;
f = image_get_feature(flist, i);
if ( f == NULL ) continue;
val = modulus(f->rx, f->ry, f->rz);
if ( val > pmax ) pmax = val;
}
return pmax;
}
static int right_handed_vec(struct rvec a, struct rvec b, struct rvec c)
{
struct rvec aCb;
double aCb_dot_c;
/* "a" cross "b" */
aCb.u = a.v*b.w - a.w*b.v;
aCb.v = - (a.u*b.w - a.w*b.u);
aCb.w = a.u*b.v - a.v*b.u;
/* "a cross b" dot "c" */
aCb_dot_c = aCb.u*c.u + aCb.v*c.v + aCb.w*c.w;
if ( aCb_dot_c > 0.0 ) return 1;
return 0;
}
struct cell_candidate
{
UnitCell *cell;
double fom;
};
struct cell_candidate_list
{
struct cell_candidate *cand;
int n_cand;
};
static int check_twinning(UnitCell *c1, UnitCell *c2, int verbose)
{
int i;
int n_dup;
const int n_trials = 40;
double asx, asy, asz;
double bsx, bsy, bsz;
double csx, csy, csz;
double ax, ay, az;
double bx, by, bz;
double cx, cy, cz;
cell_get_reciprocal(c1, &asx, &asy, &asz,
&bsx, &bsy, &bsz,
&csx, &csy, &csz);
cell_get_cartesian(c2, &ax, &ay, &az, &bx, &by, &bz, &cx, &cy, &cz);
n_dup = 0;
for ( i=0; i<n_trials; i++ ) {
signed int h, k, l;
double h2, k2, l2;
double rx, ry, rz;
double dev;
signed int h2i, k2i, l2i;
h = flat_noise(0, 10);
k = flat_noise(0, 10);
l = flat_noise(0, 10);
/* Position of this (randomly selected)
* reciprocal lattice point */
rx = h*asx + k*bsx + l*csx;
ry = h*asy + k*bsy + l*csy;
rz = h*asz + k*bsz + l*csz;
/* Indices of this point in the basis of the other cell */
h2 = rx*ax + ry*ay + rz*az;
k2 = rx*bx + ry*by + rz*bz;
l2 = rx*cx + ry*cy + rz*cz;
h2i = lrint(h2);
k2i = lrint(k2);
l2i = lrint(l2);
dev = pow(h2i-h2, 2.0) + pow(k2i-k2, 2.0) + pow(l2i-l2, 2.0);
if ( verbose ) {
STATUS("%3i %3i %3i -> %5.2f %5.2f %5.2f -> "
"%3i %3i %3i -> %5.2f\n", h, k, l,
h2, k2, l2, h2i, k2i, l2i, dev);
}
if ( dev < 0.1 ) {
n_dup++;
}
}
if ( verbose ) {
STATUS("%i duplicates.\n", n_dup);
}
if ( n_dup > 10 ) return 1;
return 0;
}
/* Return true if "cnew" accounts for more than 25% of the peaks predicted by
* any of the "ncells" cells in "cells". */
static int twinned(UnitCell *cnew, struct cell_candidate_list *cl)
{
int i;
for ( i=0; i<cl->n_cand; i++ ) {
if ( check_twinning(cnew, cl->cand[i].cell, 0) ) return 1;
}
return 0;
}
static int check_vector_combination(struct dvec *vi, struct dvec *vj,
struct dvec *vk, UnitCell *cell)
{
double ang;
double a, b, c, al, be, ga;
const double angtol = deg2rad(5.0);
cell_get_parameters(cell, &a, &b, &c, &al, &be, &ga);
ang = angle_between(vi->x, vi->y, vi->z, vj->x, vj->y, vj->z);
if ( fabs(ang-ga) > angtol ) return 0;
ang = angle_between(vi->x, vi->y, vi->z, vk->x, vk->y, vk->z);
if ( fabs(ang-be) > angtol ) return 0;
ang = angle_between(vj->x, vj->y, vj->z, vk->x, vk->y, vk->z);
if ( fabs(ang-al) > angtol ) return 0;
return 1;
}
static void add_cell_candidate(struct cell_candidate_list *cl, UnitCell *cnew,
double fom)
{
struct cell_candidate cshift;
int i, cpos;
cpos = cl->n_cand;
for ( i=0; i<cl->n_cand; i++ ) {
if ( fom > cl->cand[i].fom ) {
cpos = i;
break;
}
}
cshift.cell = cnew;
cshift.fom = fom;
for ( i=cpos; i<cl->n_cand; i++ ) {
struct cell_candidate cshift2;
cshift2 = cl->cand[i];
cl->cand[i] = cshift;
cshift = cshift2;
}
if ( cl->n_cand >= MAX_CELL_CANDIDATES ) {
/* "cshift" just fell off the end of the list */
} else {
cl->cand[cl->n_cand++] = cshift;
}
}
static void assemble_cells_from_candidates(struct image *image,
struct reax_search *s,
UnitCell *cell)
{
int i, j, k;
signed int ti, tj, tk;
struct cell_candidate_list cl;
cl.cand = calloc(MAX_CELL_CANDIDATES, sizeof(struct cell_candidate));
if ( cl.cand == NULL ) {
ERROR("Failed to allocate cell candidate list.\n");
return;
}
cl.n_cand = 0;
/* Find candidates for axes 0 and 1 which have the right angle */
for ( i=0; i<s->search[0].n_cand; i++ ) {
for ( j=0; j<s->search[1].n_cand; j++ ) {
for ( k=0; k<s->search[2].n_cand; k++ ) {
for ( ti=-1; ti<=1; ti+=2 ) {
for ( tj=-1; tj<=1; tj+=2 ) {
for ( tk=-1; tk<=1; tk+=2 ) {
struct dvec vi, vj, vk;
struct rvec ai, bi, ci;
UnitCell *cnew;
double fom;
vi = s->search[0].cand[i].v;
vj = s->search[1].cand[j].v;
vk = s->search[2].cand[k].v;
vi.x *= ti; vi.y *= ti; vi.z *= ti;
vj.x *= tj; vj.y *= tj; vj.z *= tj;
vk.x *= tk; vk.y *= tk; vk.z *= tk;
if ( !check_vector_combination(&vi, &vj, &vk, cell) ) continue;
ai.u = vi.x; ai.v = vi.y; ai.w = vi.z;
bi.u = vj.x; bi.v = vj.y; bi.w = vj.z;
ci.u = vk.x; ci.v = vk.y; ci.w = vk.z;
if ( !right_handed_vec(ai, bi, ci) ) continue;
/* We have three vectors with the right angles */
cnew = cell_new_from_direct_axes(ai, bi, ci);
if ( twinned(cnew, &cl) ) {
cell_free(cnew);
continue;
}
peak_lattice_agreement(image, cnew, &fom);
add_cell_candidate(&cl, cnew, fom);
}
}
}
}
}
}
for ( i=0; i<cl.n_cand; i++ ) {
double a, b, c, al, be, ga;
double aA, bA, cA, alA, beA, gaA;
int w = 0;
// STATUS("%i: %f\n", i, cl.cand[i].fom);
cell_get_parameters(cl.cand[i].cell, &a, &b, &c, &al, &be, &ga);
cell_get_parameters(cl.cand[i].cell, &aA, &bA, &cA,
&alA, &beA, &gaA);
if ( (a - aA) > aA/10.0 ) w = 1;
if ( (b - bA) > bA/10.0 ) w = 1;
if ( (c - cA) > cA/10.0 ) w = 1;
if ( (al - alA) > deg2rad(5.0) ) w = 1;
if ( (be - beA) > deg2rad(5.0) ) w = 1;
if ( (ga - gaA) > deg2rad(5.0) ) w = 1;
if ( w ) {
STATUS("This cell is a long way from that sought:\n");
cell_print(cl.cand[i].cell);
}
}
image->ncells = cl.n_cand;
assert(image->ncells <= MAX_CELL_CANDIDATES);
for ( i=0; i<cl.n_cand; i++ ) {
image->candidate_cells[i] = cl.cand[i].cell;
}
free(cl.cand);
}
void reax_index(IndexingPrivate *pp, struct image *image, UnitCell *cell)
{
struct reax_private *p;
double *fft_in;
fftw_complex *fft_out;
double pmax;
struct reax_search *s;
int i;
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));
pmax = max_feature_resolution(image->features);
/* Sanity check */
if ( pmax < 1e4 ) {
fftw_free(fft_in);
fftw_free(fft_out);
return;
}
s = search_all_axes(cell, pmax);
find_candidates(p, image->features, pmax, fft_in, fft_out, s,
NULL, image->det);
// refine_all_rigid_groups(image, image->candidate_cells[0], pmax,
// fft_in, fft_out, p->plan, smin, smax,
// image->det, p);
assemble_cells_from_candidates(image, s, cell);
for ( i=0; i<s->n_search; i++ ) {
free(s->search[i].cand);
}
free(s->search);
free(s);
fftw_free(fft_in);
fftw_free(fft_out);
}
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(1.0);
/* 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; th<M_PI_2; th+=p->angular_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_dir<samp*samp);
dir = &p->directions[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;
free(p->directions);
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);
}
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