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/*
* peaks.c
*
* Peak search and other image analysis
*
* Copyright © 2012 Deutsches Elektronen-Synchrotron DESY,
* a research centre of the Helmholtz Association.
* Copyright © 2012 Richard Kirian
*
* Authors:
* 2010-2012 Thomas White <taw@physics.org>
* 2011 Andrew Martin <andrew.martin@desy.de>
* 2011 Richard Kirian
*
* 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 <string.h>
#include <assert.h>
#include <gsl/gsl_statistics_int.h>
#include <pthread.h>
#include <fenv.h>
#include "image.h"
#include "utils.h"
#include "peaks.h"
#include "detector.h"
#include "filters.h"
#include "reflist-utils.h"
#include "beam-parameters.h"
/* Degree of polarisation of X-ray beam */
#define POL (1.0)
static int cull_peaks_in_panel(struct image *image, struct panel *p)
{
int i, n;
int nelim = 0;
n = image_feature_count(image->features);
for ( i=0; i<n; i++ ) {
struct imagefeature *f;
int j, ncol;
f = image_get_feature(image->features, i);
if ( f == NULL ) continue;
if ( f->fs < p->min_fs ) continue;
if ( f->fs > p->max_fs ) continue;
if ( f->ss < p->min_ss ) continue;
if ( f->ss > p->max_ss ) continue;
/* How many peaks are in the same column? */
ncol = 0;
for ( j=0; j<n; j++ ) {
struct imagefeature *g;
if ( i==j ) continue;
g = image_get_feature(image->features, j);
if ( g == NULL ) continue;
if ( p->badrow == 'f' ) {
if ( fabs(f->ss - g->ss) < 2.0 ) ncol++;
} else if ( p->badrow == 's' ) {
if ( fabs(f->fs - g->fs) < 2.0 ) ncol++;
} /* else do nothing */
}
/* More than three? */
if ( ncol <= 3 ) continue;
/* Yes? Delete them all... */
nelim = 0;
for ( j=0; j<n; j++ ) {
struct imagefeature *g;
g = image_get_feature(image->features, j);
if ( g == NULL ) continue;
if ( p->badrow == 'f' ) {
if ( fabs(f->ss - g->ss) < 2.0 ) {
image_remove_feature(image->features,
j);
nelim++;
}
} else if ( p->badrow == 's' ) {
if ( fabs(f->fs - g->ss) < 2.0 ) {
image_remove_feature(image->features,
j);
nelim++;
}
} else {
ERROR("Invalid badrow direction.\n");
abort();
}
}
}
return nelim;
}
/* Post-processing of the peak list to remove noise */
static int cull_peaks(struct image *image)
{
int nelim = 0;
struct panel *p;
int i;
for ( i=0; i<image->det->n_panels; i++ ) {
p = &image->det->panels[i];
if ( p->badrow != '-' ) {
nelim += cull_peaks_in_panel(image, p);
}
}
return nelim;
}
/* Returns non-zero if peak has been vetoed.
* i.e. don't use result if return value is not zero. */
static int integrate_peak(struct image *image, int cfs, int css,
double *pfs, double *pss,
double *intensity, double *sigma,
double ir_inn, double ir_mid, double ir_out)
{
signed int fs, ss;
double lim_sq, out_lim_sq, mid_lim_sq;
double pk_total;
int pk_counts;
double fsct, ssct;
double bg_tot = 0.0;
int bg_counts = 0;
struct panel *p;
double bg_mean, bg_var;
double bg_tot_sq = 0.0;
double var;
double aduph;
p = find_panel(image->det, cfs, css);
if ( p == NULL ) return 1;
if ( p->no_index ) return 1;
aduph = p->adu_per_eV * ph_lambda_to_eV(image->lambda);
lim_sq = pow(ir_inn, 2.0);
mid_lim_sq = pow(ir_mid, 2.0);
out_lim_sq = pow(ir_out, 2.0);
/* Estimate the background */
for ( fs=-ir_out; fs<=+ir_out; fs++ ) {
for ( ss=-ir_out; ss<=+ir_out; ss++ ) {
double val;
uint16_t flags;
struct panel *p2;
int idx;
/* Restrict to annulus */
if ( fs*fs + ss*ss > out_lim_sq ) continue;
if ( fs*fs + ss*ss < mid_lim_sq ) continue;
/* Strayed off one panel? */
p2 = find_panel(image->det, fs+cfs, ss+css);
if ( p2 != p ) return 1;
idx = fs+cfs+image->width*(ss+css);
/* Veto this peak if we tried to integrate in a bad region */
if ( image->flags != NULL ) {
flags = image->flags[idx];
/* It must have all the "good" bits to be valid */
if ( !((flags & image->det->mask_good)
== image->det->mask_good) ) return 1;
/* If it has any of the "bad" bits, reject */
if ( flags & image->det->mask_bad ) return 1;
}
val = image->data[idx];
bg_tot += val;
bg_tot_sq += pow(val, 2.0);
bg_counts++;
}
}
if ( bg_counts == 0 ) return 1;
bg_mean = bg_tot / bg_counts;
bg_var = (bg_tot_sq/bg_counts) - pow(bg_mean, 2.0);
/* Measure the peak */
pk_total = 0.0;
pk_counts = 0;
fsct = 0.0; ssct = 0.0;
for ( fs=-ir_inn; fs<=+ir_inn; fs++ ) {
for ( ss=-ir_inn; ss<=+ir_inn; ss++ ) {
double val;
uint16_t flags;
struct panel *p2;
int idx;
/* Inner mask radius */
if ( fs*fs + ss*ss > lim_sq ) continue;
/* Strayed off one panel? */
p2 = find_panel(image->det, fs+cfs, ss+css);
if ( p2 != p ) return 1;
idx = fs+cfs+image->width*(ss+css);
/* Veto this peak if we tried to integrate in a bad region */
if ( image->flags != NULL ) {
flags = image->flags[idx];
/* It must have all the "good" bits to be valid */
if ( !((flags & image->det->mask_good)
== image->det->mask_good) ) return 1;
/* If it has any of the "bad" bits, reject */
if ( flags & image->det->mask_bad ) return 1;
}
val = image->data[idx] - bg_mean;
pk_counts++;
pk_total += val;
fsct += val*(cfs+fs);
ssct += val*(css+ss);
}
}
if ( pk_counts == 0 ) return 1;
*pfs = ((double)fsct / pk_total) + 0.5;
*pss = ((double)ssct / pk_total) + 0.5;
var = pk_counts * bg_var;
var += aduph * pk_total;
if ( var < 0.0 ) return 1;
if ( intensity != NULL ) *intensity = pk_total;
if ( sigma != NULL ) *sigma = sqrt(var);
return 0;
}
static void search_peaks_in_panel(struct image *image, float threshold,
float min_gradient, float min_snr,
struct panel *p,
double ir_inn, double ir_mid, double ir_out)
{
int fs, ss, stride;
float *data;
double d;
int idx;
double f_fs = 0.0;
double f_ss = 0.0;
double intensity = 0.0;
double sigma = 0.0;
int nrej_dis = 0;
int nrej_pro = 0;
int nrej_fra = 0;
int nrej_bad = 0;
int nrej_snr = 0;
int nacc = 0;
int ncull;
const int pws = p->peak_sep/2;
data = image->data;
stride = image->width;
for ( fs = p->min_fs+1; fs <= p->max_fs-1; fs++ ) {
for ( ss = p->min_ss+1; ss <= p->max_ss-1; ss++ ) {
double dx1, dx2, dy1, dy2;
double dxs, dys;
double grad;
int mask_fs, mask_ss;
int s_fs, s_ss;
double max;
unsigned int did_something;
int r;
/* Overall threshold */
if ( data[fs+stride*ss] < threshold ) continue;
/* Get gradients */
dx1 = data[fs+stride*ss] - data[(fs+1)+stride*ss];
dx2 = data[(fs-1)+stride*ss] - data[fs+stride*ss];
dy1 = data[fs+stride*ss] - data[(fs+1)+stride*(ss+1)];
dy2 = data[fs+stride*(ss-1)] - data[fs+stride*ss];
/* Average gradient measurements from both sides */
dxs = ((dx1*dx1) + (dx2*dx2)) / 2;
dys = ((dy1*dy1) + (dy2*dy2)) / 2;
/* Calculate overall gradient */
grad = dxs + dys;
if ( grad < min_gradient ) continue;
mask_fs = fs;
mask_ss = ss;
do {
max = data[mask_fs+stride*mask_ss];
did_something = 0;
for ( s_ss=biggest(mask_ss-pws/2,
p->min_ss);
s_ss<=smallest(mask_ss+pws/2,
p->max_ss);
s_ss++ ) {
for ( s_fs=biggest(mask_fs-pws/2,
p->min_fs);
s_fs<=smallest(mask_fs+pws/2,
p->max_fs);
s_fs++ ) {
if ( data[s_fs+stride*s_ss] > max ) {
max = data[s_fs+stride*s_ss];
mask_fs = s_fs;
mask_ss = s_ss;
did_something = 1;
}
}
}
/* Abort if drifted too far from the foot point */
if ( distance(mask_fs, mask_ss, fs, ss) >
p->peak_sep/2.0 )
{
break;
}
} while ( did_something );
/* Too far from foot point? */
if ( distance(mask_fs, mask_ss, fs, ss) > p->peak_sep/2.0 ) {
nrej_dis++;
continue;
}
/* Should be enforced by bounds used above. Muppet check. */
assert(mask_fs <= p->max_fs);
assert(mask_ss <= p->max_ss);
assert(mask_fs >= p->min_fs);
assert(mask_ss >= p->min_ss);
/* Centroid peak and get better coordinates. */
r = integrate_peak(image, mask_fs, mask_ss,
&f_fs, &f_ss, &intensity, &sigma,
ir_inn, ir_mid, ir_out);
if ( r ) {
/* Bad region - don't detect peak */
nrej_bad++;
continue;
}
/* It is possible for the centroid to fall outside the image */
if ( (f_fs < p->min_fs) || (f_fs > p->max_fs)
|| (f_ss < p->min_ss) || (f_ss > p->max_ss) ) {
nrej_fra++;
continue;
}
if ( fabs(intensity)/sigma < min_snr ) {
nrej_snr++;
continue;
}
/* Check for a nearby feature */
image_feature_closest(image->features, f_fs, f_ss, &d, &idx);
if ( d < p->peak_sep/2.0 ) {
nrej_pro++;
continue;
}
/* Add using "better" coordinates */
image_add_feature(image->features, f_fs, f_ss, image, intensity,
NULL);
nacc++;
}
}
if ( image->det != NULL ) {
ncull = cull_peaks(image);
nacc -= ncull;
} else {
STATUS("Not culling peaks because I don't have a "
"detector geometry file.\n");
ncull = 0;
}
// STATUS("%i accepted, %i box, %i proximity, %i outside panel, "
// "%i in bad regions, %i with SNR < %g, %i badrow culled.\n",
// nacc, nrej_dis, nrej_pro, nrej_fra, nrej_bad,
// nrej_snr, min_snr, ncull);
}
void search_peaks(struct image *image, float threshold, float min_gradient,
float min_snr, double ir_inn, double ir_mid, double ir_out)
{
int i;
if ( image->features != NULL ) {
image_feature_list_free(image->features);
}
image->features = image_feature_list_new();
for ( i=0; i<image->det->n_panels; i++ ) {
struct panel *p = &image->det->panels[i];
if ( p->no_index ) continue;
search_peaks_in_panel(image, threshold, min_gradient,
min_snr, p, ir_inn, ir_mid, ir_out);
}
}
double peak_lattice_agreement(struct image *image, UnitCell *cell, double *pst)
{
int i;
int n_feat = 0;
int n_sane = 0;
double ax, ay, az;
double bx, by, bz;
double cx, cy, cz;
double min_dist = 0.25;
double stot = 0.0;
/* Round towards nearest */
fesetround(1);
/* Cell basis vectors for this image */
cell_get_cartesian(cell, &ax, &ay, &az, &bx, &by, &bz, &cx, &cy, &cz);
/* Loop over peaks, checking proximity to nearest reflection */
for ( i=0; i<image_feature_count(image->features); i++ ) {
struct imagefeature *f;
struct rvec q;
double h,k,l,hd,kd,ld;
/* Assume all image "features" are genuine peaks */
f = image_get_feature(image->features, i);
if ( f == NULL ) continue;
n_feat++;
/* Reciprocal space position of found peak */
q = get_q(image, f->fs, f->ss, NULL, 1.0/image->lambda);
/* Decimal and fractional Miller indices of nearest
* reciprocal lattice point */
hd = q.u * ax + q.v * ay + q.w * az;
kd = q.u * bx + q.v * by + q.w * bz;
ld = q.u * cx + q.v * cy + q.w * cz;
h = lrint(hd);
k = lrint(kd);
l = lrint(ld);
/* Check distance */
if ( (fabs(h - hd) < min_dist) && (fabs(k - kd) < min_dist)
&& (fabs(l - ld) < min_dist) )
{
double sval;
n_sane++;
sval = pow(h-hd, 2.0) + pow(k-kd, 2.0) + pow(l-ld, 2.0);
stot += 1.0 - sval;
continue;
}
}
*pst = stot;
return (double)n_sane / (float)n_feat;
}
int peak_sanity_check(struct image *image)
{
double stot;
/* 0 means failed test, 1 means passed test */
return peak_lattice_agreement(image, image->indexed_cell, &stot) >= 0.5;
}
struct integr_ind
{
double res;
Reflection *refl;
};
static int compare_resolution(const void *av, const void *bv)
{
const struct integr_ind *a = av;
const struct integr_ind *b = bv;
return a->res > b->res;
}
static struct integr_ind *sort_reflections(RefList *list, UnitCell *cell,
int *np)
{
struct integr_ind *il;
Reflection *refl;
RefListIterator *iter;
int i, n;
n = num_reflections(list);
*np = 0; /* For now */
if ( n == 0 ) return NULL;
il = calloc(n, sizeof(struct integr_ind));
if ( il == NULL ) return NULL;
i = 0;
for ( refl = first_refl(list, &iter);
refl != NULL;
refl = next_refl(refl, iter) )
{
signed int h, k, l;
double res;
get_indices(refl, &h, &k, &l);
res = resolution(cell, h, k, l);
il[i].res = res;
il[i].refl = refl;
i++;
assert(i <= n);
}
qsort(il, n, sizeof(struct integr_ind), compare_resolution);
*np = n;
return il;
}
/* Integrate the list of predicted reflections in "image" */
void integrate_reflections(struct image *image, int use_closer, int bgsub,
double min_snr,
double ir_inn, double ir_mid, double ir_out)
{
struct integr_ind *il;
int n, i;
double av = 0.0;
int first = 1;
il = sort_reflections(image->reflections, image->indexed_cell, &n);
if ( il == NULL ) {
ERROR("Couldn't sort reflections\n");
return;
}
for ( i=0; i<n; i++ ) {
double fs, ss, intensity;
double d;
int idx;
double sigma, snr;
double pfs, pss;
int r;
Reflection *refl;
signed int h, k, l;
refl = il[i].refl;
get_detector_pos(refl, &pfs, &pss);
get_indices(refl, &h, &k, &l);
/* Is there a really close feature which was detected? */
if ( use_closer ) {
struct imagefeature *f;
if ( image->features != NULL ) {
f = image_feature_closest(image->features,
pfs, pss, &d, &idx);
} else {
f = NULL;
}
/* FIXME: Horrible hardcoded value */
if ( (f != NULL) && (d < 10.0) ) {
pfs = f->fs;
pss = f->ss;
}
}
r = integrate_peak(image, pfs, pss, &fs, &ss,
&intensity, &sigma, ir_inn, ir_mid, ir_out);
/* Record intensity and set redundancy to 1 on success */
if ( r == 0 ) {
set_intensity(refl, intensity);
set_esd_intensity(refl, sigma);
set_redundancy(refl, 1);
} else {
set_redundancy(refl, 0);
}
snr = intensity / sigma;
if ( snr > 1.0 ) {
if ( first ) {
av = snr;
first = 0;
} else {
av = av + 0.1*(snr - av);
}
//STATUS("%5.2f A, %5.2f, av %5.2f\n",
// 1e10/il[i].res, snr, av);
//if ( av < 1.0 ) break;
}
}
image->diffracting_resolution = 0.0;
free(il);
}
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