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/*
* scaling.c
*
* Scaling
*
* Copyright © 2012-2020 Deutsches Elektronen-Synchrotron DESY,
* a research centre of the Helmholtz Association.
*
* Authors:
* 2010-2017 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 <assert.h>
#include <gsl/gsl_matrix.h>
#include <gsl/gsl_vector.h>
#include <gsl/gsl_linalg.h>
#include <gsl/gsl_eigen.h>
#include <gsl/gsl_fit.h>
#include <gsl/gsl_statistics_double.h>
#include "merge.h"
#include "post-refinement.h"
#include "symmetry.h"
#include "cell.h"
#include "cell-utils.h"
#include "scaling.h"
#include "reflist-utils.h"
struct scale_args
{
RefList *full;
Crystal *crystal;
int flags;
};
struct scale_queue_args
{
int n_started;
int n_done;
Crystal **crystals;
int n_crystals;
struct scale_args task_defaults;
};
static void scale_crystal(void *task, int id)
{
struct scale_args *pargs = task;
scale_one_crystal(pargs->crystal, pargs->full, pargs->flags);
}
static void *get_crystal(void *vqargs)
{
struct scale_args *task;
struct scale_queue_args *qargs = vqargs;
task = malloc(sizeof(struct scale_args));
memcpy(task, &qargs->task_defaults, sizeof(struct scale_args));
task->crystal = qargs->crystals[qargs->n_started];
qargs->n_started++;
return task;
}
static void done_crystal(void *vqargs, void *task)
{
struct scale_queue_args *qa = vqargs;
qa->n_done++;
progress_bar(qa->n_done, qa->n_crystals, "Scaling");
free(task);
}
static double total_log_r(Crystal **crystals, int n_crystals, RefList *full,
int *ninc)
{
int i;
double total = 0.0;
int n = 0;
for ( i=0; i<n_crystals; i++ ) {
double r;
if ( crystal_get_user_flag(crystals[i]) ) continue;
r = log_residual(crystals[i], full, 0, NULL, NULL);
if ( isnan(r) ) continue;
total += r;
n++;
}
if ( ninc != NULL ) *ninc = n;
return total;
}
/* Perform iterative scaling, all the way to convergence */
void scale_all(Crystal **crystals, int n_crystals, int nthreads, int scaleflags)
{
struct scale_args task_defaults;
struct scale_queue_args qargs;
double old_res, new_res;
int niter = 0;
task_defaults.crystal = NULL;
task_defaults.flags = scaleflags;
qargs.task_defaults = task_defaults;
qargs.n_crystals = n_crystals;
qargs.crystals = crystals;
/* Don't have threads which are doing nothing */
if ( n_crystals < nthreads ) nthreads = n_crystals;
new_res = INFINITY;
do {
RefList *full;
int ninc;
double bef_res;
full = merge_intensities(crystals, n_crystals, nthreads,
2, INFINITY, 0, 1);
old_res = new_res;
bef_res = total_log_r(crystals, n_crystals, full, NULL);
qargs.task_defaults.full = full;
qargs.n_started = 0;
qargs.n_done = 0;
run_threads(nthreads, scale_crystal, get_crystal, done_crystal,
&qargs, n_crystals, 0, 0, 0);
new_res = total_log_r(crystals, n_crystals, full, &ninc);
STATUS("Log residual went from %e to %e, %i crystals\n",
bef_res, new_res, ninc);
int i;
double meanB = 0.0;
for ( i=0; i<n_crystals; i++ ) {
meanB += crystal_get_Bfac(crystals[i]);
}
meanB /= n_crystals;
STATUS("Mean B = %e\n", meanB);
free_contribs(full);
reflist_free(full);
niter++;
} while ( (fabs(new_res-old_res) >= 0.01*old_res) && (niter < 10) );
if ( niter == 10 ) {
ERROR("Too many iterations - giving up!\n");
}
}
/* Calculates G and B, by which cr's reflections should be multiplied to fit reference */
int scale_one_crystal(Crystal *cr, const RefList *listR, int flags)
{
const Reflection *reflS;
RefListIterator *iter;
int max_n = 256;
int n = 0;
double *x;
double *y;
double *w;
int r;
double cov00, cov01, cov11, chisq;
int n_esdS = 0;
int n_esdR = 0;
int n_ihS = 0;
int n_ihR = 0;
int n_nanS = 0;
int n_nanR = 0;
int n_infS = 0;
int n_infR = 0;
int n_part = 0;
int n_nom = 0;
int n_red = 0;
RefList *listS = crystal_get_reflections(cr);
UnitCell *cell = crystal_get_cell(cr);
double G, B;
assert(cell != NULL);
assert(listR != NULL);
assert(listS != NULL);
x = malloc(max_n*sizeof(double));
w = malloc(max_n*sizeof(double));
y = malloc(max_n*sizeof(double));
if ( (x==NULL) || (y==NULL) || (w==NULL) ) {
ERROR("Failed to allocate memory for scaling.\n");
return 1;
}
int nb = 0;
for ( reflS = first_refl_const(listS, &iter);
reflS != NULL;
reflS = next_refl_const(reflS, iter) )
{
signed int h, k, l;
const Reflection *reflR;
double IhR, IhS, esdS, pS, LS;
double s;
nb++;
get_indices(reflS, &h, &k, &l);
reflR = find_refl(listR, h, k, l);
if ( reflR == NULL ) {
n_nom++;
continue;
}
s = resolution(cell, h, k, l);
IhR = get_intensity(reflR);
IhS = get_intensity(reflS);
esdS = get_esd_intensity(reflS);
pS = get_partiality(reflS);
LS = get_lorentz(reflS);
/* Problem cases in approximate descending order of severity */
if ( isnan(IhR) ) { n_nanR++; continue; }
if ( isinf(IhR) ) { n_infR++; continue; }
if ( isnan(IhS) ) { n_nanS++; continue; }
if ( isinf(IhS) ) { n_infS++; continue; }
if ( pS < 0.3 ) { n_part++; continue; }
if ( IhS <= 0.0 ) { n_ihS++; continue; }
if ( IhS <= 3.0*esdS ) { n_esdS++; continue; }
if ( IhR <= 0.0 ) { n_ihR++; continue; }
if ( get_redundancy(reflR) < 2 ) { n_red++; continue; }
if ( n == max_n ) {
max_n *= 2;
x = realloc(x, max_n*sizeof(double));
y = realloc(y, max_n*sizeof(double));
w = realloc(w, max_n*sizeof(double));
if ( (x==NULL) || (y==NULL) || (w==NULL) ) {
ERROR("Failed to allocate memory for scaling.\n");
return 1;
}
}
x[n] = s*s;
y[n] = log(LS) + log(IhS) -log(pS) - log(IhR);
w[n] = pS;
n++;
}
if ( n < 2 ) {
if ( flags & SCALE_VERBOSE_ERRORS ) {
ERROR("Not enough reflections for scaling (had %i, but %i remain)\n", nb, n);
if ( n_esdR ) ERROR("%i reference reflection esd\n", n_esdR);
if ( n_esdS ) ERROR("%i subject reflection esd\n", n_esdS);
if ( n_ihR ) ERROR("%i reference reflection intensity\n", n_ihR);
if ( n_red ) ERROR("%i reference reflection redundancy\n", n_red);
if ( n_ihS ) ERROR("%i subject reflection intensity\n", n_ihS);
if ( n_nanR ) ERROR("%i reference reflection nan\n", n_nanR);
if ( n_nanS ) ERROR("%i subject reflection nan\n", n_nanS);
if ( n_infR ) ERROR("%i reference reflection inf\n", n_infR);
if ( n_infS ) ERROR("%i subject reflection inf\n", n_infS);
if ( n_part ) ERROR("%i subject reflection partiality\n", n_part);
if ( n_nom ) ERROR("%i no match in reference list\n", n_nom);
}
free(x);
free(y);
free(w);
return 1;
}
if ( flags & SCALE_NO_B ) {
G = gsl_stats_wmean(w, 1, y, 1, n);
B = 0.0;
r = 0;
} else {
r = gsl_fit_wlinear(x, 1, w, 1, y, 1, n, &G, &B, &cov00, &cov01, &cov11, &chisq);
}
if ( r ) {
ERROR("Scaling failed.\n");
free(x);
free(y);
free(w);
return 1;
}
if ( isnan(G) ) {
if ( flags & SCALE_VERBOSE_ERRORS ) {
ERROR("Scaling gave NaN (%i pairs)\n", n);
if ( n < 10 ) {
int i;
for ( i=0; i<n; i++ ) {
STATUS("%3i %e %e %e\n", i, x[i], y[i], w[i]);
}
}
}
free(x);
free(y);
free(w);
return 1;
}
crystal_set_osf(cr, exp(G));
crystal_set_Bfac(cr, -B);
free(x);
free(y);
free(w);
return 0;
}
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