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|
/*
* partialator.c
*
* Scaling and post refinement for coherent nanocrystallography
*
* Copyright © 2012-2018 Deutsches Elektronen-Synchrotron DESY,
* a research centre of the Helmholtz Association.
*
* Authors:
* 2010-2018 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 <stdarg.h>
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <unistd.h>
#include <getopt.h>
#include <assert.h>
#include <pthread.h>
#include <gsl/gsl_errno.h>
#include <sys/stat.h>
#include <image.h>
#include <utils.h>
#include <symmetry.h>
#include <stream.h>
#include <geometry.h>
#include <peaks.h>
#include <thread-pool.h>
#include <reflist.h>
#include <reflist-utils.h>
#include <cell.h>
#include <cell-utils.h>
#include "scaling.h"
#include "post-refinement.h"
#include "merge.h"
#include "rejection.h"
struct csplit_hash_entry
{
int n_events;
char **events;
int *datasets;
};
#define CSPLIT_HASH_MAX (65521)
struct custom_split
{
int n_events_total;
int n_datasets;
char **dataset_names;
struct csplit_hash_entry hashes[CSPLIT_HASH_MAX];
};
static int csplit_hash(const char *id)
{
int i;
size_t len = strlen(id);
int h = 0;
for ( i=0; i<len; i++ ) {
h = (h*31 + id[i]) % CSPLIT_HASH_MAX;
}
assert(h < CSPLIT_HASH_MAX);
return h;
}
static void add_to_hash_entry(struct csplit_hash_entry *he, const char *id,
int dsn)
{
he->events = realloc(he->events, (1+he->n_events)*sizeof(char *));
he->datasets = realloc(he->datasets, (1+he->n_events)*sizeof(int));
if ( (he->events == NULL) || (he->datasets == NULL) ) {
ERROR("Failed to grow csplit hash entry.\n");
abort();
}
he->events[he->n_events] = strdup(id);
he->datasets[he->n_events] = dsn;
he->n_events++;
}
static signed int find_dsn_for_id(struct custom_split *csplit, const char *id)
{
int hash = csplit_hash(id);
int i;
struct csplit_hash_entry *he = &csplit->hashes[hash];
for ( i=0; i<he->n_events; i++ ) {
if ( strcmp(he->events[i], id) == 0 ) {
return he->datasets[i];
}
}
return -1;
}
/* Find dataset number */
static int find_dsn(struct custom_split *csplit, const char *ds)
{
int i;
for ( i=0; i<csplit->n_datasets; i++ ) {
if ( strcmp(csplit->dataset_names[i], ds) == 0 ) {
return i;
}
}
csplit->dataset_names = realloc(csplit->dataset_names,
(1+csplit->n_datasets)*sizeof(char *));
if ( csplit->dataset_names == NULL ) {
ERROR("Failed to grow list of dataset names\n");
abort();
}
csplit->n_datasets++;
csplit->dataset_names[csplit->n_datasets-1] = strdup(ds);
return csplit->n_datasets-1;
}
/* Add arbitrary ID 'id' to dataset table with name 'ds' */
static void add_to_csplit(struct custom_split *csplit, const char *id,
const char *ds)
{
int dsn;
int hash;
struct csplit_hash_entry *he;
dsn = find_dsn(csplit, ds);
hash = csplit_hash(id);
he = &csplit->hashes[hash];
add_to_hash_entry(he, id, dsn);
csplit->n_events_total++;
}
/* Write two-way split results (i.e. for CC1/2 etc) for this list of crystals */
static void write_split(Crystal **crystals, int n_crystals, const char *outfile,
int nthreads, PartialityModel pmodel,
int min_measurements, SymOpList *sym, double push_res)
{
char tmp[1024];
RefList *split;
Crystal *crystals1[n_crystals];
Crystal *crystals2[n_crystals];
int n_crystals1 = 0;
int n_crystals2 = 0;
int i;
for ( i=0; i<n_crystals; i++ ) {
if ( i % 2 ) {
crystals1[n_crystals1] = crystals[i];
n_crystals1++;
} else {
crystals2[n_crystals2] = crystals[i];
n_crystals2++;
}
}
snprintf(tmp, 1024, "%s1", outfile);
split = merge_intensities(crystals1, n_crystals1, nthreads,
min_measurements, push_res, 1, 0);
if ( split == NULL ) {
ERROR("Not enough crystals for two way split!\n");
return;
}
STATUS("Writing two-way split to %s ", tmp);
write_reflist_2(tmp, split, sym);
free_contribs(split);
reflist_free(split);
snprintf(tmp, 1024, "%s2", outfile);
split = merge_intensities(crystals2, n_crystals2, nthreads,
min_measurements, push_res, 1, 0);
STATUS("and %s\n", tmp);
write_reflist_2(tmp, split, sym);
free_contribs(split);
reflist_free(split);
}
static char *insert_into_filename(const char *fn, const char *add)
{
int i;
char *out;
out = malloc(strlen(fn) + strlen(add) + 2);
if ( out == NULL ) return NULL;
for ( i=strlen(fn); i>0; i-- ) {
if ( fn[i] == '.' ) {
strncpy(out, fn, i);
out[i] = '\0';
strcat(out, "-");
strcat(out, add);
strcat(out, fn+i);
return out;
}
}
/* Fallback if fn does not contain a dot */
strcpy(out, fn);
strcat(out, "-");
strcat(out, add);
return out;
}
/* Write custom split results (including a two-way split) */
static void write_custom_split(struct custom_split *csplit, int dsn,
Crystal **crystals, int n_crystals,
PartialityModel pmodel, int min_measurements,
double push_res, SymOpList *sym, int nthreads,
const char *outfile)
{
char *tmp;
RefList *split;
Crystal *crystalsn[n_crystals];
int n_crystalsn = 0;
int i;
for ( i=0; i<n_crystals; i++ ) {
const char *fn;
struct event *ev;
char *evs;
char *id;
int dsn_crystal;
fn = crystal_get_image(crystals[i])->filename;
ev = crystal_get_image(crystals[i])->event;
evs = get_event_string(ev);
id = malloc(strlen(evs)+strlen(fn)+2);
if ( id == NULL ) {
ERROR("Failed to allocate ID\n");
return;
}
strcpy(id, fn);
strcat(id, " ");
strcat(id, evs);
dsn_crystal = find_dsn_for_id(csplit, id);
free(id);
if ( dsn == dsn_crystal ) {
crystalsn[n_crystalsn] = crystals[i];
n_crystalsn++;
}
}
tmp = insert_into_filename(outfile, csplit->dataset_names[dsn]);
if ( n_crystalsn == 0 ) {
ERROR("Not writing dataset '%s' because it contains no "
"crystals\n", csplit->dataset_names[dsn]);
return;
}
STATUS("Writing dataset '%s' to %s (%i crystals)\n",
csplit->dataset_names[dsn], tmp, n_crystalsn);
split = merge_intensities(crystalsn, n_crystalsn, nthreads,
min_measurements, push_res, 1, 0);
write_reflist_2(tmp, split, sym);
free_contribs(split);
reflist_free(split);
write_split(crystalsn, n_crystalsn, tmp, nthreads, pmodel,
min_measurements, sym, push_res);
free(tmp);
}
static void show_help(const char *s)
{
printf("Syntax: %s [options]\n\n", s);
printf(
"Scaling and post refinement for coherent nanocrystallography.\n"
"\n"
" -h, --help Display this help message.\n"
" --version Print CrystFEL version number and exit.\n"
"\n"
" -i, --input=<filename> Specify the name of the input 'stream'.\n"
" -o, --output=<filename> Output filename. Default: partialator.hkl.\n"
" --output-every-cycle Write .hkl* and .params files in every cycle.\n"
" -y, --symmetry=<sym> Merge according to symmetry <sym>.\n"
" --start-after=<n> Skip <n> crystals at the start of the stream.\n"
" --stop-after=<n> Stop after merging <n> crystals.\n"
" -n, --iterations=<n> Run <n> cycles of scaling and post-refinement.\n"
" --no-scale Disable scale factor (G, B) refinement.\n"
" --no-Bscale Disable B factor scaling.\n"
" --no-pr Disable orientation/physics refinement.\n"
" --no-deltacchalf Disable rejection based on deltaCChalf.\n"
" -m, --model=<model> Specify partiality model.\n"
" --min-measurements=<n> Minimum number of measurements to require.\n"
" --no-polarisation Disable polarisation correction.\n"
" --max-adu=<n> Saturation value of detector.\n"
" --min-res=<n> Merge only crystals which diffract above <n> A.\n"
" --push-res=<n> Merge higher than apparent resolution cutoff.\n"
" -j <n> Run <n> analyses in parallel.\n"
" --no-free Disable cross-validation (testing only).\n"
" --custom-split List of files for custom dataset splitting.\n"
" --max-rel-B Maximum allowable relative |B| factor.\n"
" --no-logs Do not write extensive log files.\n"
" -w <pg> Apparent point group for resolving ambiguities.\n"
" --operator=<op> Indexing ambiguity operator for resolving.\n"
" --force-bandwidth=<n> Set all bandwidths to <n> (fraction).\n"
" --force-radius=<n> Set all profile radii to <n> nm^-1.\n"
" --force-lambda=<n> Set all wavelengths to <n> A.\n");
}
static signed int find_first_crystal(Crystal **crystals, int n_crystals,
struct custom_split *csplit, int dsn)
{
int i;
for ( i=0; i<n_crystals; i++ ) {
const char *fn;
struct event *ev;
char *evs;
char *id;
int dsn_crystal;
fn = crystal_get_image(crystals[i])->filename;
ev = crystal_get_image(crystals[i])->event;
evs = get_event_string(ev);
id = malloc(strlen(evs)+strlen(fn)+2);
if ( id == NULL ) {
ERROR("Failed to allocate ID\n");
return -1;
}
strcpy(id, fn);
strcat(id, " ");
strcat(id, evs);
dsn_crystal = find_dsn_for_id(csplit, id);
free(id);
if ( dsn == dsn_crystal ) return i;
}
return -1;
}
static void check_csplit(Crystal **crystals, int n_crystals,
struct custom_split *csplit)
{
int i;
int n_nosplit = 0;
int n_split = 0;
int n_cry = 0;
int n_nocry = 0;
STATUS("Checking your custom split datasets...\n");
for ( i=0; i<n_crystals; i++ ) {
const char *fn;
struct event *ev;
char *evs;
char *id;
int dsn_crystal;
fn = crystal_get_image(crystals[i])->filename;
ev = crystal_get_image(crystals[i])->event;
evs = get_event_string(ev);
id = malloc(strlen(evs)+strlen(fn)+2);
if ( id == NULL ) {
ERROR("Failed to allocate ID\n");
return;
}
strcpy(id, fn);
strcat(id, " ");
strcat(id, evs);
dsn_crystal = find_dsn_for_id(csplit, id);
free(id);
if ( dsn_crystal == -1 ) {
n_nosplit++;
} else {
n_split++;
}
}
for ( i=0; i<csplit->n_datasets; i++ ) {
/* Try to find a crystal with dsn = i */
if ( find_first_crystal(crystals, n_crystals, csplit, i) != -1 )
{
n_cry++;
} else {
n_nocry++;
STATUS("Dataset %s has no crystals.\n",
csplit->dataset_names[i]);
}
}
STATUS("Please check that these numbers match your expectations:\n");
STATUS(" Number of crystals assigned to a dataset: %i\n", n_split);
STATUS("Number of crystals with no dataset asssigned: %i\n", n_nosplit);
STATUS("Number of datasets with at least one crystal: %i\n", n_cry);
STATUS(" Number of datasets with no crystals: %i\n", n_nocry);
}
static struct custom_split *load_custom_split(const char *filename)
{
struct custom_split *csplit;
FILE *fh;
int i;
csplit = malloc(sizeof(struct custom_split));
if ( csplit == NULL ) return NULL;
csplit->n_datasets = 0;
csplit->n_events_total = 0;
csplit->dataset_names = NULL;
for ( i=0; i<CSPLIT_HASH_MAX; i++ ) {
csplit->hashes[i].n_events = 0;
csplit->hashes[i].events = NULL;
csplit->hashes[i].datasets = NULL;
}
fh = fopen(filename, "r");
if ( fh == NULL ) {
ERROR("Failed to open '%s'\n", filename);
free(csplit);
return NULL;
}
do {
char *rval;
char line[1024];
char *fn;
char *evs;
char *ds;
char *id;
int n;
char **bits;
rval = fgets(line, 1023, fh);
if ( rval == NULL ) break;
chomp(line);
notrail(line);
n = assplode(line, " \t,", &bits, ASSPLODE_NONE);
if ( n < 2 ) {
ERROR("Badly formatted line '%s'\n", line);
return NULL;
}
if ( n == 3 ) {
/* Filename, event, dataset */
fn = bits[0];
evs = bits[1];
ds = bits[2];
} else {
fn = bits[0];
evs = get_event_string(NULL);
ds = bits[1];
}
free(bits);
id = malloc(strlen(fn) + strlen(evs) + 2);
strcpy(id, fn);
strcat(id, " ");
strcat(id, evs);
add_to_csplit(csplit, id, ds);
free(id);
free(fn);
free(evs);
free(ds);
} while ( 1 );
fclose(fh);
int max = 0;
for ( i=0; i<CSPLIT_HASH_MAX; i++ ) {
if ( csplit->hashes[i].n_events > max ) {
max = csplit->hashes[i].n_events;
}
}
STATUS("Hash table load factor = %.2f (max %i)\n",
(double)csplit->n_events_total / CSPLIT_HASH_MAX, max);
return csplit;
}
static void display_progress(int n_images, int n_crystals)
{
if ( !isatty(STDERR_FILENO) ) return;
if ( tcgetpgrp(STDERR_FILENO) != getpgrp() ) return;
pthread_mutex_lock(&stderr_lock);
fprintf(stderr, "\r%i images loaded, %i crystals.",
n_images, n_crystals);
pthread_mutex_unlock(&stderr_lock);
fflush(stdout);
}
static RefList *apply_max_adu(RefList *list, double max_adu)
{
RefList *nlist;
Reflection *refl;
RefListIterator *iter;
nlist = reflist_new();
if ( nlist == NULL ) return NULL;
for ( refl = first_refl(list, &iter);
refl != NULL;
refl = next_refl(refl, iter) )
{
if ( get_peak(refl) < max_adu ) {
signed int h, k, l;
get_indices(refl, &h, &k, &l);
Reflection *nrefl = add_refl(nlist, h, k, l);
copy_data(nrefl, refl);
}
}
reflist_free(list);
return nlist;
}
static void skip_to_end(FILE *fh)
{
int c;
do {
c = fgetc(fh);
} while ( (c != '\n') && (c != EOF) );
}
static int set_initial_params(Crystal *cr, FILE *fh)
{
if ( fh != NULL ) {
int err;
int n;
float osf, B;
err = fscanf(fh, "%i %f %f", &n, &osf, &B);
if ( err != 3 ) {
ERROR("Failed to read parameters.\n");
return 1;
}
crystal_set_osf(cr, osf);
crystal_set_Bfac(cr, B*1e-20);
skip_to_end(fh);
} else {
crystal_set_osf(cr, 1.0);
crystal_set_Bfac(cr, 0.0);
}
return 0;
}
/* Flag a random 5% of reflections */
static void select_free_reflections(RefList *list, gsl_rng *rng)
{
Reflection *refl;
RefListIterator *iter;
for ( refl = first_refl(list, &iter);
refl != NULL;
refl = next_refl(refl, iter) )
{
set_flag(refl, random_flat(rng, 1.0) > 0.95);
}
}
static void write_to_pgraph(FILE *fh, RefList *list, RefList *full, Crystal *cr,
int fr, signed int inum)
{
Reflection *refl;
RefListIterator *iter;
double G = crystal_get_osf(cr);
double B = crystal_get_Bfac(cr);
UnitCell *cell = crystal_get_cell(cr);
char ins[16];
if ( inum >= 0 ) {
snprintf(ins, 12, "%i", inum);
} else {
ins[0] = 'F';
ins[1] = '\0';
}
for ( refl = first_refl(list, &iter);
refl != NULL;
refl = next_refl(refl, iter) )
{
signed int h, k, l;
double pobs, pcalc;
double res, Ipart;
Reflection *match;
if ( !get_flag(refl) ) continue; /* Not free-flagged */
/* Strong reflections only */
if ( get_intensity(refl) < 3.0*get_esd_intensity(refl) ) continue;
get_indices(refl, &h, &k, &l);
res = resolution(cell, h, k, l);
if ( 2.0*res > crystal_get_resolution_limit(cr) ) continue;
match = find_refl(full, h, k, l);
if ( match == NULL ) continue;
/* Don't calculate pobs if reference reflection is weak */
if ( fabs(get_intensity(match)) / get_esd_intensity(match) < 3.0 ) continue;
/* Calculated partiality */
pcalc = get_partiality(refl);
/* Observed partiality */
Ipart = correct_reflection_nopart(refl, G, B, res);
pobs = Ipart / get_intensity(match);
fprintf(fh, "%5i %4i %4i %4i %e %e %8.3f %8.3f %s\n",
fr, h, k, l, 2*res, Ipart, pcalc, pobs, ins);
}
}
static void write_pgraph(RefList *full, Crystal **crystals, int n_crystals,
signed int iter, const char *suff)
{
FILE *fh;
char tmp[256];
int i;
snprintf(tmp, 256, "pr-logs/pgraph%s.dat", suff);
if ( iter == 0 ) {
fh = fopen(tmp, "w");
} else {
fh = fopen(tmp, "a");
}
if ( fh == NULL ) {
ERROR("Failed to open '%s'\n", tmp);
return;
}
if ( iter == 0 ) {
fprintf(fh, " Crystal h k l 1/d(m) Ipart pcalc pobs iteration\n");
}
for ( i=0; i<n_crystals; i++ ) {
if ( crystal_get_user_flag(crystals[i]) != 0 ) continue;
write_to_pgraph(fh, crystal_get_reflections(crystals[i]), full,
crystals[i], i, iter);
}
fclose(fh);
}
static void all_residuals(Crystal **crystals, int n_crystals, RefList *full,
int no_free,
double *presidual, double *pfree_residual,
double *plog_residual, double *pfree_log_residual,
int *pn_used)
{
int i;
int n_used = 0;
int n_nan_linear = 0;
int n_nan_linear_free = 0;
int n_nan_log = 0;
int n_nan_log_free = 0;
int n_non_linear = 0;
int n_non_linear_free = 0;
int n_non_log = 0;
int n_non_log_free = 0;
*presidual = 0.0;
*pfree_residual = 0.0;
*plog_residual = 0.0;
*pfree_log_residual = 0.0;
for ( i=0; i<n_crystals; i++ ) {
double r, free_r, log_r, free_log_r;
int n;
if ( crystal_get_user_flag(crystals[i]) ) continue;
/* Scaling should have been done right before calling this */
r = residual(crystals[i], full, 0, &n, NULL);
if ( n == 0 ) {
n_non_linear++;
} else if ( isnan(r) ) {
n_nan_linear++;
}
free_r = residual(crystals[i], full, 1, &n, NULL);
if ( n == 0 ) {
n_non_linear_free++;
} else if ( isnan(free_r) ) {
n_nan_linear_free++;
}
log_r = log_residual(crystals[i], full, 0, &n, NULL);
if ( n == 0 ) {
n_non_log++;
} else if ( isnan(log_r) ) {
n_nan_log++;
}
free_log_r = log_residual(crystals[i], full, 1, &n, NULL);
if ( n == 0 ) {
n_non_log_free++;
} else if ( isnan(free_log_r) ) {
n_nan_log_free++;
}
if ( isnan(r) || isnan(log_r) ) continue;
if ( !no_free && (isnan(free_r) || isnan(free_log_r)) ) continue;
*presidual += r;
*pfree_residual += free_r;
*plog_residual += log_r;
*pfree_log_residual += free_log_r;
n_used++;
}
if ( n_non_linear ) {
ERROR("WARNING: %i crystals had no reflections in linear "
"residual calculation\n", n_non_linear);
}
if ( n_non_linear_free ) {
ERROR("WARNING: %i crystals had no reflections in linear free "
"residual calculation\n", n_non_linear_free);
}
if ( n_non_log ) {
ERROR("WARNING: %i crystals had no reflections in log "
"residual calculation\n", n_non_log);
}
if ( n_non_log_free ) {
ERROR("WARNING: %i crystals had no reflections in log free "
"residual calculation\n", n_non_log_free);
}
if ( n_nan_linear ) {
ERROR("WARNING: %i crystals had NaN linear residuals\n",
n_nan_linear);
}
if ( n_nan_linear_free ) {
ERROR("WARNING: %i crystals had NaN linear free residuals\n",
n_nan_linear_free);
}
if ( n_nan_log ) {
ERROR("WARNING: %i crystals had NaN log residuals\n",
n_nan_log);
}
if ( n_nan_log_free ) {
ERROR("WARNING: %i crystals had NaN log free residuals\n",
n_nan_log_free);
}
*pn_used = n_used;
}
static void show_all_residuals(Crystal **crystals, int n_crystals,
RefList *full, int no_free)
{
double dev, free_dev, log_dev, free_log_dev;
int n;
all_residuals(crystals, n_crystals, full, no_free,
&dev, &free_dev, &log_dev, &free_log_dev, &n);
STATUS("Residuals:"
" linear linear free log log free\n");
STATUS(" ");
STATUS("%15e %15e %15e %15e (%i crystals)\n",
dev, free_dev, log_dev, free_log_dev, n);
}
struct log_qargs
{
int iter;
int next;
Crystal **crystals;
int n_crystals;
RefList *full;
int scaleflags;
int n_done;
};
struct log_args
{
Crystal *cr;
RefList *full;
int scaleflags;
int iter;
int cnum;
};
static void *get_log_task(void *vp)
{
struct log_qargs *qargs = vp;
struct log_args *task;
if ( qargs->next >= qargs->n_crystals ) return NULL;
task = malloc(sizeof(struct log_args));
if ( task == NULL ) return NULL;
task->cr = qargs->crystals[qargs->next];
task->full = qargs->full;
task->iter = qargs->iter;
task->cnum = qargs->next;
task->scaleflags = qargs->scaleflags;
qargs->next += 20;
return task;
}
static void write_logs(void *vp, int cookie)
{
struct log_args *args = vp;
write_specgraph(args->cr, args->full, args->iter, args->cnum);
write_gridscan(args->cr, args->full, args->iter, args->cnum,
args->scaleflags);
write_test_logs(args->cr, args->full, args->iter, args->cnum);
}
static void done_log(void *vqargs, void *vp)
{
struct log_args *task = vp;
struct log_qargs *qargs = vqargs;
qargs->n_done++;
progress_bar(qargs->n_done, qargs->n_crystals/20, "Writing logs/grid scans");
free(task);
}
static void write_logs_parallel(Crystal **crystals, int n_crystals,
RefList *full, int iter, int n_threads,
int scaleflags)
{
struct log_qargs qargs;
qargs.iter = iter;
qargs.next = 0;
qargs.full = full;
qargs.crystals = crystals;
qargs.n_done = 0;
qargs.n_crystals = n_crystals;
qargs.scaleflags = scaleflags;
run_threads(n_threads, write_logs, get_log_task, done_log, &qargs,
n_crystals/20, 0, 0, 0);
}
int main(int argc, char *argv[])
{
int c;
char *infile = NULL;
char *outfile = NULL;
char *sym_str = NULL;
SymOpList *sym;
SymOpList *amb;
SymOpList *w_sym;
int nthreads = 1;
int i;
int n_iter = 10;
RefList *full;
int n_images = 0;
int n_crystals = 0;
int n_crystals_seen = 0;
char cmdline[1024];
int no_scale = 0;
int no_Bscale = 0;
int no_pr = 0;
Stream *st;
Crystal **crystals;
char *pmodel_str = NULL;
PartialityModel pmodel = PMODEL_XSPHERE;
int min_measurements = 2;
char *rval;
int polarisation = 1;
int start_after = 0;
int stop_after = 0;
double max_adu = +INFINITY;
char *sparams_fn = NULL;
FILE *sparams_fh;
double push_res = +INFINITY;
gsl_rng *rng;
int no_free = 0;
int output_everycycle = 0;
char *csplit_fn = NULL;
struct custom_split *csplit = NULL;
double max_B = 1e-18;
char *rfile = NULL;
RefList *reference = NULL;
int no_logs = 0;
char *w_sym_str = NULL;
char *operator = NULL;
double force_bandwidth = -1.0;
double force_radius = -1.0;
double force_lambda = -1.0;
char *audit_info;
int scaleflags = 0;
double min_res = 0.0;
int do_write_logs = 0;
int no_deltacchalf = 0;
/* Long options */
const struct option longopts[] = {
{"help", 0, NULL, 'h'},
{"version", 0, NULL, 'v'},
{"input", 1, NULL, 'i'},
{"output", 1, NULL, 'o'},
{"start-after", 1, NULL, 's'},
{"stop-after", 1, NULL, 'f'},
{"symmetry", 1, NULL, 'y'},
{"iterations", 1, NULL, 'n'},
{"model", 1, NULL, 'm'},
{"min-measurements", 1, NULL, 2},
{"max-adu", 1, NULL, 3},
{"start-params", 1, NULL, 4},
{"push-res", 1, NULL, 5},
{"res-push", 1, NULL, 5}, /* compat */
{"custom-split", 1, NULL, 6},
{"max-rel-B", 1, NULL, 7},
{"max-rel-b", 1, NULL, 7}, /* compat */
{"reference", 1, NULL, 8}, /* ssshhh! */
{"operator", 1, NULL, 9},
{"force-bandwidth", 1, NULL, 10},
{"force-radius", 1, NULL, 11},
{"min-res", 1, NULL, 12},
{"force-lambda", 1, NULL, 13},
{"no-scale", 0, &no_scale, 1},
{"no-Bscale", 0, &no_Bscale, 1},
{"no-pr", 0, &no_pr, 1},
{"no-polarisation", 0, &polarisation, 0},
{"no-polarization", 0, &polarisation, 0}, /* compat */
{"polarisation", 0, &polarisation, 1},
{"polarization", 0, &polarisation, 1}, /* compat */
{"no-free", 0, &no_free, 1},
{"output-every-cycle", 0, &output_everycycle, 1},
{"no-logs", 0, &no_logs, 1},
{"no-deltacchalf", 0, &no_deltacchalf, 1},
{0, 0, NULL, 0}
};
cmdline[0] = '\0';
for ( i=1; i<argc; i++ ) {
strncat(cmdline, argv[i], 1023-strlen(cmdline));
strncat(cmdline, " ", 1023-strlen(cmdline));
}
/* Short options */
while ((c = getopt_long(argc, argv, "hi:o:g:b:y:n:j:m:w:",
longopts, NULL)) != -1)
{
switch (c) {
case 'h' :
show_help(argv[0]);
return 0;
case 'v' :
printf("CrystFEL: " CRYSTFEL_VERSIONSTRING "\n");
printf(CRYSTFEL_BOILERPLATE"\n");
return 0;
case 'i' :
infile = strdup(optarg);
break;
case 'j' :
nthreads = atoi(optarg);
break;
case 's' :
errno = 0;
start_after = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid value for --start-after (%s)\n",
optarg);
return 1;
}
break;
case 'f' :
errno = 0;
stop_after = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid value for --stop-after (%s)\n",
optarg);
return 1;
}
break;
case 'y' :
sym_str = strdup(optarg);
break;
case 'o' :
outfile = strdup(optarg);
break;
case 'n' :
n_iter = atoi(optarg);
break;
case 'm' :
pmodel_str = strdup(optarg);
break;
case 'w' :
w_sym_str = strdup(optarg);
break;
case 2 :
errno = 0;
min_measurements = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid value for --min-measurements.\n");
return 1;
}
break;
case 3 :
errno = 0;
max_adu = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid value for --max-adu.\n");
return 1;
}
break;
case 4 :
sparams_fn = strdup(optarg);
break;
case 5 :
errno = 0;
push_res = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid value for --push-res.\n");
return 1;
}
push_res = push_res*1e9;
break;
case 6 :
csplit_fn = strdup(optarg);
break;
case 7 :
errno = 0;
max_B = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid value for --max-rel-B.\n");
return 1;
}
max_B = max_B * 1e-20;
break;
case 8 :
rfile = strdup(optarg);
break;
case 9 :
operator = strdup(optarg);
break;
case 10 :
errno = 0;
force_bandwidth = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid value for --force-bandwidth.\n");
return 1;
}
break;
case 11 :
errno = 0;
force_radius = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid value for --force-radius.\n");
return 1;
}
force_radius *= 1e9;
break;
case 12 :
errno = 0;
min_res = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid value for --min-res.\n");
return 1;
}
min_res = 1e10/min_res;
break;
case 13 :
errno = 0;
force_lambda = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid value for --force-lambda.\n");
return 1;
}
force_lambda *= 1e-10;
break;
case 0 :
break;
case '?' :
break;
default :
ERROR("Unhandled option '%c'\n", c);
break;
}
}
if ( nthreads < 1 ) {
ERROR("Invalid number of threads.\n");
return 1;
}
if ( infile == NULL ) {
ERROR("Please give the input filename (with -i)\n");
return 1;
}
st = open_stream_for_read(infile);
if ( st == NULL ) {
ERROR("Failed to open input stream '%s'\n", infile);
return 1;
}
if ( outfile == NULL ) {
outfile = strdup("partialator.hkl");
}
if ( sym_str == NULL ) sym_str = strdup("1");
pointgroup_warning(sym_str);
sym = get_pointgroup(sym_str);
free(sym_str);
if ( sym == NULL ) return 1;
if ( (w_sym_str != NULL) && (operator != NULL) ) {
ERROR("Specify the apparent symmetry (-w) or the operator, "
"not both.\n");
return 1;
}
if ( w_sym_str == NULL ) {
w_sym = NULL;
amb = NULL;
} else {
pointgroup_warning(w_sym_str);
w_sym = get_pointgroup(w_sym_str);
free(w_sym_str);
if ( w_sym == NULL ) return 1;
amb = get_ambiguities(w_sym, sym);
if ( amb == NULL ) {
ERROR("Couldn't find ambiguity operator.\n");
ERROR("Check that your values for -y and -w are "
"correct.\n");
return 1;
}
}
if ( operator ) {
amb = parse_symmetry_operations(operator);
if ( amb == NULL ) return 1;
set_symmetry_name(amb, "Ambiguity");
}
if ( amb != NULL ) {
STATUS("Indexing ambiguity resolution enabled. "
"The ambiguity operation(s) are:\n");
describe_symmetry(amb);
/* In contrast to ambigator, partialator can deal with multiple
* ambiguities at once */
}
if ( pmodel_str != NULL ) {
if ( strcmp(pmodel_str, "unity") == 0 ) {
pmodel = PMODEL_UNITY;
} else if ( strcmp(pmodel_str, "xsphere") == 0 ) {
pmodel = PMODEL_XSPHERE;
} else if ( strcmp(pmodel_str, "random") == 0 ) {
pmodel = PMODEL_RANDOM;
} else {
ERROR("Unknown partiality model '%s'.\n", pmodel_str);
return 1;
}
free(pmodel_str);
}
if ( (pmodel == PMODEL_UNITY) && !no_pr ) {
no_pr = 1;
STATUS("Setting --no-pr because we are not modelling "
"partialities (--model=unity).\n");
}
if ( no_Bscale ) {
scaleflags |= SCALE_NO_B;
}
/* Decide whether or not to create stuff in the pr-logs folder */
if ( !(no_logs || (no_pr && pmodel == PMODEL_UNITY)) ) {
do_write_logs = 1;
} else {
do_write_logs = 0;
}
if ( do_write_logs ) {
int r = mkdir("pr-logs", S_IRWXU | S_IRWXG | S_IROTH | S_IXOTH);
if ( r ) {
if ( errno == EEXIST ) {
ERROR("WARNING: pr-logs folder already exists. "
"Beware of mixing old and new log files!\n");
} else {
ERROR("Failed to create pr-logs folder.\n");
return 1;
}
}
} else {
struct stat s;
if ( stat("pr-logs", &s) != -1 ) {
ERROR("WARNING: pr-logs folder exists, but I will not "
"write anything in it with these settings.\n");
}
}
/* Read the custom split list (if applicable) */
if ( csplit_fn != NULL ) {
csplit = load_custom_split(csplit_fn);
if ( csplit == NULL ) {
ERROR("Failed to load custom split list.\n");
return 1;
}
free(csplit_fn);
}
if ( rfile != NULL ) {
RefList *rread;
rread = read_reflections(rfile);
if ( rread == NULL ) {
ERROR("Failed to read reference reflections\n");
return 1;
}
reference = asymmetric_indices(rread, sym);
reflist_free(rread);
ERROR("WARNING: Using an external reference.\n");
ERROR("WARNING: If you publish a structure based on the result,"
" expect to have to retract your paper!\n");
}
gsl_set_error_handler_off();
rng = gsl_rng_alloc(gsl_rng_mt19937);
/* Fill in what we know about the images so far */
n_images = 0;
n_crystals = 0;
n_crystals_seen = 0;
crystals = NULL;
if ( sparams_fn != NULL ) {
char line[1024];
sparams_fh = fopen(sparams_fn, "r");
if ( sparams_fh == NULL ) {
ERROR("Failed to open '%s'\n", sparams_fn);
return 1;
}
if ( fgets(line, 1024, sparams_fh) == NULL ) {
ERROR("Failed to read header from %s\n", sparams_fn);
return 1;
}
STATUS("Reading initial scaling factors (G,B) from '%s'\n",
sparams_fn);
free(sparams_fn);
} else {
sparams_fh = NULL;
}
do {
RefList *as;
int i;
struct image cur;
cur.div = NAN;
cur.bw = NAN;
cur.det = NULL;
if ( read_chunk_2(st, &cur, STREAM_READ_REFLECTIONS
| STREAM_READ_UNITCELL) != 0 ) {
break;
}
if ( isnan(cur.div) || isnan(cur.bw) ) {
ERROR("Chunk doesn't contain beam parameters.\n");
return 1;
}
free_stuff_from_stream(cur.stuff_from_stream);
cur.stuff_from_stream = NULL;
for ( i=0; i<cur.n_crystals; i++ ) {
Crystal *cr;
Crystal **crystals_new;
RefList *cr_refl;
struct image *image;
n_crystals_seen++;
if ( n_crystals_seen <= start_after ) continue;
if ( crystal_get_resolution_limit(cur.crystals[i]) < min_res ) continue;
crystals_new = realloc(crystals,
(n_crystals+1)*sizeof(Crystal *));
if ( crystals_new == NULL ) {
ERROR("Failed to allocate memory for crystal "
"list.\n");
return 1;
}
crystals = crystals_new;
crystals[n_crystals] = cur.crystals[i];
cr = crystals[n_crystals];
image = malloc(sizeof(struct image));
if ( image == NULL ) {
ERROR("Failed to allocate memory for image.\n");
return 1;
}
crystal_set_image(cr, image);
*image = cur;
image->n_crystals = 1;
image->crystals = &crystals[n_crystals];
image->filename = strdup(image->filename);
/* This is the raw list of reflections */
cr_refl = crystal_get_reflections(cr);
cr_refl = apply_max_adu(cr_refl, max_adu);
if ( polarisation ) {
polarisation_correction(cr_refl,
crystal_get_cell(cr),
image);
}
if ( !no_free ) select_free_reflections(cr_refl, rng);
as = asymmetric_indices(cr_refl, sym);
crystal_set_reflections(cr, as);
crystal_set_user_flag(cr, PRFLAG_OK);
reflist_free(cr_refl);
if ( set_initial_params(cr, sparams_fh) ) {
ERROR("Failed to set initial parameters\n");
return 1;
}
n_crystals++;
if ( n_crystals == stop_after ) break;
}
free(cur.crystals);
free(cur.filename);
n_images++;
if ( n_images % 100 == 0 ) {
display_progress(n_images, n_crystals);
}
if ( (stop_after>0) && (n_crystals == stop_after) ) break;
} while ( 1 );
display_progress(n_images, n_crystals);
fprintf(stderr, "\n");
if ( sparams_fh != NULL ) fclose(sparams_fh);
audit_info = stream_audit_info(st);
close_stream(st);
STATUS("Initial partiality calculation...\n");
for ( i=0; i<n_crystals; i++ ) {
Crystal *cr = crystals[i];
if ( force_bandwidth > 0.0 ) {
crystal_get_image(cr)->bw = force_bandwidth;
}
if ( force_radius > 0.0 ) {
crystal_set_profile_radius(cr, force_radius);
}
if ( force_lambda > 0.0 ) {
crystal_get_image(cr)->lambda = force_lambda;
}
update_predictions(cr);
calculate_partialities(cr, pmodel);
}
if (csplit != NULL) check_csplit(crystals, n_crystals, csplit);
/* Make a first pass at cutting out crap */
//STATUS("Early rejection...\n");
//early_rejection(crystals, n_crystals);
/* Create reference data set if we don't already have one */
if ( reference == NULL ) {
if ( !no_scale ) {
STATUS("Initial scaling...\n");
scale_all(crystals, n_crystals, nthreads, scaleflags);
}
full = merge_intensities(crystals, n_crystals, nthreads,
min_measurements, push_res, 1, 0);
} else {
full = reference;
}
/* Check rejection and write figures of merit */
check_rejection(crystals, n_crystals, full, max_B, no_deltacchalf,
nthreads);
show_all_residuals(crystals, n_crystals, full, no_free);
if ( do_write_logs ) {
write_pgraph(full, crystals, n_crystals, 0, "");
write_logs_parallel(crystals, n_crystals, full, 0, nthreads,
scaleflags);
}
/* Iterate */
for ( i=0; i<n_iter; i++ ) {
STATUS("Scaling and refinement cycle %i of %i\n", i+1, n_iter);
if ( !no_pr ) {
refine_all(crystals, n_crystals, full, nthreads, pmodel,
0, i+1, no_logs, sym, amb, scaleflags);
}
/* Create new reference if needed */
if ( reference == NULL ) {
free_contribs(full);
reflist_free(full);
if ( !no_scale ) {
scale_all(crystals, n_crystals, nthreads,
scaleflags);
}
full = merge_intensities(crystals, n_crystals, nthreads,
min_measurements,
push_res, 1, 0);
} /* else full still equals reference */
check_rejection(crystals, n_crystals, full, max_B,
no_deltacchalf, nthreads);
show_all_residuals(crystals, n_crystals, full, no_free);
if ( do_write_logs ) {
write_pgraph(full, crystals, n_crystals, i+1, "");
}
if ( output_everycycle ) {
char tmp[1024];
snprintf(tmp, 1024, "iter%.2d_%s", i+1, outfile);
/* Output results */
STATUS("Writing overall results to %s\n", tmp);
write_reflist_2(tmp, full, sym);
/* Output split results */
write_split(crystals, n_crystals, tmp, nthreads, pmodel,
min_measurements, sym, push_res);
/* Output custom split results */
if ( csplit != NULL ) {
int j;
for ( j=0; j<csplit->n_datasets; j++ ) {
write_custom_split(csplit, j, crystals,
n_crystals, pmodel,
min_measurements,
push_res, sym,
nthreads, tmp);
}
}
}
}
/* Final merge */
STATUS("Final merge...\n");
if ( reference == NULL ) {
free_contribs(full);
reflist_free(full);
if ( !no_scale ) {
scale_all(crystals, n_crystals, nthreads, scaleflags);
}
full = merge_intensities(crystals, n_crystals, nthreads,
min_measurements,
push_res, 1, 0);
} else {
full = merge_intensities(crystals, n_crystals, nthreads,
min_measurements, push_res, 1, 0);
}
/* Write final figures of merit (no rejection any more) */
show_all_residuals(crystals, n_crystals, full, no_free);
if ( do_write_logs ) {
write_pgraph(full, crystals, n_crystals, -1, "");
write_logs_parallel(crystals, n_crystals, full, -1, nthreads,
scaleflags);
}
/* Output results */
STATUS("Writing overall results to %s\n", outfile);
reflist_add_command_and_version(full, argc, argv);
if ( audit_info != NULL ) {
reflist_add_notes(full, "Audit information from stream:");
reflist_add_notes(full, audit_info);
free(audit_info);
}
write_reflist_2(outfile, full, sym);
/* Output split results */
write_split(crystals, n_crystals, outfile, nthreads, pmodel,
min_measurements, sym, push_res);
/* Output custom split results */
if ( csplit != NULL ) {
for ( i=0; i<csplit->n_datasets; i++ ) {
write_custom_split(csplit, i, crystals, n_crystals,
pmodel, min_measurements, push_res,
sym, nthreads, outfile);
}
}
/* Clean up */
gsl_rng_free(rng);
for ( i=0; i<n_crystals; i++ ) {
struct image *image = crystal_get_image(crystals[i]);
reflist_free(crystal_get_reflections(crystals[i]));
free(image->filename);
free(image);
cell_free(crystal_get_cell(crystals[i]));
crystal_free(crystals[i]);
}
free_contribs(full);
reflist_free(full);
free_symoplist(sym);
free(outfile);
free(crystals);
free(infile);
return 0;
}
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