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|
/*
* pattern_sim.c
*
* Simulate diffraction patterns from small crystals
*
* Copyright © 2012-2014 Deutsches Elektronen-Synchrotron DESY,
* a research centre of the Helmholtz Association.
*
* Authors:
* 2009-2014 Thomas White <taw@physics.org>
* 2013-2014 Chun Hong Yoon <chun.hong.yoon@desy.de>
* 2014 Valerio Mariani
* 2013 Alexandra Tolstikova
*
* 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 "version.h"
#include "image.h"
#include "diffraction.h"
#include "diffraction-gpu.h"
#include "cell.h"
#include "cell-utils.h"
#include "utils.h"
#include "hdf5-file.h"
#include "detector.h"
#include "peaks.h"
#include "symmetry.h"
#include "reflist.h"
#include "reflist-utils.h"
#include "pattern_sim.h"
#include "stream.h"
static void show_help(const char *s)
{
printf("Syntax: %s [options]\n\n", s);
printf(
"Simulate diffraction patterns from small crystals probed with femtosecond\n"
"pulses of X-rays from a free electron laser.\n"
"\n"
" -h, --help Display this help message.\n"
" --version Print CrystFEL version number and exit.\n"
"\n"
" -p, --pdb=<file> File from which to get the unit cell.\n"
" (The actual Bragg intensities come from the\n"
" intensities file)\n"
" --gpu Use the GPU to speed up the calculation.\n"
" --gpu-dev=<n> Use GPU device <n>. Omit this option to see the\n"
" available devices.\n"
" -g, --geometry=<file> Get detector geometry from file.\n"
" -n, --number=<N> Generate N images. Default 1.\n"
" --no-images Do not output any HDF5 files.\n"
" -o, --output=<filename> Output HDF5 filename. Default: sim.h5.\n"
" -r, --random-orientation Use randomly generated orientations.\n"
" --powder=<file> Write a summed pattern of all images simulated by\n"
" this invocation as the given filename.\n"
" -i, --intensities=<file> Specify file containing reflection intensities\n"
" (and phases) to use.\n"
" -y, --symmetry=<sym> The symmetry of the intensities file.\n"
" -t, --gradients=<method> Select method for calculation of shape transforms\n"
" --really-random Seed the random number generator with /dev/urandom.\n"
" --min-size=<s> Minimum crystal size in nm.\n"
" --max-size=<s> Naximum crystal size in nm.\n"
" --no-noise Do not calculate Poisson noise.\n"
" -s, --sample-spectrum=<N> Use N samples from spectrum. Default 3.\n"
" -x, --spectrum=<type> Type of spectrum to simulate.\n"
" --background=<N> Add N photons of Poisson background (default 0).\n"
" --template=<file> Take orientations from stream <file>.\n"
" --no-fringes Exclude the side maxima of Bragg peaks.\n"
" --beam-divergence Beam divergence in radians. Default 1 mrad.\n"
" --beam-bandwidth Beam bandwidth as a fraction. Default 1%%.\n"
" --profile-radius Reciprocal space reflection profile radius in m^-1.\n"
" Default 0.001e9 m^-1\n"
" --photon-energy Photon energy in eV. Default 9000.\n"
);
}
static double *intensities_from_list(RefList *list, SymOpList *sym)
{
Reflection *refl;
RefListIterator *iter;
double *out = new_arr_intensity();
SymOpMask *m = new_symopmask(sym);
int neq = num_equivs(sym, NULL);
for ( refl = first_refl(list, &iter);
refl != NULL;
refl = next_refl(refl, iter) ) {
signed int h, k, l;
int eps;
double intensity = get_intensity(refl);
get_indices(refl, &h, &k, &l);
special_position(sym, m, h, k, l);
eps = neq / num_equivs(sym, m);
set_arr_intensity(out, h, k, l, intensity / eps);
}
return out;
}
static double *phases_from_list(RefList *list)
{
Reflection *refl;
RefListIterator *iter;
double *out = new_arr_phase();
for ( refl = first_refl(list, &iter);
refl != NULL;
refl = next_refl(refl, iter) ) {
signed int h, k, l;
double phase = get_phase(refl, NULL);
get_indices(refl, &h, &k, &l);
set_arr_phase(out, h, k, l, phase);
}
return out;
}
static unsigned char *flags_from_list(RefList *list)
{
Reflection *refl;
RefListIterator *iter;
unsigned char *out = new_arr_flag();
for ( refl = first_refl(list, &iter);
refl != NULL;
refl = next_refl(refl, iter) ) {
signed int h, k, l;
get_indices(refl, &h, &k, &l);
set_arr_flag(out, h, k, l, 1);
}
return out;
}
static struct quaternion read_quaternion()
{
do {
int r;
float w, x, y, z;
char line[1024];
char *rval;
printf("Please input quaternion: w x y z\n");
rval = fgets(line, 1023, stdin);
if ( rval == NULL ) return invalid_quaternion();
chomp(line);
r = sscanf(line, "%f %f %f %f", &w, &x, &y, &z);
if ( r == 4 ) {
struct quaternion quat;
quat.w = w;
quat.x = x;
quat.y = y;
quat.z = z;
return quat;
} else {
ERROR("Invalid rotation '%s'\n", line);
}
} while ( 1 );
}
static int random_ncells(double len, double min_nm, double max_nm)
{
int min_cells, max_cells, wid;
min_cells = min_nm*1e-9 / len;
max_cells = max_nm*1e-9 / len;
wid = max_cells - min_cells;
return wid*random()/RAND_MAX + min_cells;
}
int main(int argc, char *argv[])
{
int c;
struct image image;
struct gpu_context *gctx = NULL;
struct image *powder;
float *powder_data;
char *intfile = NULL;
double *intensities;
char *rval;
double *phases;
unsigned char *flags;
int config_randomquat = 0;
int config_noimages = 0;
int config_nonoise = 0;
int config_nosfac = 0;
int config_gpu = 0;
int config_random = 0;
char *powder_fn = NULL;
char *filename = NULL;
char *grad_str = NULL;
char *outfile = NULL;
char *geometry = NULL;
char *beamfile = NULL;
char *spectrum_str = NULL;
GradientMethod grad;
SpectrumType spectrum_type;
int ndone = 0; /* Number of simulations done (images or not) */
int number = 1; /* Number used for filename of image */
int n_images = 1; /* Generate one image by default */
int done = 0;
UnitCell *input_cell;
struct quaternion orientation;
int gpu_dev = -1;
int random_size = 0;
double min_size = 0.0;
double max_size = 0.0;
char *sym_str = NULL;
SymOpList *sym;
int nsamples = 3;
gsl_rng *rng;
int background = 0;
char *template_file = NULL;
Stream *st = NULL;
int no_fringes = 0;
double nphotons = 1e12;
double beam_radius = 1e-6; /* metres */
double bandwidth = 0.01;
double photon_energy = 9000.0;
/* Long options */
const struct option longopts[] = {
{"help", 0, NULL, 'h'},
{"version", 0, NULL, 'v'},
{"gpu", 0, &config_gpu, 1},
{"random-orientation", 0, NULL, 'r'},
{"number", 1, NULL, 'n'},
{"no-images", 0, &config_noimages, 1},
{"no-noise", 0, &config_nonoise, 1},
{"intensities", 1, NULL, 'i'},
{"symmetry", 1, NULL, 'y'},
{"powder", 1, NULL, 'w'},
{"gradients", 1, NULL, 't'},
{"pdb", 1, NULL, 'p'},
{"output", 1, NULL, 'o'},
{"geometry", 1, NULL, 'g'},
{"sample-spectrum", 1, NULL, 's'},
{"type-spectrum", 1, NULL, 'x'},
{"spectrum", 1, NULL, 'x'},
{"really-random", 0, &config_random, 1},
{"no-fringes", 0, &no_fringes, 1},
{"gpu-dev", 1, NULL, 2},
{"min-size", 1, NULL, 3},
{"max-size", 1, NULL, 4},
{"background", 1, NULL, 5},
{"template", 1, NULL, 6},
{"beam-bandwidth", 1, NULL, 7},
{"photon-energy", 1, NULL, 9},
{"nphotons", 1, NULL, 10},
{"beam-radius", 1, NULL, 11},
{0, 0, NULL, 0}
};
/* Short options */
while ((c = getopt_long(argc, argv, "hrn:i:t:p:o:g:y:s:x:v",
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 'r' :
config_randomquat = 1;
break;
case 'n' :
n_images = strtol(optarg, &rval, 10);
if ( *rval != '\0' ) {
ERROR("Invalid number of images.\n");
return 1;
}
break;
case 'i' :
intfile = strdup(optarg);
break;
case 't' :
grad_str = strdup(optarg);
break;
case 'p' :
filename = strdup(optarg);
break;
case 'o' :
outfile = strdup(optarg);
break;
case 'w' :
powder_fn = strdup(optarg);
break;
case 'g' :
geometry = strdup(optarg);
break;
case 'b' :
beamfile = strdup(optarg);
break;
case 'y' :
sym_str = strdup(optarg);
break;
case 's' :
nsamples = strtol(optarg, &rval, 10);
if ( *rval != '\0' ) {
ERROR("Invalid number of spectrum samples.\n");
return 1;
}
break;
case 'x' :
spectrum_str = strdup(optarg);
break;
case 2 :
gpu_dev = atoi(optarg);
break;
case 3 :
min_size = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid minimum size.\n");
return 1;
}
random_size++;
break;
case 4 :
max_size = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid maximum size.\n");
return 1;
}
random_size++;
break;
case 5 :
background = strtol(optarg, &rval, 10);
if ( *rval != '\0' ) {
ERROR("Invalid background level.\n");
return 1;
}
break;
case 6 :
template_file = strdup(optarg);
break;
case 7 :
bandwidth = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid beam bandwidth.\n");
return 1;
}
if ( bandwidth < 0.0 ) {
ERROR("Beam bandwidth must be positive.\n");
return 1;
}
break;
case 9 :
photon_energy = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid photon energy.\n");
return 1;
}
if ( photon_energy < 0.0 ) {
ERROR("Photon energy must be positive.\n");
return 1;
}
break;
case 10 :
nphotons = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid number of photons.\n");
return 1;
}
if ( nphotons < 0.0 ) {
ERROR("Number of photons must be positive.\n");
return 1;
}
break;
case 11 :
beam_radius = strtod(optarg, &rval);
if ( *rval != '\0' ) {
ERROR("Invalid beam radius.\n");
return 1;
}
if ( beam_radius < 0.0 ) {
ERROR("Beam radius must be positive.\n");
return 1;
}
break;
case 0 :
break;
case '?' :
break;
default :
ERROR("Unhandled option '%c'\n", c);
break;
}
}
if ( random_size == 1 ) {
ERROR("You must specify both --min-size and --max-size.\n");
return 1;
}
if ( filename == NULL ) {
filename = strdup("molecule.pdb");
}
if ( outfile == NULL ) {
if ( n_images == 1 ) {
outfile = strdup("sim.h5");
} else {
outfile = strdup("sim");
}
}
if ( template_file != NULL ) {
if ( config_randomquat ) {
ERROR("You cannot use -r and --template together.\n");
return 1;
}
st = open_stream_for_read(template_file);
if ( st == NULL ) {
ERROR("Failed to open stream.\n");
return 1;
}
free(template_file);
}
if ( sym_str == NULL ) sym_str = strdup("1");
sym = get_pointgroup(sym_str);
/* sym_str is used below */
if ( grad_str == NULL ) {
STATUS("You didn't specify a gradient calculation method, so"
" I'm using the 'mosaic' method, which is fastest.\n");
grad = GRADIENT_MOSAIC;
} else if ( strcmp(grad_str, "mosaic") == 0 ) {
grad = GRADIENT_MOSAIC;
} else if ( strcmp(grad_str, "interpolate") == 0) {
grad = GRADIENT_INTERPOLATE;
} else if ( strcmp(grad_str, "phased") == 0) {
grad = GRADIENT_PHASED;
} else {
ERROR("Unrecognised gradient method '%s'\n", grad_str);
return 1;
}
free(grad_str);
if ( config_gpu && (grad != GRADIENT_MOSAIC) ) {
ERROR("Only the mosaic method can be used for gradients when"
"calculating on the GPU.\n");
return 1;
}
if ( geometry == NULL ) {
ERROR("You need to specify a geometry file with --geometry\n");
return 1;
}
image.det = get_detector_geometry(geometry, NULL);
if ( image.det == NULL ) {
ERROR("Failed to read detector geometry from '%s'\n", geometry);
return 1;
}
free(geometry);
if ( spectrum_str == NULL ) {
STATUS("You didn't specify a spectrum type, so"
" I'm using a 'tophat' spectrum.\n");
spectrum_type = SPECTRUM_TOPHAT;
} else if ( strcasecmp(spectrum_str, "tophat") == 0) {
spectrum_type = SPECTRUM_TOPHAT;
} else if ( strcasecmp(spectrum_str, "sase") == 0) {
spectrum_type = SPECTRUM_SASE;
} else if ( strcasecmp(spectrum_str, "twocolour") == 0 ||
strcasecmp(spectrum_str, "twocolor") == 0 ||
strcasecmp(spectrum_str, "twocolours") == 0 ||
strcasecmp(spectrum_str, "twocolors") == 0) {
spectrum_type = SPECTRUM_TWOCOLOUR;
} else {
ERROR("Unrecognised spectrum type '%s'\n", spectrum_str);
return 1;
}
free(spectrum_str);
if ( intfile == NULL ) {
/* Gentle reminder */
STATUS("You didn't specify the file containing the ");
STATUS("reflection intensities (with --intensities).\n");
STATUS("I'll simulate a flat intensity distribution.\n");
intensities = NULL;
phases = NULL;
flags = NULL;
} else {
RefList *reflections;
reflections = read_reflections2(intfile, image.det);
if ( reflections == NULL ) {
ERROR("Problem reading input file %s\n", intfile);
return 1;
}
free(intfile);
if ( grad == GRADIENT_PHASED ) {
phases = phases_from_list(reflections);
} else {
phases = NULL;
}
intensities = intensities_from_list(reflections, sym);
phases = phases_from_list(reflections);
flags = flags_from_list(reflections);
/* Check that the intensities have the correct symmetry */
if ( check_list_symmetry(reflections, sym) ) {
ERROR("The input reflection list does not appear to"
" have symmetry %s\n", symmetry_name(sym));
return 1;
}
reflist_free(reflections);
}
/* Define image parameters */
image.width = image.det->max_fs + 1;
image.height = image.det->max_ss + 1;
double wl = ph_en_to_lambda(eV_to_J(photon_energy));
image.lambda = wl;
image.bw = bandwidth;
image.nsamples = nsamples;
free(beamfile);
/* Load unit cell */
input_cell = load_cell_from_file(filename);
if ( input_cell == NULL ) {
exit(1);
}
/* Initialise stuff */
image.filename = NULL;
image.features = NULL;
image.flags = NULL;
rng = gsl_rng_alloc(gsl_rng_mt19937);
if ( config_random ) {
FILE *fh;
unsigned long int seed;
fh = fopen("/dev/urandom", "r");
fread(&seed, sizeof(seed), 1, fh);
fclose(fh);
gsl_rng_set(rng, seed);
}
powder = calloc(1, sizeof(struct image));
powder->width = image.width;
powder->height = image.height;
powder->det = image.det;
powder_data = calloc(image.width*image.height, sizeof(float));
powder->data = powder_data;
/* Splurge a few useful numbers */
STATUS("Wavelength is %f nm\n", image.lambda/1.0e-9);
do {
int na, nb, nc;
double a, b, c, d;
UnitCell *cell;
if ( random_size ) {
double alen, blen, clen, dis;
cell_get_parameters(input_cell, &alen, &blen, &clen,
&dis, &dis, &dis);
na = random_ncells(alen, min_size, max_size);
nb = random_ncells(blen, min_size, max_size);
nc = random_ncells(clen, min_size, max_size);
} else {
na = 8;
nb = 8;
nc = 8;
}
if ( st == NULL ) {
if ( config_randomquat ) {
orientation = random_quaternion(rng);
} else {
orientation = read_quaternion();
}
STATUS("Orientation is %5.3f %5.3f %5.3f %5.3f\n",
orientation.w, orientation.x,
orientation.y, orientation.z);
if ( !quaternion_valid(orientation) ) {
ERROR("Orientation modulus is not zero!\n");
return 1;
}
cell = cell_rotate(input_cell, orientation);
} else {
struct image image;
int i;
Crystal *cr;
image.det = NULL;
/* Get data from next chunk */
if ( read_chunk(st, &image) ) break;
free(image.filename);
image_feature_list_free(image.features);
if ( image.n_crystals == 0 ) continue;
cr = image.crystals[0];
cell = crystal_get_cell(cr);
if ( image.n_crystals > 1 ) {
ERROR("Using the first crystal only.\n");
}
for ( i=1; i<image.n_crystals; i++ ) {
Crystal *cr = image.crystals[i];
cell = crystal_get_cell(cr);
reflist_free(crystal_get_reflections(cr));
cell_free(crystal_get_cell(cr));
crystal_free(cr);
}
free(image.crystals);
}
switch ( spectrum_type ) {
case SPECTRUM_TOPHAT :
image.spectrum = generate_tophat(&image);
break;
case SPECTRUM_SASE :
image.spectrum = generate_SASE(&image, rng);
break;
case SPECTRUM_TWOCOLOUR :
image.spectrum = generate_twocolour(&image);
break;
}
/* Ensure no residual information */
image.data = NULL;
image.twotheta = NULL;
cell_get_parameters(cell, &a, &b, &c, &d, &d, &d);
STATUS("Particle size = %i x %i x %i"
" ( = %5.2f x %5.2f x %5.2f nm)\n",
na, nb, nc, na*a/1.0e-9, nb*b/1.0e-9, nc*c/1.0e-9);
if ( config_gpu ) {
if ( gctx == NULL ) {
gctx = setup_gpu(config_nosfac,
intensities, flags, sym_str,
gpu_dev);
}
get_diffraction_gpu(gctx, &image, na, nb, nc, cell,
no_fringes);
} else {
get_diffraction(&image, na, nb, nc, intensities, phases,
flags, cell, grad, sym, no_fringes);
}
if ( image.data == NULL ) {
ERROR("Diffraction calculation failed.\n");
goto skip;
}
record_image(&image, !config_nonoise, background, rng,
beam_radius, nphotons);
if ( powder_fn != NULL ) {
int x, y, w;
w = image.width;
for ( x=0; x<image.width; x++ ) {
for ( y=0; y<image.height; y++ ) {
powder->data[x+w*y] += (double)image.data[x+w*y];
}
}
if ( !(ndone % 10) ) {
hdf5_write_image(powder_fn, powder, NULL);
}
}
if ( !config_noimages ) {
char filename[1024];
if ( n_images != 1 ) {
snprintf(filename, 1023, "%s-%i.h5",
outfile, number);
} else {
strncpy(filename, outfile, 1023);
}
number++;
/* Write the output file */
hdf5_write_image(filename, &image, NULL);
}
/* Clean up */
free(image.data);
free(image.twotheta);
cell_free(cell);
skip:
ndone++;
if ( n_images && (ndone >= n_images) ) done = 1;
} while ( !done );
if ( powder_fn != NULL ) {
hdf5_write_image(powder_fn, powder, NULL);
}
if ( gctx != NULL ) {
cleanup_gpu(gctx);
}
free(image.det->panels);
free(image.det);
free(powder->data);
free(powder);
cell_free(input_cell);
free(intensities);
free(outfile);
free(filename);
free(sym_str);
free_symoplist(sym);
gsl_rng_free(rng);
return 0;
}
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