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/*
* intensities.c
*
* Extract integrated intensities by relrod estimation
*
* (c) 2007 Thomas White <taw27@cam.ac.uk>
*
* dtr - Diffraction Tomography Reconstruction
*
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include "control.h"
#include "reflections.h"
#include "image.h"
#include "reproject.h"
#include "displaywindow.h"
/* Extract integrated reflection intensities by estimating the spike function
* based on the observed intensity and the calculated excitation error from
* the lattice refinement. Easy. */
void intensities_extract(ControlContext *ctx) {
int i, j;
int n_meas, n_dupl, n_notf;
double max;
Reflection *reflection;
/* Free previous analysis if required */
if ( ctx->integrated != NULL ) {
reflectionlist_free(ctx->integrated);
}
ctx->integrated = reflectionlist_new();
n_meas = 0;
n_dupl = 0;
n_notf = 0;
max = 0;
for ( i=0; i<ctx->images->n_images; i++ ) {
ImageRecord *image;
image = &ctx->images->images[i];
if ( image->rflist == NULL ) image->rflist = reproject_get_reflections(image, ctx->cell_lattice);
for ( j=0; j<image->rflist->n_features; j++ ) {
ImageFeature *feature;
signed int h, k, l;
feature = &image->rflist->features[j];
h = feature->reflection->h;
k = feature->reflection->k;
l = feature->reflection->l;
if ( feature->partner != NULL ) {
if ( (h!=0) || (k!=0) || (l!=0) ) {
double intensity;
Reflection *new;
/* Perform relrod calculation of doom here.
* TODO: Figure out if this is even possible. */
intensity = feature->partner->intensity;
new = reflection_add(ctx->integrated,
feature->reflection->x, feature->reflection->y, feature->reflection->z,
intensity, REFLECTION_GENERATED);
if ( new != NULL ) {
new->h = h;
new->k = k;
new->l = l;
//printf("IN: Adding %3i %3i %3i, intensity=%f\n", h, k, l, intensity);
if ( intensity > max ) max = intensity;
n_meas++;
} else {
printf("IN: Duplicate measurement for %3i %3i %3i\n", h, k, l);
n_dupl++;
}
}
} else {
//printf("IN: %3i %3i %3i not found\n", h, k, l);
n_notf++;
}
}
}
/* Normalise all reflections to the most intense reflection */
reflection = ctx->integrated->reflections;
while ( reflection ) {
reflection->intensity /= max;
reflection = reflection->next;
}
printf("IN: %5i intensities measured\n", n_meas);
printf("IN: %5i duplicated measurements\n", n_dupl);
printf("IN: %5i predicted reflections not found\n", n_notf);
}
static int intensities_do_save(ReflectionList *integrated, const char *filename) {
FILE *fh;
Reflection *reflection;
fh = fopen(filename, "w");
reflection = integrated->reflections;
while ( reflection ) {
fprintf(fh, "%3i %3i %3i %12.8f\n", reflection->h, reflection->k, reflection->l, reflection->intensity);
reflection = reflection->next;
}
fclose(fh);
return 0;
}
static gint intensities_save_response(GtkWidget *widget, gint response, ControlContext *ctx) {
if ( response == GTK_RESPONSE_ACCEPT ) {
char *filename;
filename = gtk_file_chooser_get_filename(GTK_FILE_CHOOSER(widget));
if ( intensities_do_save(ctx->integrated, filename) ) {
displaywindow_error("Failed to save cache file.", ctx->dw);
}
g_free(filename);
}
gtk_widget_destroy(widget);
return 0;
}
void intensities_save(ControlContext *ctx) {
GtkWidget *save;
save = gtk_file_chooser_dialog_new("Save Reflections to File", GTK_WINDOW(ctx->dw->window),
GTK_FILE_CHOOSER_ACTION_SAVE,
GTK_STOCK_CANCEL, GTK_RESPONSE_CANCEL,
GTK_STOCK_OPEN, GTK_RESPONSE_ACCEPT,
NULL);
g_signal_connect(G_OBJECT(save), "response", G_CALLBACK(intensities_save_response), ctx);
gtk_widget_show_all(save);
}
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