/* * indexamajig.c * * Find hits, index patterns, output hkl+intensity etc. * * (c) 2006-2010 Thomas White * * Part of CrystFEL - crystallography with a FEL * */ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #include #include #include #include "utils.h" #include "hdf5-file.h" #include "index.h" #include "intensities.h" #include "peaks.h" #include "diffraction.h" #include "diffraction-gpu.h" #include "detector.h" #include "sfac.h" #include "filters.h" static void show_help(const char *s) { printf("Syntax: %s [options]\n\n", s); printf( "Process and index FEL diffraction images.\n" "\n" " -h, --help Display this help message.\n" "\n" " -i, --input= Specify file containing list of images to process.\n" " '-' means stdin, which is the default.\n" " --indexing= Use 'method' for indexing. Choose from:\n" " none : no indexing\n" " dirax : invoke DirAx\n" "\n" " --verbose Be verbose about indexing.\n" " --write-drx Write 'xfel.drx' for visualisation of reciprocal\n" " space. Implied by any indexing method other than\n" " 'none'. Beware: the units in this file are\n" " reciprocal Angstroms.\n" " --dump-peaks Write the results of the peak search to stdout.\n" " --near-bragg Output a list of reflection intensities to stdout.\n" " --simulate Simulate the diffraction pattern using the indexed\n" " unit cell.\n" " --gpu Use the GPU to speed up the simulation.\n" " --clean-image Perform common-mode noise subtraction and\n" " background removal on images before proceeding.\n" " --no-match Don't attempt to match the indexed cell to the\n" " model, just proceed with the one generated by the\n" " auto-indexing procedure.\n" ); } static struct image *get_simage(struct image *template, int alternate) { struct image *image; struct panel panels[2]; image = malloc(sizeof(*image)); /* Simulate a diffraction pattern */ image->twotheta = NULL; image->data = NULL; image->det = template->det; /* View head-on (unit cell is tilted) */ image->orientation.w = 1.0; image->orientation.x = 0.0; image->orientation.y = 0.0; image->orientation.z = 0.0; /* Detector geometry for the simulation * - not necessarily the same as the original. */ image->width = 1024; image->height = 1024; image->det.n_panels = 2; if ( alternate ) { /* Upper */ panels[0].min_x = 0; panels[0].max_x = 1023; panels[0].min_y = 512; panels[0].max_y = 1023; panels[0].cx = 523.6; panels[0].cy = 502.5; panels[0].clen = 56.4e-2; /* 56.4 cm */ panels[0].res = 13333.3; /* 75 microns/pixel */ /* Lower */ panels[1].min_x = 0; panels[1].max_x = 1023; panels[1].min_y = 0; panels[1].max_y = 511; panels[1].cx = 520.8; panels[1].cy = 772.1; panels[1].clen = 56.7e-2; /* 56.7 cm */ panels[1].res = 13333.3; /* 75 microns/pixel */ image->det.panels = panels; } else { /* Copy pointer to old geometry */ image->det.panels = template->det.panels; } image->lambda = ph_en_to_lambda(eV_to_J(1.8e3)); image->molecule = template->molecule; image->molecule->cell = template->indexed_cell; return image; } static void simulate_and_write(struct image *simage, struct gpu_context **gctx) { /* Set up GPU if necessary */ if ( (gctx != NULL) && (*gctx == NULL) ) { *gctx = setup_gpu(0, simage, simage->molecule); } if ( (gctx != NULL) && (*gctx != NULL) ) { get_diffraction_gpu(*gctx, simage, 24, 24, 40); } else { get_diffraction(simage, 24, 24, 40, 0, 0); } if ( simage->molecule == NULL ) { ERROR("Couldn't open molecule.pdb\n"); return; } record_image(simage, 0); hdf5_write("simulated.h5", simage->data, simage->width, simage->height, H5T_NATIVE_FLOAT); } int main(int argc, char *argv[]) { int c; struct gpu_context *gctx = NULL; char *filename = NULL; FILE *fh; char *rval; int n_images; int n_hits; int config_noindex = 0; int config_dumpfound = 0; int config_nearbragg = 0; int config_writedrx = 0; int config_simulate = 0; int config_clean = 0; int config_nomatch = 0; int config_gpu = 0; int config_verbose = 0; int config_alternate = 0; IndexingMethod indm; char *indm_str = NULL; struct image image; /* Long options */ const struct option longopts[] = { {"help", 0, NULL, 'h'}, {"input", 1, NULL, 'i'}, {"gpu", 0, &config_gpu, 1}, {"no-index", 0, &config_noindex, 1}, {"dump-peaks", 0, &config_dumpfound, 1}, {"near-bragg", 0, &config_nearbragg, 1}, {"write-drx", 0, &config_writedrx, 1}, {"indexing", 1, NULL, 'z'}, {"simulate", 0, &config_simulate, 1}, {"clean-image", 0, &config_clean, 1}, {"no-match", 0, &config_nomatch, 1}, {"verbose", 0, &config_verbose, 1}, {"alternate", 0, &config_alternate, 1}, {0, 0, NULL, 0} }; /* Short options */ while ((c = getopt_long(argc, argv, "hi:w", longopts, NULL)) != -1) { switch (c) { case 'h' : { show_help(argv[0]); return 0; } case 'i' : { filename = strdup(optarg); break; } case 'z' : { indm_str = strdup(optarg); break; } case 0 : { break; } default : { return 1; } } } if ( filename == NULL ) { filename = strdup("-"); } if ( strcmp(filename, "-") == 0 ) { fh = stdin; } else { fh = fopen(filename, "r"); } free(filename); if ( fh == NULL ) { ERROR("Failed to open input file\n"); return 1; } if ( indm_str == NULL ) { STATUS("You didn't specify an indexing method, so I won't" " try to index anything. If that isn't what you\n" " wanted, re-run with --indexing=.\n"); indm = INDEXING_NONE; } else if ( strcmp(indm_str, "none") == 0 ) { indm = INDEXING_NONE; } else if ( strcmp(indm_str, "dirax") == 0) { indm = INDEXING_DIRAX; } else { ERROR("Unrecognised indexing method '%s'\n", indm_str); return 1; } image.molecule = load_molecule(); if ( image.molecule == NULL ) { ERROR("You must provide molecule.pdb in the working " "directory.\n"); return 1; } n_images = 0; n_hits = 0; do { char line[1024]; struct hdfile *hdfile; struct image *simage; rval = fgets(line, 1023, fh); if ( rval == NULL ) continue; chomp(line); image.features = NULL; image.data = NULL; image.indexed_cell = NULL; #include "geometry-lcls.tmp" STATUS("Processing '%s'\n", line); n_images++; hdfile = hdfile_open(line); if ( hdfile == NULL ) { continue; } else if ( hdfile_set_first_image(hdfile, "/") ) { ERROR("Couldn't select path\n"); continue; } hdf5_read(hdfile, &image); if ( config_clean ) { clean_image(&image); } /* Perform 'fine' peak search */ search_peaks(&image); if ( image_feature_count(image.features) < 5 ) goto done; if ( config_dumpfound ) dump_peaks(&image); /* Not indexing nor writing xfel.drx? * Then there's nothing left to do. */ if ( (!config_writedrx) && (indm == INDEXING_NONE) ) { goto done; } /* Calculate orientation matrix (by magic) */ if ( config_writedrx || (indm != INDEXING_NONE) ) { index_pattern(&image, indm, config_nomatch, config_verbose); } /* No cell at this point? Then we're done. */ if ( image.indexed_cell == NULL ) goto done; n_hits++; simage = get_simage(&image, config_alternate); /* Measure intensities if requested */ if ( config_nearbragg ) { /* Use original data (temporarily) */ simage->data = image.data; output_intensities(simage, image.indexed_cell); simage->data = NULL; } /* Simulate if requested */ if ( config_simulate ) { if ( config_gpu ) { simulate_and_write(simage, &gctx); } else { simulate_and_write(simage, NULL); } } /* Finished with alternate image */ if ( simage->twotheta != NULL ) free(simage->twotheta); if ( simage->data != NULL ) free(simage->data); free(simage); done: free(image.data); free(image.det.panels); image_feature_list_free(image.features); hdfile_close(hdfile); H5close(); } while ( rval != NULL ); fclose(fh); STATUS("There were %i images.\n", n_images); STATUS("%i hits were found.\n", n_hits); if ( gctx != NULL ) { cleanup_gpu(gctx); } return 0; }