/* * process_image.c * * The processing pipeline for one image * * Copyright © 2012-2021 Deutsches Elektronen-Synchrotron DESY, * a research centre of the Helmholtz Association. * * Authors: * 2010-2020 Thomas White * 2014-2017 Valerio Mariani * 2017 Stijn de Graaf * * 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 . * */ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "process_image.h" #include "predict-refine.h" #include "im-sandbox.h" #include "im-zmq.h" #include "time-accounts.h" static float **backup_image_data(float **dp, struct detgeom *det) { float **bu; int i; bu = malloc(det->n_panels * sizeof(float *)); if ( bu == NULL ) return NULL; for ( i=0; in_panels; i++ ) { size_t data_size; data_size = det->panels[i].w * det->panels[i].h * sizeof(float); bu[i] = malloc(data_size); if ( bu[i] == NULL ) { free(bu); ERROR("Failed to allocate pre-filter backup.\n"); return NULL; } memcpy(bu[i], dp[i], data_size); } return bu; } static void restore_image_data(float **dp, struct detgeom *det, float **bu) { int i; for ( i=0; in_panels; i++ ) { size_t data_size; data_size = det->panels[i].w * det->panels[i].h * sizeof(float); memcpy(dp[i], bu[i], data_size); free(bu[i]); } free(bu); } static struct image *file_wait_open_read(const char *filename, const char *event, DataTemplate *dtempl, struct sb_shm *sb_shared, TimeAccounts *taccs, char *last_task, signed int wait_for_file, int cookie, int no_image_data, int no_mask_data) { signed int file_wait_time = wait_for_file; int wait_message_done = 0; int read_retry_done = 0; int r; struct image *image; time_accounts_set(taccs, TACC_WAITFILE); set_last_task(last_task, "wait for file"); do { struct stat statbuf; sb_shared->pings[cookie]++; r = stat(filename, &statbuf); if ( r ) { if ( (wait_for_file != 0) && (file_wait_time != 0) ) { if ( !wait_message_done ) { STATUS("Waiting for '%s'\n", filename); wait_message_done = 1; } sleep(1); if ( wait_for_file != -1 ) { file_wait_time--; } continue; } ERROR("File %s not found\n", filename); return NULL; } } while ( r ); time_accounts_set(taccs, TACC_HDF5OPEN); set_last_task(last_task, "open file"); sb_shared->pings[cookie]++; do { time_accounts_set(taccs, TACC_HDF5READ); set_last_task(last_task, "read file"); sb_shared->pings[cookie]++; image = image_read(dtempl, filename, event, no_image_data, no_mask_data); if ( image == NULL ) { if ( wait_for_file && !read_retry_done ) { read_retry_done = 1; STATUS("File '%s' exists but could not be read." " Trying again after 10 seconds.\n", filename); sleep(10); continue; } ERROR("Couldn't read image: %s\n", filename); return NULL; } } while ( image == NULL ); return image; } void process_image(const struct index_args *iargs, struct pattern_args *pargs, Stream *st, int cookie, const char *tmpdir, int serial, struct sb_shm *sb_shared, TimeAccounts *taccs, char *last_task) { struct image *image; int i; int r; int ret; char *rn; float **prefilter; int any_crystals; if ( pargs->zmq_data != NULL ) { set_last_task(last_task, "unpacking messagepack object"); image = image_read_data_block(iargs->dtempl, pargs->zmq_data, pargs->zmq_data_size, DATA_SOURCE_TYPE_MSGPACK, serial, iargs->no_image_data, iargs->no_mask_data); if ( image == NULL ) return; } else { image = file_wait_open_read(pargs->filename, pargs->event, iargs->dtempl, sb_shared, taccs, last_task, iargs->wait_for_file, cookie, iargs->no_image_data, iargs->no_mask_data); if ( image == NULL ) { if ( iargs->wait_for_file != 0 ) { pthread_mutex_lock(&sb_shared->totals_lock); sb_shared->should_shutdown = 1; pthread_mutex_unlock(&sb_shared->totals_lock); } return; } } image->serial = serial; /* Take snapshot of image before applying horrible noise filters */ time_accounts_set(taccs, TACC_FILTER); set_last_task(last_task, "image filter"); sb_shared->pings[cookie]++; prefilter = backup_image_data(image->dp, image->detgeom); if ( iargs->median_filter > 0 ) { filter_median(image, iargs->median_filter); } if ( iargs->noisefilter ) { filter_noise(image); } time_accounts_set(taccs, TACC_RESRANGE); set_last_task(last_task, "resolution range"); sb_shared->pings[cookie]++; mark_resolution_range_as_bad(image, iargs->highres, +INFINITY); time_accounts_set(taccs, TACC_PEAKSEARCH); sb_shared->pings[cookie]++; switch ( iargs->peaks ) { case PEAK_HDF5: case PEAK_CXI: set_last_task(last_task, "peaksearch:hdf5orcxi"); image->features = image_read_peaks(iargs->dtempl, pargs->filename, pargs->event, iargs->half_pixel_shift); if ( image->features == NULL ) { ERROR("Failed to get peaks from HDF5 file.\n"); } if ( !iargs->no_revalidate ) { validate_peaks(image, iargs->min_snr, iargs->pk_inn, iargs->pk_mid, iargs->pk_out, iargs->use_saturated, iargs->check_hdf5_snr); } break; case PEAK_ZAEF: set_last_task(last_task, "peaksearch:zaef"); search_peaks(image, iargs->threshold, iargs->min_sq_gradient, iargs->min_snr, iargs->pk_inn, iargs->pk_mid, iargs->pk_out, iargs->use_saturated); break; case PEAK_PEAKFINDER8: set_last_task(last_task, "peaksearch:pf8"); if ( search_peaks_peakfinder8(image, 2048, iargs->threshold, iargs->min_snr, iargs->min_pix_count, iargs->max_pix_count, iargs->local_bg_radius, iargs->min_res, iargs->max_res, iargs->use_saturated) ) { ERROR("Failed to find peaks in image %s" "(event %s).\n", image->filename, image->ev); } break; case PEAK_PEAKFINDER9: set_last_task(last_task, "peaksearch:pf9"); if ( search_peaks_peakfinder9(image, iargs->min_snr_biggest_pix, iargs->min_snr_peak_pix, iargs->min_snr, iargs->min_sig, iargs->min_peak_over_neighbour, iargs->local_bg_radius) ) { ERROR("Failed to find peaks in image %s" "(event %s).\n", image->filename, image->ev); } break; case PEAK_MSGPACK: image->features = image_msgpack_read_peaks(iargs->dtempl, pargs->zmq_data, pargs->zmq_data_size, iargs->half_pixel_shift); break; case PEAK_NONE: case PEAK_ERROR: break; } image->peak_resolution = estimate_peak_resolution(image->features, image->lambda, image->detgeom); restore_image_data(image->dp, image->detgeom, prefilter); rn = getcwd(NULL, 0); r = chdir(tmpdir); if ( r ) { ERROR("Failed to chdir to temporary folder: %s\n", strerror(errno)); return; } /* Set beam parameters */ if ( iargs->fix_divergence >= 0.0 ) { image->div = iargs->fix_divergence; } else { image->div = 0.0; } if ( image_feature_count(image->features) < iargs->min_peaks ) { r = chdir(rn); if ( r ) { ERROR("Failed to chdir: %s\n", strerror(errno)); return; } free(rn); image->hit = 0; if ( iargs->stream_nonhits ) { goto streamwrite; } else { goto out; } } image->hit = 1; /* Index the pattern */ time_accounts_set(taccs, TACC_INDEXING); set_last_task(last_task, "indexing"); index_pattern_3(image, iargs->ipriv, &sb_shared->pings[cookie], last_task); r = chdir(rn); if ( r ) { ERROR("Failed to chdir: %s\n", strerror(errno)); return; } free(rn); /* Set beam/crystal parameters */ time_accounts_set(taccs, TACC_PREDPARAMS); set_last_task(last_task, "prediction params"); if ( iargs->fix_profile_r >= 0.0 ) { for ( i=0; in_crystals; i++ ) { crystal_set_profile_radius(image->crystals[i], iargs->fix_profile_r); crystal_set_mosaicity(image->crystals[i], 0.0); } } else { for ( i=0; in_crystals; i++ ) { crystal_set_profile_radius(image->crystals[i], 0.02e9); crystal_set_mosaicity(image->crystals[i], 0.0); } } if ( iargs->fix_profile_r < 0.0 ) { for ( i=0; in_crystals; i++ ) { if ( refine_radius(image->crystals[i], image) ) { ERROR("WARNING: Radius determination failed\n"); } } } /* Integrate! */ time_accounts_set(taccs, TACC_INTEGRATION); set_last_task(last_task, "integration"); sb_shared->pings[cookie]++; integrate_all_5(image, iargs->int_meth, PMODEL_XSPHERE, iargs->push_res, iargs->ir_inn, iargs->ir_mid, iargs->ir_out, iargs->int_diag, iargs->int_diag_h, iargs->int_diag_k, iargs->int_diag_l, &sb_shared->term_lock, iargs->overpredict); streamwrite: time_accounts_set(taccs, TACC_WRITESTREAM); set_last_task(last_task, "stream write"); sb_shared->pings[cookie]++; ret = stream_write_chunk(st, image, iargs->stream_flags); if ( ret != 0 ) { ERROR("Error writing stream file.\n"); } int n = 0; for ( i=0; in_crystals; i++ ) { n += crystal_get_num_implausible_reflections(image->crystals[i]); } if ( n > 0 ) { STATUS("WARNING: %i implausibly negative reflection%s in %s " "%s\n", n, n>1?"s":"", image->filename, image->ev); } out: /* Count crystals which are still good */ time_accounts_set(taccs, TACC_TOTALS); set_last_task(last_task, "process_image finalisation"); sb_shared->pings[cookie]++; pthread_mutex_lock(&sb_shared->totals_lock); any_crystals = 0; for ( i=0; in_crystals; i++ ) { if ( crystal_get_user_flag(image->crystals[i]) == 0 ) { sb_shared->n_crystals++; any_crystals = 1; } } sb_shared->n_processed++; sb_shared->n_hits += image->hit; sb_shared->n_hadcrystals += any_crystals; pthread_mutex_unlock(&sb_shared->totals_lock); /* Free image (including detgeom) */ image_free(image); set_last_task(last_task, "sandbox"); }