// Copyright (2019-2024) Paul Scherrer Institute #include "MXAnalyzer.h" #include "CPUSpotFinder.h" #include "../common/DiffractionGeometry.h" #include "Regression.h" double stddev(const std::vector &v) { if (v.size() <= 1) return 0.0; double mean = 0.0f; for (const auto &i: v) mean += i; mean /= v.size(); double stddev = 0.0f; for (const auto &i: v) stddev += (i - mean) * (i - mean); return sqrt(stddev / (v.size() - 1)); } MXAnalyzer::MXAnalyzer(const DiffractionExperiment &in_experiment) : experiment(in_experiment) { auto uc = experiment.GetUnitCell(); if (uc) { do_indexing = true; indexer.Setup(uc.value()); } if (experiment.IsSpotFindingEnabled()) find_spots = true; } void MXAnalyzer::ReadFromFPGA(const DeviceOutput *output, const SpotFindingSettings &settings, size_t module_number) { if (!find_spots || !settings.enable) return; StrongPixelSet strong_pixel_set; strong_pixel_set.ReadFPGAOutput(experiment, *output); strong_pixel_set.FindSpots(experiment, settings, spots, module_number); } void MXAnalyzer::ReadFromCPU(const int16_t *image, const SpotFindingSettings &settings, size_t module_number) { if (!find_spots) return; if (experiment.GetPixelDepth() == 4) throw JFJochException(JFJochExceptionCategory::InputParameterInvalid, "CPU spot finder simulation doesn't support 32-bit images"); std::vector d_map(RAW_MODULE_SIZE); DeviceOutput output{}; memcpy(output.pixels, image, RAW_MODULE_SIZE * sizeof(int16_t)); CalcSpotFinderResolutionMap(d_map.data(), experiment, module_number); FindSpots(output, settings, d_map.data()); ReadFromFPGA(&output, settings, module_number); } bool MXAnalyzer::Process(DataMessage &message, const SpotFindingSettings& settings) { message.indexing_result = 0; if (!find_spots) return false; bool indexed = false; std::vector spots_out; FilterSpotsByCount(experiment, spots, spots_out); for (const auto &spot: spots_out) message.spots.push_back(spot); if (do_indexing && settings.indexing) { std::vector recip; recip.reserve(spots_out.size()); for (const auto &i: spots_out) recip.push_back(i.ReciprocalCoord(experiment)); auto indexer_result = indexer.Run(recip, settings.indexing_tolerance); float x_drift = 0.0f, y_drift = 0.0f; if (!indexer_result.empty()) { message.indexing_result = 1; CalculateBeamCenterAndDistance(spots_out, indexer_result[0], message); indexer_result[0].l.Save(message.indexing_lattice); message.indexing_unit_cell = indexer_result[0].l.GetUnitCell(); } } spots.clear(); return indexed; } void MXAnalyzer::CalculateBeamCenterAndDistance(const std::vector &spots, const IndexingResult& result, DataMessage &message) { if (spots.empty()) return; assert(result.predicted_spots.size() == spots.size()); std::vector spot_x_position(spots.size()); std::vector spot_y_position(spots.size()); std::vector spot_x_Sd1_over_Sd3(spots.size()); std::vector spot_y_Sd2_over_Sd3(spots.size()); for (int i = 0; i < spots.size(); i++) { spot_x_position[i] = spots[i].RawCoord().x * experiment.GetPixelSize_mm(); spot_y_position[i] = spots[i].RawCoord().y * experiment.GetPixelSize_mm(); Coord S = experiment.GetScatteringVector() + result.predicted_spots[i]; if (S.z != 0.0f) { spot_x_Sd1_over_Sd3[i] = S.x / S.z; spot_y_Sd2_over_Sd3[i] = S.y / S.z; } } auto reg_x = regression(spot_x_Sd1_over_Sd3, spot_x_position); auto reg_y = regression(spot_y_Sd2_over_Sd3, spot_y_position); message.corr_beam_x_pxl = experiment.GetBeamX_pxl() - reg_x.intercept / experiment.GetPixelSize_mm(); message.corr_beam_y_pxl = experiment.GetBeamY_pxl() - reg_y.intercept / experiment.GetPixelSize_mm(); message.corr_det_dist_mm = experiment.GetDetectorDistance_mm() - (reg_x.slope + reg_y.slope) / 2.0; }