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v1.0.0-rc.157 (#67)
This is an UNSTABLE release. It includes many experimental features, as well as many AI generated fixes. We recommend using rc.152 for production use.

* rugnux: Rebrand the offline data-processing subsystem as `rugnux` and consolidate all offline analysis into the single `rugnux` binary - `jfjoch_process` is now `rugnux`, the former `jfjoch_azint` is now `rugnux --azint-only`, and `jfjoch_scale` is now `rugnux --scale` (see the new docs/NAMING.md and docs/RUGNUX.md). Scaling and merging are on by default for rotation and stills (`--no-merge` disables them), replacing the previous opt-in `-M, --scale-merge`.
* rugnux: CLI fixes - default `-N` to all hardware threads, parse numeric option arguments strictly (reject non-numeric or trailing input instead of silently yielding 0), require `--wavelength > 0`, and correct the reproduced command line and `--scale` reference-cell handling.
* rugnux: De-novo space-group improvements - recover genuine high symmetry and centred Bravais lattices from intensities, add an automatic CC1/2 high-resolution cutoff, and report L-test twinning statistics.
* rugnux: Index weakly-diffracting low-resolution rotation data that previously failed (e.g. F-cubic crystals that diffract only to ~4 A on a detector reaching ~1.5 A). The per-frame indexing gate now measures the indexed fraction only within the resolution range the lattice actually diffracts to, so the many sub-diffraction ice/noise spots no longer make the fraction floor unreachable; the two-pass first pass tries several image-sampling schemes (spread across the whole rotation vs a consecutive wedge whose native stride keeps a reflection's rocking curve continuous, letting the FFT resolve a long axis) and keeps the one that indexes the most frames; and the de-novo space-group search no longer discards all reflections (and crashes) when every resolution shell falls below <I/sigma> = 1.
* rugnux: Lower the low-resolution R-meas for strongly-diffracting rotation data - drop edge-of-sweep truncated fulls whose rocking curve was captured below `--min-captured-fraction` (default 0.7 for rotation), and report R-meas only over the observations kept by outlier rejection (matching XDS). The 0.7 default also strips the partiality-extrapolated fulls that dominate the intensity second moment on weakly-diffracting crystals, so the de-novo space-group search is no longer starved by the error-model I/sigma floor and recovers the correct symmetry (e.g. the F-cubic Benas crystals: Benas_3 -> F432, Benas_7 -> P6122, instead of P4/P1); on the reference battery every other crystal keeps its space group.
* rugnux: Write the refined geometry (beam, tilt, axis) to _process.h5 and place non-standard mmCIF items under a reserved `jfjoch` prefix.
* jfjoch_broker: Ordinary acquisition failures (receiver/writer/analysis problems, missed packets, writer disconnect) now return to the Idle state with an Error-severity message, so a run can be retried without an expensive re-initialisation; only failures that leave the detector in an undefined state (new JFJochCriticalException, e.g. PCIe/FPGA faults) go to the Error state and force re-initialisation.
* jfjoch_broker: A synchronous /start now reports its failure to the HTTP caller instead of returning HTTP 200, and an incomplete or truncated dataset (missing packets, writer disconnect) is reported as an error rather than a "reduce frame rate" warning.
* jfjoch_broker: Drop uncollected placeholder rows (number = -1) from the scan_result REST endpoint.
* jfjoch_broker: Fix the inverted per-image compression ratio reported by the Lite receiver (was compressed/uncompressed instead of uncompressed/compressed).
* jfjoch_broker: Bragg integration adds a quantization-noise variance floor with a box-sum fallback, and treats the type-maximum marker as an invalid pixel for unsigned image types.
* jfjoch_writer: Detect file-overwrite conflicts at start for back-channel transports, and reset the writer when end-of-collection finalisation fails.
* jfjoch_viewer: Preview overlays follow the geometry (resolution/ROI arcs, true beam centre, predictions, coral secondary-lattice spots, legend), add save-as-JPEG, and fix an HTTP live-follow memory leak.
* Frontend: Improved aesthetics and usability, and added in-browser pixel-mask and JUNGFRAU-pedestal visualisation.
* CI: Name the Windows installer jfjoch-viewer-* instead of jfjoch-*.Reviewed-on: #67

Co-authored-by: Filip Leonarski <filip.leonarski@psi.ch>
2026-07-11 07:19:11 +02:00

14 KiB

CLAUDE.md

This file provides guidance to Claude Code (claude.ai/code) when working with code in this repository.

What this is

Jungfraujoch is the data-acquisition and analysis system for the PSI JUNGFRAU and EIGER X-ray detectors. It receives detector data, runs it through an FPGA-accelerated pipeline (spot finding, azimuthal/ROI integration, compression), streams images out over ZeroMQ for writing to HDF5, and runs crystallographic analysis (indexing, integration, scaling/merging). Most authoritative documentation lives in docs/ and on Read The Docs (https://jungfraujoch.readthedocs.io). When changing CLI behaviour, the program's own usage message is the source of truth, not the docs.

Build

Out-of-source CMake build, C++20, heavy use of FetchContent (spdlog, zstd, HDF5, slsDetectorPackage, Catch2, cpp-httplib, libzmq, Ceres, fast-feedback-indexer are downloaded and statically linked — the first configure needs network access and is slow).

mkdir build && cd build
cmake -DCMAKE_BUILD_TYPE=Release ..
make -j$(nproc) jfjoch_broker      # the main service; build other targets by name

Key CMake options:

  • JFJOCH_USE_CUDA (default ON) — GPU path. Needs CUDA ≥ 12.8. Provides the ffbidx and fft GPU indexers; without it only the CPU fftw indexer is available (requires FFTW at configure time, auto-detected). CUDA absence is not a build error.
  • JFJOCH_WRITER_ONLY (default OFF) — builds only the HDF5 writer; skips broker, FPGA, receiver, analysis, tests, frontend.
  • JFJOCH_VIEWER_BUILD (default OFF) — builds the Qt6 jfjoch_viewer desktop app.
  • SLS9 (default OFF) — build against slsDetectorPackage 9.2.0 instead of 8.0.2.

The frontend is a separate custom target: make frontend (runs npm ci && npm run build in frontend/). It is not built by default unless installing.

Test

Tests use Catch2 and are collected into a single binary tests/jfjoch_test.

make -j$(nproc) jfjoch_test
cd tests
./jfjoch_test                       # all tests
./jfjoch_test "<test name>"         # one test case (exact name in TEST_CASE)
./jfjoch_test "[tag]"               # by tag
./jfjoch_test -r junit -o report.xml

make jfjoch_hdf5_test builds the HDF5 write-speed benchmark, also used by CI to produce files that are validated against XDS (Durin/Neggia) and CrystFEL.

Lint config is .clang-tidy (broad * check set with many exceptions; namespaces lower_case, classes CamelCase, global constants UPPER_CASE).

Code style

The overriding principle is simple, readable code — favour the smallest, most direct implementation that a reader can verify at a glance. Extra abstraction, speculative guards, and clever-but-dense constructs are treated as actively harmful, not as polish. When torn between a tidy abstraction and a flat, obvious version, pick the obvious one.

This matters most in image_analysis/pixel_refinement/ (e.g. PixelRefine.cpp), which is an experimental prototype where readability is how the physics gets verified — keep it especially plain. Do not add defensive/unrequested code (extra validation, rejection heuristics, "just in case" branches) without asking first; if a guard isn't clearly needed, leave it out.

Match the surrounding code's idiom, naming, and comment density rather than importing a different style.

Local end-to-end run (no detector / no FPGA)

The FPGA HLS logic can be simulated on the CPU (HLSSimulatedDevice), so the full software stack runs without hardware (slowly — fixed-point math on CPU). See docs/JFJOCH_BROKER.md for the canonical walkthrough.

cd build/broker
./jfjoch_broker ../../etc/broker_local.json 5232      # config JSON + HTTP port
# then, separately:
cd tests/test_data && python jfjoch_broker_test.py     # feeds a test image, starts collection
# observe at http://localhost:5232 ; HDF5 is written under build/broker

etc/broker_local.json, broker_eiger.json, broker_crmx.json are example broker configs (schema = jfjoch_settings in broker/jfjoch_api.yaml).

Architecture

Data flow (online): detector → FPGA acquisition (fpga/, acquisition_device/) → receiver/ builds full images from per-module FPGA output → image_pusher/ streams CBOR-encoded images over ZeroMQ → jfjoch_writer (writer/) consumes the stream and writes NXmx HDF5. The broker also emits a low-rate preview stream and a metadata stream (preview/).

Writer file split: one acquisition produces one _master.h5 plus many _data_NNNNNN.h5 files. Dataset-wide metadata (geometry, detector config, ROI/azimuthal definitions — anything fixed for the whole run) is written to the master file in writer/HDF5NXmx.cpp (the NXmx class). Per-image arrays (one entry per frame) are written to the data files by the HDF5DataFilePlugin subclasses in writer/. Put shared metadata in NXmx, not in a data-file plugin.

The HDF5 master/data layout is one of three FileWriterFormats (common/JFJochMessages.h), all NXmx: NXmxLegacy (master + _data_NNNNNN.h5 joined by external links), NXmxVDS (master + data joined by HDF5 virtual datasets — the default), and NXmxIntegrated (a single self-contained file, no separate data files). Per-image plugins must work for all three; with NXmxIntegrated "master" and "data" are the same file.

Two acquisition workflows: the FPGA-accelerated path (JUNGFRAU at PSI; FPGA does masking, summation, spot finding, ROI/azimuthal integration, compression) and the DECTRIS SIMPLON path (EIGER), which has no FPGA — masking/ROI/azimuthal analysis then runs on CPU through the shared image_analysis/ library. Treat ROI and azimuthal features as available in both workflows, not FPGA-only.

jfjoch_broker (broker/) is the central online service: HTTP/REST + OpenAPI control plane, FPGA configuration, image building, ZeroMQ output. JFJochStateMachine drives acquisition state; JFJochServices wires the pieces; OpenAPIConvert/JFJochBrokerParser translate between the generated API model and internal types.

Three analysis frontends share one analysis library (image_analysis/, built as JFJochImageAnalysis):

  • jfjoch_broker — online, real-time (FPGA + GPU).
  • jfjoch_viewer — interactive Qt desktop (viewer/), results not persisted.
  • rugnux (tools/rugnux_cli.cpp, built on the Rugnux library in rugnux/) — offline batch over a stored HDF5; writes _process.h5 and .mtz/.cif/.hkl. Merging is on by default (--no-merge to disable); --azint-only runs only azimuthal integration and --scale re-scales/merges the already-integrated reflections in a _process.h5. (rugnux = the data-processing half of the system; see docs/NAMING.md.)

image_analysis/ pipeline (subdirs): spot_finding, indexing (ffbidx/fft GPU, fftw CPU), lattice_search, geom_refinement, pixel_refinement, bragg_prediction, bragg_integration, rotation_indexer, azint, roi, scale_merge. Least-squares refinement uses Ceres (fetched, built with miniglog, no MKL, CXX_THREADS). ffbidx needs a known cell (-C) and suits sparse serial stills; fft/fftw index de novo and suit strong rotation data.

FPGA (fpga/): hls/ is the Vitis HLS source (image-analysis kernels), hls_simulation/ runs that same HLS on CPU for hardware-free testing, host_library/ is the host-side driver, pcie_driver/ is the kernel module. The HLS algorithms are documented in docs/FPGA_DATA_ANALYSIS.md.

Detector control (detector_control/): wrappers for SLS (JUNGFRAU) and DECTRIS SIMPLON (EIGER). jungfrau/: JUNGFRAU ADU→energy gain/pedestal calibration.

Other libs: common/ (geometry, diffraction experiment, image buffer, CUDA wrappers — the shared core, linked nearly everywhere), compression/ (zstd + bitshuffle + sqrt lossy), frame_serialize/ (CBOR stream codec), gemmi_gph/ (vendored GEMMI for MTZ/XDS_ASCII I/O), xds-plugin/ (XDS HDF5 read plugin).

Portability (jfjoch_viewer)

Cross-platform support is a goal only for jfjoch_viewer and its dependency tree — keep that code, and any shared library it transitively links (common/, image_analysis/, reader/, gemmi_gph/, etc.), MSVC-compatible so the viewer can build on Windows. The rest of the project (broker, receiver, FPGA host, detector control, …) is Linux-only and does not need to be portable; don't constrain it for portability's sake.

  • Windows/MSVC is the primary portability target. The end goal is a Windows viewer built with MSVC and CUDA (JFJOCH_USE_CUDA=ON): GPU processing is a wanted feature, not optional, so the intended Windows config is the full GPU path (ffbidx, GPU fft), not a CPU-only fallback. MSVC is required regardless, because CUDA on Windows requires it. Avoid GCC/Clang-only extensions, POSIX-only APIs, and other non-MSVC constructs in viewer-reachable code, and keep CUDA-reachable viewer code (ffbidx, GPU indexers) MSVC-buildable too.
  • macOS is a nice-to-have for the viewer. It rules out CUDA, so anything the viewer depends on must also have a working CPU-only / non-CUDA path (the JFJOCH_USE_CUDA=OFF, fftw-indexer configuration). This non-CUDA path must keep working, but it is the macOS fallback — not the intended Windows configuration.

A self-contained Windows build still needs a few dependencies that the Linux build picks up from the system and that are not auto-provided via FetchContent (besides Qt, supplied externally): ZLIB (pulled by hdf5/libtiff/gemmi/libzmq — a bundled zlib-ng in ZLIB_COMPAT mode is the intended fix, presented as the ZLIB::ZLIB target so the scattered find_package(ZLIB) calls resolve), libjpeg-turbo (used by preview/; upstream discourages add_subdirectory, so bring it in via ExternalProject), and Eigen (header-only; needed by Ceres, by the analysis libs directly, and by ffbidx under CUDA — fetch it and point Ceres' internal find_package(Eigen3) at it). Wire each guarded so the Linux build, which finds these on the system, stays unchanged.

OpenAPI is the single source of truth

broker/jfjoch_api.yaml defines the entire REST API and the shared data schemas. From it, update_version.sh regenerates three clients — do not hand-edit generated code:

  • C++ server model → broker/gen/ (cpp-pistache-server generator; compiled as JFJochAPI).
  • Python client → python-client/ (and gen_python_client.sh, published as PyPI jfjoch-client).
  • TypeScript frontend client → frontend/src/client/ (hey-api openapi-ts, npm run openapi).

When you change jfjoch_api.yaml, regenerate the relevant client(s); for a version bump run update_version.sh (also rewrites VERSION, frontend/src/version.ts, and the Redoc html).

Frontend

React 19 + TypeScript + MUI + Vite (frontend/). Data layer is generated from the OpenAPI spec (@hey-api/openapi-ts → fetch client + TanStack Query hooks + zod schemas). Scripts: npm start (dev server), npm run build (tsc + vite), npm run openapi (regen client), npm run redocly4broker (regen broker/redoc-static.html).

Adding a per-image scalar quantity

A per-image scalar (e.g. ice_ring_score, bkg_estimate, mosaicity) flows analysis → message → CBOR → HDF5 → scan-result/plot → API → viewer/frontend. To add one, mirror an existing float scalar (bkg_estimate is a clean template) at every layer:

  1. Compute where the azint profile is finalized: image_analysis/MXAnalysisWithoutFPGA.cpp (CPU), receiver/JFJochReceiverFPGA.cpp (FPGA), and the offline azint worker in rugnux/Rugnux.cpp.
  2. Message (common/JFJochMessages.h): std::optional<float> in DataMessage, std::vector<float> in EndMessage.
  3. CBOR: encode in frame_serialize/CBORStream2Serializer.cpp (DataMessage block and END block), decode in CBORStream2Deserializer.cpp (both). Optional fields are back-compatible — no version bump.
  4. HDF5 write: writer/HDF5DataFilePluginMX.{h,cpp} — an AutoIncrVector<float> with reserve / per-image write / SaveVector("/entry/MX/<name>") (per-image arrays live in the data-file plugin); plus the NXmx master write in writer/HDF5NXmx.cpp (SaveVectorIfMissing(..., end.<name>)). HDF5 read-back (so a stored file re-opens, e.g. in the viewer) is in reader/HDF5MetadataSource.cpp, NOT JFJochHDF5Reader.cpp: mirror the three bkgEstimate sites — master ReadOptVector, data-file ReadVector into the dataset, and the per-image message population.
  5. Scan result: common/ScanResult.h (ScanResultElem) + common/ScanResultGenerator.cpp (copy in Add, resize+fill in FillEndMessage).
  6. Receiver plot: common/Plot.h (PlotType) + common/JFJochReceiverPlots.{h,cpp} (StatusVector
    • Clear / AddElement / GetPlots / GetPlotRaw cases).
  7. API: add to the plot_type enum and the scan_result images schema in broker/jfjoch_api.yaml, regenerate the C++ model (java -jar openapi-generator-cli.jar generate -i broker/jfjoch_api.yaml -o broker/gen -g cpp-pistache-server) and the frontend client (cd frontend && npm run openapi), then wire broker/OpenAPIConvert.cpp (ConvertPlotType string→enum and the Convert(ScanResult) setter).
  8. Reader/viewer: reader/JFJochReaderDataset.h + reader/JFJochHttpReader.cpp (GetPlot_i) and viewer/JFJochViewerDatasetInfo.cpp (combo item + ExtractMetric).
  9. Frontend: frontend/src/components/DataProcessingPlots.tsx (MenuItem) + DataProcessingPlot.tsx (y-axis label).
  10. Docs: docs/CBOR.md, docs/HDF5.md, docs/CPU_DATA_ANALYSIS.md.

Gotcha: an existing build/ dir needs a cmake . reconfigure to pick up a newly-added broker/gen source file (the source list is a configure-time glob).