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Jungfraujoch/image_analysis/bragg_integration/BraggIntegrationEngineGPU.h
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v1.0.0-rc.156 (#66)
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.

* jfjoch_process: Major rotation (rot3d) data processing overhaul - robust profile-fit integration, Cauchy-loss scaling with optional absorption surface, de-novo indexing and space-group/centering determination fixes, and merging statistics + ISa in the mmCIF output.
* jfjoch_process: Add EXPERIMENTAL ice-ring detection (--detect-ice-rings) that excludes ice reflections from scaling.
* Compression: Add BSHUF_ZSTD_RLE_HUFF, make compression size-aware (drop frames that don't fit rather than aborting), and add the jfjoch_recompress tool.
* jfjoch_viewer: Report "Multiple lattices detected" and grey out "Analyze dataset" on a live connection.
* jfjoch_broker: Write smargon chi/phi goniometer positions to NXmx; read sensor thickness/material from HDF5 metadata.
* CI: Build Windows (CUDA and non-CUDA) installers.Reviewed-on: #66

Co-authored-by: Filip Leonarski <filip.leonarski@psi.ch>
2026-07-03 19:18:56 +02:00

58 lines
2.8 KiB
C++

// SPDX-FileCopyrightText: 2026 Filip Leonarski, Paul Scherrer Institute <filip.leonarski@psi.ch>
// SPDX-License-Identifier: GPL-3.0-only
#pragma once
#include <cstdint>
#include <memory>
#include <vector>
#include "BraggIntegrationEngine.h"
#include "../indexing/CUDAMemHelpers.h"
// CUDA engine: reproduces BraggIntegrationEngineCPU up to floating-point precision. Each stage is a
// kernel with one CUDA block per reflection cooperating over the small window via shared-memory
// reductions (the natural mapping for thousands of independent, tiny per-spot integrations).
//
// Pipeline (profile modes): reset -> mark_mask -> boxsum -> learn_profile -> build_profiles -> fit
// (the resolution shell is computed inline, so there is no separate shell pass). BoxSum mode stops
// after boxsum (that pass is the BraggIntegrate2D box integrator and the seed of the profile fit).
// The preprocessed image already lives on the device (ImagePreprocessorBufferGPU::getGPUBuffer());
// only the per-frame predicted centres are uploaded.
class BraggIntegrationEngineGPU : public BraggIntegrationEngine {
std::shared_ptr<CudaStream> stream;
int threads;
size_t fit_shared_bytes;
size_t capacity = 0; // per-reflection device/host arrays hold at least this many reflections
// --- per-reflection device arrays (grown by EnsureCapacity) ---
CudaDevicePtr<float> d_px_x, d_px_y, d_d;
CudaDevicePtr<int> d_cx, d_cy;
CudaDevicePtr<float> d_I, d_sigma, d_bkg, d_obs_x, d_obs_y;
CudaDevicePtr<uint8_t> d_ok, d_strong, d_has_obs;
// --- fixed-size device arrays ---
// The learning/fit math is single precision: FP64 is heavily throttled on consumer GPUs and the
// extraction is Poisson-noise limited, so float reproduces the double CPU path to ~1e-4.
CudaDevicePtr<uint8_t> d_mask; // per-pixel r2-disk reflection mask
CudaDevicePtr<float> d_shell_grid, d_global_grid; // learned profile accumulators (N_SHELL*GG, GG)
CudaDevicePtr<float> d_shell_P, d_global_P; // normalised profiles (empirical mode)
CudaDevicePtr<float> d_shell_sigma2, d_global_sigma2;
CudaDevicePtr<int> d_shell_n, d_global_n;
CudaDevicePtr<unsigned long long> d_invd2; // [min,max] inv-d^2 as monotonic bit patterns
// --- host staging (copied back once per frame) ---
std::vector<float> h_px_x, h_px_y, h_d;
std::vector<float> h_I, h_sigma, h_bkg, h_obs_x, h_obs_y;
std::vector<uint8_t> h_ok, h_has_obs;
void EnsureCapacity(size_t n);
public:
BraggIntegrationEngineGPU(const DiffractionExperiment &experiment, std::shared_ptr<CudaStream> stream);
std::vector<Reflection> Run(const ImagePreprocessorBuffer &image,
const std::vector<Reflection> &predicted, size_t npredicted,
int64_t image_number) override;
};