Jungfraujoch/viewer/windows/JFJochViewerProcessingWindow.cpp

// SPDX-FileCopyrightText: 2025 Filip Leonarski, Paul Scherrer Institute <filip.leonarski@psi.ch>
// SPDX-License-Identifier: GPL-3.0-only

#include "JFJochViewerProcessingWindow.h"

#include <QHBoxLayout>
#include <QGroupBox>
#include <QFormLayout>
#include <QButtonGroup>
#include <QRadioButton>
#include <vector>

#include "../../common/CUDAWrapper.h"   // get_gpu_count()

namespace {
    struct RadioChoice { const char *label; int value; };

    QString algorithm_name(IndexingAlgorithmEnum a) {
        switch (a) {
            case IndexingAlgorithmEnum::FFBIDX: return "FFBIDX (GPU)";
            case IndexingAlgorithmEnum::FFT:    return "FFT (GPU)";
            case IndexingAlgorithmEnum::FFTW:   return "FFTW (CPU)";
            case IndexingAlgorithmEnum::Auto:   return "Auto";
            default:                            return "None";
        }
    }

    // A titled group of mutually-exclusive radio buttons, with an optional explanatory line.
    QGroupBox *MakeRadioGroup(const QString &title, const QString &help,
                              const std::vector<RadioChoice> &choices, int current,
                              QButtonGroup *group, QWidget *parent) {
        auto *box = new QGroupBox(title, parent);
        auto *layout = new QVBoxLayout(box);
        if (!help.isEmpty()) {
            auto *label = new QLabel(help, box);
            label->setWordWrap(true);
            layout->addWidget(label);
        }
        for (const auto &c: choices) {
            auto *button = new QRadioButton(c.label, box);
            button->setChecked(c.value == current);
            group->addButton(button, c.value);
            layout->addWidget(button);
        }
        return box;
    }
}

JFJochViewerProcessingWindow::JFJochViewerProcessingWindow(const SpotFindingSettings &settings, const IndexingSettings& indexing,QWidget *parent)
        : JFJochHelperWindow(parent), m_settings(settings), m_indexing(indexing) {

    setWindowTitle("Image processing settings");

    // --- Spot finding page ---
    m_spotFindingPage = new QWidget(this);
    auto spotLayout = new QVBoxLayout(m_spotFindingPage);

    auto generalGroup = new QGroupBox("Spot finding", m_spotFindingPage);
    auto generalLayout = new QFormLayout(generalGroup);

    m_enableCheckBox = new QCheckBox("Enable", this);
    m_enableCheckBox->setChecked(m_settings.enable);
    generalLayout->addRow("", m_enableCheckBox);

    m_signalToNoise = new SliderPlusBox(1.0, 10.0, 0.1, 1, this);
    m_signalToNoise->setValue(m_settings.signal_to_noise_threshold);
    generalLayout->addRow("Signal to Noise threshold:", m_signalToNoise);

    m_photonCount = new SliderPlusBox(0.0, 100.0, 1.0, 0, this);
    m_photonCount->setValue(std::lround(m_settings.photon_count_threshold));
    generalLayout->addRow("Photon count threshold:", m_photonCount);

    m_minPixPerSpot = new SliderPlusBox(1.0, 20.0, 1.0, 0, this);
    m_minPixPerSpot->setValue(std::lround(m_settings.min_pix_per_spot));
    generalLayout->addRow("Minimum pixels per spot:", m_minPixPerSpot);

    m_maxPixPerSpot = new SliderPlusBox(10.0, 200.0, 1.0, 0, this);
    m_maxPixPerSpot->setValue(std::lround(m_settings.max_pix_per_spot));
    generalLayout->addRow("Maximum pixels per spot:", m_maxPixPerSpot);

    // New: Max spot count slider [100 .. 2000]
    m_maxSpotCount = new SliderPlusBox(100.0, 2000.0, 10.0, 0, this);
    // If there is no existing value source, initialize to a sensible default
    m_maxSpotCount->setValue(1000.0);
    generalLayout->addRow("Maximum spots per image:", m_maxSpotCount);

    m_highResolution = new SliderPlusBox(0.8, 10.0, 0.1, 1, this);
    m_highResolution->setValue(m_settings.high_resolution_limit);
    generalLayout->addRow("High resolution", m_highResolution);

    m_lowResolution = new SliderPlusBox(10.0, 100.0, 0.1, 1, this);
    m_lowResolution->setValue(m_settings.low_resolution_limit);
    generalLayout->addRow("Low resolution", m_lowResolution);

    // High-res spurious spot filter (gap in 1/d)
    m_highResSpuriousFilterCheckBox = new QCheckBox("Enable high-res spurious spot filter", this);
    const bool gapFilterEnabled = m_settings.high_res_gap_Q_recipA > 0.0f;
    m_highResSpuriousFilterCheckBox->setChecked(m_settings.high_res_gap_Q_recipA.has_value());
    generalLayout->addRow("", m_highResSpuriousFilterCheckBox);

    m_highResSpuriousGapOneOverD = new SliderPlusBox(0.1, 5.0, 0.01, 2, this);
    // If disabled by setting = 0, show a reasonable default on the slider but keep disabled
    const double initialGap = m_settings.high_res_gap_Q_recipA.value_or(0.25);
    m_highResSpuriousGapOneOverD->setValue(initialGap);
    m_highResSpuriousGapOneOverD->setEnabled(gapFilterEnabled);
    generalLayout->addRow("Gap threshold in Q-space [A^-1]:", m_highResSpuriousGapOneOverD);

    m_iceRingWidthQRecipA = new SliderPlusBox(0.0, 0.3, 0.001, 3, this);
    m_iceRingWidthQRecipA->setValue(m_settings.ice_ring_width_Q_recipA);
    generalLayout->addRow("Ice ring width in Q-space [A^-1]:", m_iceRingWidthQRecipA);

    auto processingGroup = new QGroupBox("Other steps", m_spotFindingPage);
    auto processingLayout = new QFormLayout(processingGroup);

    m_quickIntegrationCheckBox = new QCheckBox("Enable Bragg Integration", this);
    m_quickIntegrationCheckBox->setChecked(m_settings.quick_integration);
    processingLayout->addRow("", m_quickIntegrationCheckBox);

    spotLayout->addWidget(generalGroup);
    spotLayout->addWidget(processingGroup);
    spotLayout->addStretch();

    // --- Indexing page ---
    m_indexingPage = new QWidget(this);
    auto indexLayout = new QVBoxLayout(m_indexingPage);

    m_indexingCheckBox = new QCheckBox("Enable Indexing", this);
    m_indexingCheckBox->setChecked(m_settings.indexing);
    indexLayout->addWidget(m_indexingCheckBox);

    m_indexAlgGroup = new QButtonGroup(this);
    indexLayout->addWidget(MakeRadioGroup(
        "Indexing algorithm",
        "FFBIDX is fast but needs a known cell; FFT/FFTW index de-novo (FFT on GPU, FFTW on CPU). "
        "Auto picks the best available.",
        {{"Auto", static_cast<int>(IndexingAlgorithmEnum::Auto)},
         {"FFBIDX — GPU, needs known cell", static_cast<int>(IndexingAlgorithmEnum::FFBIDX)},
         {"FFT — GPU, de-novo", static_cast<int>(IndexingAlgorithmEnum::FFT)},
         {"FFTW — CPU, de-novo", static_cast<int>(IndexingAlgorithmEnum::FFTW)},
         {"None — skip indexing", static_cast<int>(IndexingAlgorithmEnum::None)}},
        static_cast<int>(m_indexing.GetAlgorithm()), m_indexAlgGroup, m_indexingPage));

#ifndef JFJOCH_USE_CUDA
    // The GPU indexers are not built without CUDA - only FFTW (CPU) is available.
    for (int id: {static_cast<int>(IndexingAlgorithmEnum::FFBIDX), static_cast<int>(IndexingAlgorithmEnum::FFT)}) {
        if (auto *button = m_indexAlgGroup->button(id)) {
            button->setEnabled(false);
            button->setToolTip("Requires a CUDA build");
        }
    }
#endif

    m_resolvedAlgLabel = new QLabel(m_indexingPage);
    indexLayout->addWidget(m_resolvedAlgLabel);

    m_geomRefGroup = new QButtonGroup(this);
    indexLayout->addWidget(MakeRadioGroup(
        "Geometry refinement",
        "How the geometry is refined once a lattice is found.",
        {{"None", static_cast<int>(GeomRefinementAlgorithmEnum::None)},
         {"Orientation only", static_cast<int>(GeomRefinementAlgorithmEnum::OrientationOnly)},
         {"Beam center + lattice", static_cast<int>(GeomRefinementAlgorithmEnum::BeamCenter)},
         {"Pixel refinement (experimental)", static_cast<int>(GeomRefinementAlgorithmEnum::PixelRefine)}},
        static_cast<int>(m_indexing.GetGeomRefinementAlgorithm()), m_geomRefGroup, m_indexingPage));

    auto indexingGroup = new QGroupBox("Indexing parameters", m_indexingPage);
    auto indexingLayout = new QFormLayout(indexingGroup);

    m_idxIndexIceRings = new QCheckBox("Index ice rings", this);
    m_idxIndexIceRings->setChecked(m_indexing.GetIndexIceRings());
    indexingLayout->addRow("", m_idxIndexIceRings);

    m_idxTolerance = new SliderPlusBox(0.0, 0.5, 0.001, 3, this);
    m_idxTolerance->setValue(m_indexing.GetTolerance());
    indexingLayout->addRow("Indexing tolerance", m_idxTolerance);

    m_idxUnitCellDistTolerance = new SliderPlusBox(0.001, 0.200, 0.001, 3, this);
    m_idxUnitCellDistTolerance->setValue(m_indexing.GetUnitCellDistTolerance());
    indexingLayout->addRow("Unit cell dist tol vs ref", m_idxUnitCellDistTolerance);

    m_idxViableCellMinSpots = new SliderPlusBox(6.0, 200.0, 1.0, 0, this);
    m_idxViableCellMinSpots->setValue(static_cast<double>(m_indexing.GetViableCellMinSpots()));
    indexingLayout->addRow("Viable cell min spots", m_idxViableCellMinSpots);

    indexLayout->addWidget(indexingGroup);
    indexLayout->addStretch();

    // --- Connections ---
    connect(m_enableCheckBox, &QCheckBox::toggled, [this](bool checked) {
        m_settings.enable = checked;
        Update();
    });

    connect(m_signalToNoise, &SliderPlusBox::valueChanged, [this](double val) {
        m_settings.signal_to_noise_threshold = val;
        Update();
    });

    connect(m_photonCount, &SliderPlusBox::valueChanged, [this](double val) {
        m_settings.photon_count_threshold = val;
        Update();
    });

    connect(m_minPixPerSpot, &SliderPlusBox::valueChanged, [this](double val) {
        m_settings.min_pix_per_spot = std::lround(val);
        Update();
    });

    connect(m_maxPixPerSpot, &SliderPlusBox::valueChanged, [this](double val) {
        m_settings.max_pix_per_spot = std::lround(val);
        Update();
    });

    // New: update on max spot count change
    connect(m_maxSpotCount, &SliderPlusBox::valueChanged, [this](double /*val*/) {
        Update();
    });

    connect(m_highResolution, &SliderPlusBox::valueChanged, [this](double val) {
        m_settings.high_resolution_limit = val;
        Update();
    });

    connect(m_lowResolution, &SliderPlusBox::valueChanged, [this](double val) {
        m_settings.low_resolution_limit = val;
        Update();
    });

    // Toggle for high-res spurious spot filter
    connect(m_highResSpuriousFilterCheckBox, &QCheckBox::toggled, [this](bool checked) {
        m_highResSpuriousGapOneOverD->setEnabled(checked);
        if (checked) {
            // If currently disabled (zero), restore a sensible default
            if (m_settings.high_res_gap_Q_recipA) {
                m_settings.high_res_gap_Q_recipA = static_cast<float>(
                    m_highResSpuriousGapOneOverD->value());
            }
        } else
            m_settings.high_res_gap_Q_recipA = std::nullopt;

        Update();
    });

    // Gap slider handler
    connect(m_highResSpuriousGapOneOverD, &SliderPlusBox::valueChanged, [this](double val) {
        m_settings.high_res_gap_Q_recipA = static_cast<float>(val);
        if (val > 0.0 && !m_highResSpuriousFilterCheckBox->isChecked()) {
            m_highResSpuriousFilterCheckBox->setChecked(true);
        }
        Update();
    });

    // Indexing enable in its own group now
    connect(m_indexingCheckBox, &QCheckBox::toggled, [this](bool checked) {
        m_settings.indexing = checked;
        Update();
    });

    connect(m_quickIntegrationCheckBox, &QCheckBox::toggled, [this](bool checked) {
        m_settings.quick_integration = checked;
        Update();
    });

    connect(m_indexAlgGroup, &QButtonGroup::idClicked, [this](int id) {
        m_indexing.Algorithm(static_cast<IndexingAlgorithmEnum>(id));
        UpdateResolvedAlgorithmLabel();
        Update();
    });

    connect(m_geomRefGroup, &QButtonGroup::idClicked, [this](int id) {
        m_indexing.GeomRefinementAlgorithm(static_cast<GeomRefinementAlgorithmEnum>(id));
        Update();
    });

    // Indexing settings signals
    connect(m_idxTolerance, &SliderPlusBox::valueChanged, [this](double val) {
        m_indexing.Tolerance(static_cast<float>(val));
        Update();
    });

    connect(m_idxUnitCellDistTolerance, &SliderPlusBox::valueChanged, [this](double val) {
        m_indexing.UnitCellDistTolerance(static_cast<float>(val));
        Update();
    });

    connect(m_idxIndexIceRings, &QCheckBox::toggled, [this](bool checked) {
        m_indexing.IndexIceRings(checked);
        Update();
    });

    connect(m_idxViableCellMinSpots, &SliderPlusBox::valueChanged, [this](double val) {
        m_indexing.ViableCellMinSpots(static_cast<int64_t>(std::lround(val)));
        Update();
    });

    connect(m_iceRingWidthQRecipA, &SliderPlusBox::valueChanged, [this](double val) {
        m_settings.ice_ring_width_Q_recipA = static_cast<float>(val);
        Update();
    });

    UpdateResolvedAlgorithmLabel();
}

void JFJochViewerProcessingWindow::Update() {
    const auto max_spots = std::lround(m_maxSpotCount->value());
    emit settingsChanged(m_settings, m_indexing, max_spots);
}

void JFJochViewerProcessingWindow::setUnitCellKnown(bool known) {
    m_unitCellKnown = known;
    UpdateResolvedAlgorithmLabel();
}

void JFJochViewerProcessingWindow::UpdateResolvedAlgorithmLabel() {
    // Mirror DiffractionExperiment::GetIndexingAlgorithm() so the user sees what Auto/FFBIDX
    // actually resolve to on this machine (GPU present?) and dataset (unit cell known?).
    const bool gpu = get_gpu_count() > 0;
    IndexingAlgorithmEnum resolved;
    switch (m_indexing.GetAlgorithm()) {
        case IndexingAlgorithmEnum::FFBIDX:
            resolved = m_unitCellKnown ? IndexingAlgorithmEnum::FFBIDX : IndexingAlgorithmEnum::None;
            break;
        case IndexingAlgorithmEnum::Auto:
            resolved = !gpu ? IndexingAlgorithmEnum::FFTW
                            : (m_unitCellKnown ? IndexingAlgorithmEnum::FFBIDX : IndexingAlgorithmEnum::FFT);
            break;
        case IndexingAlgorithmEnum::FFT:  resolved = IndexingAlgorithmEnum::FFT;  break;
        case IndexingAlgorithmEnum::FFTW: resolved = IndexingAlgorithmEnum::FFTW; break;
        default:                          resolved = IndexingAlgorithmEnum::None; break;
    }
    m_resolvedAlgLabel->setText("Effective on this system: " + algorithm_name(resolved)
                                + (gpu ? "" : "  (no GPU detected)"));
}