path: root/core/client.cpp

// [SECTION] Includes
// [SECTION] Defines
// [SECTION] Status enum
// [SECTION] String comparator declaration
// [SECTION] Trace declarations
// [SECTION] Plot declarations
// [SECTION] Plots
// [SECTION] Heatmap colormap
// [SECTION] Global variables
// [SECTION] String comparator definition
// [SECTION] Trace (base) definition
// [SECTION] TraceNamed definition
// [SECTION] TraceHeatmap definition
// [SECTION] Plot (base) definition
// [SECTION] PlotLines definition
// [SECTION] PlotStacked definition
// [SECTION] PlotHeatmap definition
// [SECTION] Data functions
// [SECTION] GUI functions
// [SECTION] Main functions

// ----------------------------------------------------------------------------
// [SECTION] Includes
// ----------------------------------------------------------------------------
#include <arpa/inet.h>
#include <GL/glu.h>
#include <GLFW/glfw3.h>
#include <imgui_impl_glfw.h>
#include <imgui_impl_opengl3.h>
#include <implot.h>
#include <implot_internal.h>
#include <json-c/json.h>
#include <signal.h>
#include <threads.h>

#include <algorithm>
#include <array>
#include <map>
#include <vector>

#include "logger.c"

// ----------------------------------------------------------------------------
// [SECTION] Defines
// ----------------------------------------------------------------------------
#define COLOR_BLACK ImVec4(0.f, 0.f, 0.f, 1.f)
#define FONT_SIZE 12.f
#define FONT_SOURCE "/usr/share/fonts/droid/DroidSansMono.ttf"
#define GLSL_VERSION "#version 130"
#define PLOT_MIN_COLS 1
#define PLOT_MAX_COLS 8
#define PLOT_MIN_HEIGHT 100.f
#define PLOT_MAX_HEIGHT 800.f
#define PLOT_HEIGHT_INTERVAL 50.f
#define PLOT_SCROLL_MARGIN 28.f
#define HM_SCALE_POW_MIN -1.f
#define HM_SCALE_POW_MAX 64.f
#define HM_SCALE_POW_INTERVAL 1.f
#define HM_COLORSCALE_WIDTH 80.f

#define IMGUI_WINDOW_FLAGS ( \
    ImGuiWindowFlags_NoBackground | \
    ImGuiWindowFlags_NoDecoration | \
    ImGuiWindowFlags_NoMove | \
    ImGuiWindowFlags_NoSavedSettings \
)

#define DATA_FETCH_INTERVAL 10
#define DATA_FETCH_INTERVAL_SUBDIV 1000

#define DEFVAL_ENTRIES 0x800l
#define DEFVAL_NTH 1l
#define DEFVAL_X_AXIS 0
#define DEFVAL_X_LOW 0l
#define DEFVAL_X_HIGH INT64_MAX
#define DEFVAL_HM_LEFT 0l
#define DEFVAL_HM_PIXEL_COUNT 0x400l // must equal HM_PIXEL_COUNT in server.c

// ----------------------------------------------------------------------------
// [SECTION] Status enum
// ----------------------------------------------------------------------------
enum Status {
    STATUS_STOPPED,
    STATUS_RUNNING,
    STATUS_FETCHING,
    STATUS_STOPPING,
};

// ----------------------------------------------------------------------------
// [SECTION] String comparator declaration
// ----------------------------------------------------------------------------
struct StringComparator {
    bool operator()(const char *a, const char *b) const;
};

// ----------------------------------------------------------------------------
// [SECTION] Trace declarations
// ----------------------------------------------------------------------------
template <class T>
struct Trace : public std::vector<T> {
    Trace();
    virtual ~Trace();
    virtual size_t start_offset() const;
    virtual void trim();
#if !defined(NDEBUG)
    virtual void validate() const;
#endif
    void clear();
    void push_back(T value);
    T *start();
    T &operator[](size_t n);
    T operator[](size_t n) const;
protected:
    void trim_spec(int64_t multiplier = 1);
};

template <class T>
struct TraceNamed : public Trace<T> {
    TraceNamed(const char *name, const char *label);
    const char *get_name() const;
    const char *get_label() const;
private:
    const char *m_name;
    const char *m_label;
};

template <class T>
struct TraceHeatmap : public TraceNamed<T> {
    TraceHeatmap(const char *name, const char *label);
    size_t start_offset() const;
    void trim();
#if !defined(NDEBUG)
    void validate() const;
#endif
};

// ----------------------------------------------------------------------------
// [SECTION] Plot declarations
// ----------------------------------------------------------------------------
typedef int (*AxisFormatter)(double value, char *buff, int size, void *data);

struct Plot {
    Plot(const char *name, const char *section);
    virtual ~Plot();
    virtual void handle_input(int key, int mods);
    virtual void flag_for_reset();
    const char *get_name() const;
    const char *get_section() const;
    void render(const ImVec2 &frame_size);
    bool m_visible;
private:
    static int hex_formatter(double value, char *buff, int size, void *data);
    virtual AxisFormatter x_formatter() const;
    virtual AxisFormatter y_formatter() const;
    virtual float right_margin() const;
    virtual int flags() const;
    virtual void render_internal(const ImVec2 &frame_size) = 0;
    virtual void render_post(const ImVec2 &frame_size);
    const char *m_name;
    const char *m_section;
};

struct PlotLines : public Plot {
    PlotLines(const char *name, const char *section, std::vector<const char *> trace_keys);
private:
    void render_internal(const ImVec2 &frame_size);
    std::vector<const char *> m_trace_keys;
};

struct PlotStacked : public Plot {
    PlotStacked(const char *name, const char *section, std::vector<const char *> trace_keys);
    void flag_for_reset();
private:
    static int percent_formatter(double value, char *buff, int size, void *data);
    AxisFormatter y_formatter() const;
    void render_internal(const ImVec2 &frame_size);
    std::vector<const char *> m_trace_keys;
    std::vector<bool> m_trace_states;
    Trace<ImS64> m_trace_totals;
    std::vector<Trace<double>> m_trace_normals;
    bool m_needs_reset;
};

struct PlotHeatmap : public Plot {
    PlotHeatmap(const char *name, const char *section, const char *trace_key);
    void handle_input(int key, int mods);
    void flag_for_reset();
private:
    float right_margin() const;
    int flags() const;
    void render_internal(const ImVec2 &frame_size);
    void render_end(const ImVec2 &frame_size);
    void render_post(const ImVec2 &frame_size);
    const char *m_trace_key;
    float m_tex_scale_pow;
    float m_tex_scale_high;
    size_t m_tex_rendered_last;
    size_t m_rows_rendered;
    GLuint m_tex_id;
    std::vector<uint8_t> m_tex_render;
    bool m_needs_reset;
};

// ----------------------------------------------------------------------------
// [SECTION] Plots
// ----------------------------------------------------------------------------
#include "arch_plots.cpp"

std::array g_core_traces = std::to_array<TraceNamed<ImS64>>({
    {"rowid", "rowid"},
    {"step", "step"},
#define FOR_CORE(i) \
    {"cycl_" #i, "cycl_" #i}, \
    {"mall_" #i, "mall_" #i}, \
    {"pnum_" #i, "pnum_" #i}, \
    {"pfst_" #i, "pfst_" #i}, \
    {"plst_" #i, "plst_" #i}, \
    {"amb0_" #i, "amb0_" #i}, \
    {"amb1_" #i, "amb1_" #i}, \
    {"emb0_" #i, "emb0_" #i}, \
    {"emb1_" #i, "emb1_" #i}, \
    {"eliv_" #i, "eliv_" #i}, \
    {"edea_" #i, "edea_" #i},
    FOR_CORES
#undef FOR_CORE
});

std::array g_core_traces_heatmaps = std::to_array<TraceHeatmap<ImS64>>({
#define FOR_CORE(i) \
    {"aev_" #i, "aev_" #i}, \
    {"eev_" #i, "eev_" #i}, \
    {"bev_" #i, "bev_" #i},
    FOR_CORES
#undef FOR_CORE
});

std::array g_core_plots = std::to_array<PlotLines>({
    {"cycl", "general", {
#define FOR_CORE(i) "cycl_" #i,
        FOR_CORES
#undef FOR_CORE
    }},
    {"mall", "general", {
#define FOR_CORE(i) "mall_" #i,
        FOR_CORES
#undef FOR_CORE
    }},
    {"pnum", "general", {
#define FOR_CORE(i) "pnum_" #i,
        FOR_CORES
#undef FOR_CORE
    }},
    {"ppop", "general", {
#define FOR_CORE(i) "pfst_" #i, "plst_" #i,
        FOR_CORES
#undef FOR_CORE
    }},
    {"ambs", "general", {
#define FOR_CORE(i) "amb0_" #i, "amb1_" #i,
        FOR_CORES
#undef FOR_CORE
    }},
    {"eevs", "general", {
#define FOR_CORE(i) "emb0_" #i, "emb1_" #i, "eliv_" #i, "edea_" #i,
        FOR_CORES
#undef FOR_CORE
    }},
});

std::array g_core_plots_heatmaps = std::to_array<PlotHeatmap>({
#define FOR_CORE(i) \
    {"aev_" #i, "heatmaps", "aev_" #i},
    FOR_CORES
#undef FOR_CORE
#define FOR_CORE(i) \
    {"eev_" #i, "heatmaps", "eev_" #i},
    FOR_CORES
#undef FOR_CORE
#define FOR_CORE(i) \
    {"bev_" #i, "heatmaps", "bev_" #i},
    FOR_CORES
#undef FOR_CORE
});

// ----------------------------------------------------------------------------
// [SECTION] Heatmap colormap
// ----------------------------------------------------------------------------
std::array g_hm_colormap = std::to_array<ImVec4>({
    {0.000f, 0.000f, 0.016f, 1.f},
    {0.106f, 0.047f, 0.255f, 1.f},
    {0.290f, 0.047f, 0.420f, 1.f},
    {0.471f, 0.110f, 0.427f, 1.f},
    {0.647f, 0.173f, 0.376f, 1.f},
    {0.812f, 0.267f, 0.275f, 1.f},
    {0.929f, 0.412f, 0.145f, 1.f},
    {0.984f, 0.608f, 0.024f, 1.f},
    {0.969f, 0.820f, 0.239f, 1.f},
    {0.988f, 1.000f, 0.643f, 1.f},
});

// ----------------------------------------------------------------------------
// [SECTION] Global variables
// ----------------------------------------------------------------------------
GLFWwindow *g_window;
ImGuiIO *g_imgui_io;
ImGuiStyle *g_imgui_style;
ImPlotStyle *g_implot_style;

std::array g_x_axes = std::to_array<const char *>({
    "rowid",
    "step",
#define FOR_CORE(i) "cycl_" #i,
    FOR_CORES
#undef FOR_CORE
});

int g_status;
int g_x_axis = DEFVAL_X_AXIS;
int64_t g_entries = DEFVAL_ENTRIES;
int64_t g_nth = DEFVAL_NTH;
int64_t g_x_low = DEFVAL_X_LOW;
int64_t g_x_high = DEFVAL_X_HIGH;
int64_t g_hm_left = DEFVAL_HM_LEFT;
int64_t g_hm_pixel_count = DEFVAL_HM_PIXEL_COUNT;
int64_t g_hm_pixel_pow; // calculate on init
int64_t g_x_current = -1l;
int64_t g_trace_len;
int64_t g_trace_offset;

thrd_t g_fetching_thread;
mtx_t g_fetching_mutex;

bool g_data_col_visible = true;
bool g_plot_maximized;
bool g_plot_scroll;
float g_plot_scroll_current;
float g_plot_scroll_to;
float g_data_col_width;
std::vector<Plot *> g_plot_cells;
std::vector<float> g_plot_cells_top;
std::vector<float> g_plot_cells_bottom;
std::vector<bool> g_plots_covered;
Plot *g_plot_selected;
Plot *g_plot_hovered;
int g_plot_stride;
int g_downsampled_trace_len;
int g_plot_cols = 2;
size_t g_plot_col_selected;
size_t g_plot_row_selected;
float g_plot_height = 300.f;
ImPlotColormap g_hm_colormap_id;

std::map<const char *, TraceNamed<ImS64> *, StringComparator> g_trace_map;
std::vector<TraceNamed<ImS64> *> g_traces;
std::vector<Plot *> g_plots;
Trace<double> g_x_axis_double;
Trace<double> g_zero_trace;

PFNGLCOPYIMAGESUBDATAPROC glCopyImageSubData;

// ----------------------------------------------------------------------------
// [SECTION] String comparator definition
// ----------------------------------------------------------------------------
bool StringComparator::operator()(const char *a, const char *b) const {
    return strcmp(a, b) < 0;
}

// ----------------------------------------------------------------------------
// [SECTION] Trace (base) definition
// ----------------------------------------------------------------------------
template <class T>
Trace<T>::Trace() : std::vector<T>() {}

template <class T>
Trace<T>::~Trace() {}

template <class T>
size_t Trace<T>::start_offset() const {
    return (size_t)g_trace_offset;
}

template <class T>
void Trace<T>::trim() {
    trim_spec();
}

#if !defined(NDEBUG)
template <class T>
void Trace<T>::validate() const {
    assert(this->size() == g_traces[0]->size());
}
#endif

template <class T>
void Trace<T>::clear() {
    std::vector<T>::clear();
}

template <class T>
void Trace<T>::push_back(T value) {
    std::vector<T>::push_back(value);
}

template <class T>
T *Trace<T>::start() {
    return this->size() ? &operator[](start_offset()) : nullptr;
}

template <class T>
T &Trace<T>::operator[](size_t n) {
#if !defined(NDEBUG)
    return this->at(n);
#else
    return std::vector<T>::operator[](n);
#endif
}

template <class T>
T Trace<T>::operator[](size_t n) const {
#if !defined(NDEBUG)
    return this->at(n);
#else
    return std::vector<T>::operator[](n);
#endif
}

template <class T>
void Trace<T>::trim_spec(int64_t multiplier) {
    assert((int64_t)this->size() >= g_entries * multiplier * 2);
    this->erase(this->begin(), this->end() - (g_entries * multiplier));
}

// ----------------------------------------------------------------------------
// [SECTION] TraceNamed definition
// ----------------------------------------------------------------------------
template <class T>
TraceNamed<T>::TraceNamed(const char *name, const char *label) : m_name(name), m_label(label) {}

template <class T>
const char *TraceNamed<T>::get_name() const {
    return m_name;
}

template <class T>
const char *TraceNamed<T>::get_label() const {
    return m_label;
}

// ----------------------------------------------------------------------------
// [SECTION] TraceHeatmap definition
// ----------------------------------------------------------------------------
template <class T>
TraceHeatmap<T>::TraceHeatmap(const char *name, const char *name_fmt) : TraceNamed<T>(name, name_fmt) {}

template <class T>
size_t TraceHeatmap<T>::start_offset() const {
    return (size_t)(g_trace_offset * g_hm_pixel_count);
}

template <class T>
void TraceHeatmap<T>::trim() {
    Trace<T>::trim_spec(g_hm_pixel_count);
}

#if !defined(NDEBUG)
template <class T>
void TraceHeatmap<T>::validate() const {
    assert(this->size() == g_traces[0]->size() * g_hm_pixel_count);
}
#endif

// ----------------------------------------------------------------------------
// [SECTION] Plot (base) definition
// ----------------------------------------------------------------------------
Plot::Plot(const char *name, const char *section) : m_visible(true), m_name(name), m_section(section) {}

Plot::~Plot() {}

void Plot::handle_input(int key, int mods) {
    (void)key;
    (void)mods;
}

void Plot::flag_for_reset() {}

const char *Plot::get_name() const {
    return m_name;
}

const char *Plot::get_section() const {
    return m_section;
}

void Plot::render(const ImVec2 &frame_size) {
    if (ImPlot::BeginPlot(m_name, ImVec2(frame_size.x - right_margin(), frame_size.y), flags())) {
        int axis_flags = ImPlotAxisFlags_Foreground | (g_status != STATUS_STOPPED ? ImPlotAxisFlags_AutoFit : 0);
        ImPlot::SetupAxes(nullptr, nullptr, axis_flags, axis_flags);
        ImPlot::SetupAxisFormat(ImAxis_X1, x_formatter());
        ImPlot::SetupAxisFormat(ImAxis_Y1, y_formatter());
        if (ImPlot::IsPlotHovered()) g_plot_hovered = this;
        render_internal(frame_size);
        ImPlot::EndPlot();
    }

    render_post(frame_size);
}

int Plot::hex_formatter(double value, char *buff, int size, void *data) {
    (void)data;
    snprintf(buff, size, "%s%#lx", value < 0. ? "-" : "", abs((int64_t)value));
    return 0;
}

AxisFormatter Plot::x_formatter() const {
    return Plot::hex_formatter;
}

AxisFormatter Plot::y_formatter() const {
    return Plot::hex_formatter;
}

float Plot::right_margin() const {
    return 0.f;
}

int Plot::flags() const {
    return 0;
}

void Plot::render_post(const ImVec2 &frame_size) {
    (void)frame_size;
}

// ----------------------------------------------------------------------------
// [SECTION] PlotLines definition
// ----------------------------------------------------------------------------
PlotLines::PlotLines(const char *name, const char *section, std::vector<const char *> trace_keys) : Plot(name, section), m_trace_keys(trace_keys) {}

void PlotLines::render_internal(const ImVec2 &frame_size) {
    (void)frame_size;

    ImS64 *x = g_trace_map[g_x_axes[g_x_axis]]->start();
    ImPlotSpec spec = ImPlotSpec(ImPlotProp_Stride, sizeof(ImS64) * g_plot_stride);

    for (auto &trace : m_trace_keys) {
        TraceNamed<ImS64> *trace_obj = g_trace_map[trace];
        ImS64 *y = trace_obj->start();
        ImPlot::PlotLine(trace_obj->get_label(), x, y, g_downsampled_trace_len, spec);
    }
}

// ----------------------------------------------------------------------------
// [SECTION] PlotStacked definition
// ----------------------------------------------------------------------------
PlotStacked::PlotStacked(const char *name, const char *section, std::vector<const char *> trace_keys) : Plot(name, section), m_trace_keys(trace_keys), m_trace_states(trace_keys.size(), true), m_trace_totals(), m_trace_normals(trace_keys.size()), m_needs_reset(true) {}

void PlotStacked::flag_for_reset() {
    m_needs_reset = true;
}

int PlotStacked::percent_formatter(double value, char *buff, int size, void *data) {
    (void)data;
    snprintf(buff, size, "%3.0f%%", value * 100.);
    return 0;
}

AxisFormatter PlotStacked::y_formatter() const {
    return PlotStacked::percent_formatter;
}

void PlotStacked::render_internal(const ImVec2 &frame_size) {
    (void)frame_size;

    for (size_t i = 0; i < m_trace_keys.size(); i++) {
        ImPlot::PlotDummy(g_trace_map[m_trace_keys[i]]->get_label());
    }

    for (size_t i = 0; i < m_trace_keys.size(); i++) {
        bool trace_visible = GImPlot->CurrentPlot->Items.GetLegendItem(i)->Show;

        if (m_trace_states[i] != trace_visible) {
            m_trace_states[i] = trace_visible;
            m_needs_reset = true;
        }
    }

    if (m_needs_reset) {
        m_trace_totals.clear();
        for (auto &trace_normal : m_trace_normals) trace_normal.clear();
        m_needs_reset = false;
    }

    size_t trace_size = m_trace_totals.size();

    for (size_t i = trace_size; i < g_traces[0]->size(); i++) {
        m_trace_totals.push_back(0l);

        for (size_t j = 0; j < m_trace_keys.size(); j++) {
            if (GImPlot->CurrentPlot->Items.GetLegendItem(j)->Show) {
                m_trace_totals.back() += g_trace_map[m_trace_keys[j]]->operator[](i);
            }
        }
    }

    for (size_t i = trace_size; i < g_traces[0]->size(); i++) {
        if (m_trace_totals[i]) {
            double normal = 0.;

            for (size_t j = 0; j < m_trace_keys.size(); j++) {
                if (GImPlot->CurrentPlot->Items.GetLegendItem(j)->Show) {
                    normal += (double)g_trace_map[m_trace_keys[j]]->operator[](i) / (double)m_trace_totals[i];
                    m_trace_normals[j].push_back(normal);
                }
            }
        } else {
            for (size_t j = 0; j < m_trace_keys.size(); j++) {
                if (GImPlot->CurrentPlot->Items.GetLegendItem(j)->Show) {
                    m_trace_normals[j].push_back(0.);
                }
            }
        }
    }

#if !defined(NDEBUG)
    m_trace_totals.validate();

    for (size_t i = 0; i < m_trace_keys.size(); i++) {
        if (GImPlot->CurrentPlot->Items.GetLegendItem(i)->Show) {
            m_trace_normals[i].validate();
        } else {
            assert(m_trace_normals[i].empty());
        }
    }
#endif

    Trace<double> *prev_trace = &g_zero_trace;

    for (size_t i = 0; i < m_trace_keys.size(); i++) {
        assert(m_trace_states[i] == GImPlot->CurrentPlot->Items.GetLegendItem(i)->Show);

        if (m_trace_states[i]) {
            bool hovered = GImPlot->CurrentPlot->Items.GetLegendItem(i)->LegendHovered;
            ImPlotSpec spec = ImPlotSpec(ImPlotProp_FillAlpha, hovered ? 1.f : 0.9f, ImPlotProp_Stride, sizeof(double) * g_plot_stride);
            const char *trace_name = g_trace_map[m_trace_keys[i]]->get_label();
            Trace<double> *current_trace = &m_trace_normals[i];
            ImPlot::PlotShaded(trace_name, g_x_axis_double.start(), prev_trace->start(), current_trace->start(), g_downsampled_trace_len, spec);
            ImPlot::PlotLine(trace_name, g_x_axis_double.start(), prev_trace->start(), g_downsampled_trace_len, spec);
            if (hovered) ImPlot::PlotLine(trace_name, g_x_axis_double.start(), current_trace->start(), g_downsampled_trace_len, spec);
            prev_trace = current_trace;
        }
    }
}

// ----------------------------------------------------------------------------
// [SECTION] PlotHeatmap definition
// ----------------------------------------------------------------------------
PlotHeatmap::PlotHeatmap(const char *name, const char *section, const char *trace_key) : Plot(name, section), m_trace_key(trace_key), m_tex_scale_pow(-1.f), m_tex_scale_high(0.f), m_tex_rendered_last(0), m_rows_rendered(0), m_tex_id(0), m_tex_render(), m_needs_reset(true) {}

void PlotHeatmap::handle_input(int key, int mods) {
    switch (mods) {
    case GLFW_MOD_CONTROL:
        switch (key) {
        case GLFW_KEY_K:
            m_tex_scale_pow = std::clamp(m_tex_scale_pow - 1, HM_SCALE_POW_MIN, HM_SCALE_POW_MAX);
            m_needs_reset = true;
            break;
        case GLFW_KEY_L:
            m_tex_scale_pow = std::clamp(m_tex_scale_pow + 1, HM_SCALE_POW_MIN, HM_SCALE_POW_MAX);
            m_needs_reset = true;
            break;
        }
    }
}

void PlotHeatmap::flag_for_reset() {
    m_needs_reset = true;
}

float PlotHeatmap::right_margin() const {
    return HM_COLORSCALE_WIDTH;
}

int PlotHeatmap::flags() const {
    return ImPlotFlags_NoLegend;
}

void PlotHeatmap::render_internal(const ImVec2 &frame_size) {
    Trace<ImS64> *trace = g_trace_map[m_trace_key];

    if (m_needs_reset) {
        m_tex_scale_high = 0.f;
        m_tex_rendered_last = trace->start_offset();
        m_rows_rendered = 0;
        glDeleteTextures(1, &m_tex_id);
        m_tex_id = 0;
        m_needs_reset = false;
    }

    if (m_tex_rendered_last == trace->size()) {
        render_end(frame_size);
        return;
    }

    assert(m_tex_render.empty());
    assert((trace->size() - m_tex_rendered_last) % g_hm_pixel_count == 0);
    size_t rows_to_append = (trace->size() - m_tex_rendered_last) / (size_t)g_hm_pixel_count;
    size_t rows_to_chop_off = (m_rows_rendered + rows_to_append) > (size_t)g_trace_len ? (m_rows_rendered + rows_to_append) - (size_t)g_trace_len : 0;

    if (rows_to_chop_off > m_rows_rendered) {
        m_needs_reset = true;
        render_internal(frame_size);
        return;
    }

    if (m_tex_scale_pow == HM_SCALE_POW_MIN) {
        ImS64 max = 0;

        for (size_t i = trace->start_offset(); i < trace->size(); i++) {
            max = std::max(max, trace->operator[](i));
        }

        m_tex_scale_high = (float)max;
    } else {
        m_tex_scale_high = pow(2.f, m_tex_scale_pow);
    }

    m_tex_render.reserve((trace->size() - m_tex_rendered_last) * 3);

    if (m_tex_scale_high != 0.f) {
        for (size_t i = m_tex_rendered_last; i < trace->size(); i++) {
            ImS64 value = trace->operator[](i);
            float normal = std::min((float)value / m_tex_scale_high, 1.f);
            assert(normal >= 0.f && normal <= 1.f);
            ImVec4 color = ImPlot::SampleColormap(normal, g_hm_colormap_id);
            m_tex_render.push_back((uint8_t)(color.x * 255.f)); // red
            m_tex_render.push_back((uint8_t)(color.y * 255.f)); // green
            m_tex_render.push_back((uint8_t)(color.z * 255.f)); // blue
        }
    } else {
        for (size_t i = m_tex_rendered_last; i < trace->size(); i++) {
            m_tex_render.push_back(0);
            m_tex_render.push_back(0);
            m_tex_render.push_back(0);
        }
    }

    GLuint new_tex_id;
    glGenTextures(1, &new_tex_id);
    glBindTexture(GL_TEXTURE_2D, new_tex_id);
    glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
    glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
    glPixelStorei(GL_UNPACK_ROW_LENGTH, 0);
    glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB8, g_hm_pixel_count, g_trace_len, 0, GL_RGB, GL_UNSIGNED_BYTE, nullptr);
    assert(glGetError() == GL_NO_ERROR);
    assert(new_tex_id);

    if (m_tex_id) {
        glCopyImageSubData(
            m_tex_id, GL_TEXTURE_2D, 0, 0, rows_to_chop_off, 0,
            new_tex_id, GL_TEXTURE_2D, 0, 0, 0, 0,
            g_hm_pixel_count, m_rows_rendered - rows_to_chop_off, 1
        );
        assert(glGetError() == GL_NO_ERROR);
        glDeleteTextures(1, &m_tex_id);
    }

    glTexSubImage2D(GL_TEXTURE_2D, 0, 0, m_rows_rendered - rows_to_chop_off, g_hm_pixel_count, rows_to_append, GL_RGB, GL_UNSIGNED_BYTE, m_tex_render.data());
    assert(glGetError() == GL_NO_ERROR);

    render_end(frame_size);

    m_tex_rendered_last = trace->size();
    m_rows_rendered += rows_to_append - rows_to_chop_off;
    assert(m_rows_rendered <= (size_t)g_trace_len);
    m_tex_id = new_tex_id;
    m_tex_render.clear();
}

void PlotHeatmap::render_end(const ImVec2 &frame_size) {
    if (g_x_axis_double.empty()) return;

    ImVec2 bmin(g_hm_left, (float)*g_x_axis_double.start());
    ImVec2 bmax(g_hm_left + g_hm_pixel_count * pow(2.f, g_hm_pixel_pow), (float)g_x_axis_double.back());
    ImVec2 uv0(0.f, 1.f);
    ImVec2 uv1(1.f, 0.f);
    double scale_max = m_tex_scale_pow == HM_SCALE_POW_MIN ? (double)m_tex_scale_high : pow(2., (double)m_tex_scale_pow);

    ImPlot::PlotImage(get_name(), (ImTextureID)m_tex_id, bmin, bmax, uv0, uv1);
    ImGui::SameLine();

    ImPlot::PushColormap(g_hm_colormap_id);
    ImPlot::ColormapScale("##hm-scale", 0., scale_max, ImVec2(HM_COLORSCALE_WIDTH, frame_size.y), "%.1e");
    ImPlot::PopColormap();
}

void PlotHeatmap::render_post(const ImVec2 &frame_size) {
    (void)frame_size;
}

// ----------------------------------------------------------------------------
// [SECTION] Data functions
// ----------------------------------------------------------------------------
int64_t data_max_hm_pixel_pow(void) {
    return (int64_t)floor(log2((double)(MVEC_SIZE - g_hm_left) / (double)g_hm_pixel_count));
}

void data_update_stride(void) {
    if (g_plot_maximized) {
        g_plot_stride = 1;
        g_downsampled_trace_len = g_trace_len;
        return;
    }

    int win_height = 0;
    glfwGetWindowSize(g_window, nullptr, &win_height);

    int max_stride = g_plot_cols * ((win_height / (int)g_plot_height) + 1);
    int max_points = DEFVAL_ENTRIES / max_stride;
    g_plot_stride = 1;

    while (g_trace_len / g_plot_stride > max_points) {
        g_plot_stride++;
    }

    g_downsampled_trace_len = g_trace_len / g_plot_stride;

    log_info("Updated plot stride: %d", g_plot_stride);
    log_info("Updated downsampled trace-len: %d", g_downsampled_trace_len);
}

void data_on_field_change(void) {
    g_entries = std::clamp(g_entries, 1l, DEFVAL_ENTRIES);
    g_nth = std::clamp(g_nth, DEFVAL_NTH, INT64_MAX);
    g_x_low = std::clamp(g_x_low, DEFVAL_X_LOW, INT64_MAX);
    g_x_high = std::clamp(g_x_high, g_x_low + 1l, DEFVAL_X_HIGH);
#if !defined(MVEC_LOOP)
    g_hm_left = std::clamp(g_hm_left, DEFVAL_HM_LEFT, (int64_t)MVEC_SIZE);
#endif
    g_hm_pixel_count = std::clamp(g_hm_pixel_count, 1l, DEFVAL_HM_PIXEL_COUNT);
    g_hm_pixel_pow = std::clamp(g_hm_pixel_pow, 0l, data_max_hm_pixel_pow());
    g_x_current = -1l;

    g_trace_len = 0l;
    g_trace_offset = 0;;
    g_plot_stride = 0;
    g_downsampled_trace_len = 0;

    for (auto &trace : g_traces) trace->clear();
    for (auto &plot: g_plots) plot->flag_for_reset();
    g_x_axis_double.clear();
    g_zero_trace.clear();
}

void data_reset_fields(void) {
    g_entries = DEFVAL_ENTRIES;
    g_nth = DEFVAL_NTH;
    g_x_axis = DEFVAL_X_AXIS;
    g_x_low = DEFVAL_X_LOW;
    g_x_high = DEFVAL_X_HIGH;
    g_hm_left = DEFVAL_HM_LEFT;
    g_hm_pixel_count = DEFVAL_HM_PIXEL_COUNT;
    g_hm_pixel_pow = data_max_hm_pixel_pow();

    data_on_field_change();
}

void data_reset_plot_cells(void) {
    std::fill(g_plot_cells.begin(), g_plot_cells.end(), nullptr);
    std::fill(g_plot_cells_top.begin(), g_plot_cells_top.end(), 0.f);
    std::fill(g_plot_cells_bottom.begin(), g_plot_cells_bottom.end(), 0.f);
}

void data_fetch(void) {
    assert(g_status == STATUS_RUNNING);
    g_status = STATUS_FETCHING;

    json_object *request = json_object_new_object();
    json_object_object_add(request, "request", json_object_new_string("data"));
    json_object_object_add(request, "entries", json_object_new_int64(g_entries));
    json_object_object_add(request, "nth", json_object_new_int64(g_nth));
    json_object_object_add(request, "x-axis", json_object_new_string(g_x_axes[g_x_axis]));
    json_object_object_add(request, "x-low", json_object_new_int64(g_x_low));
    json_object_object_add(request, "x-high", json_object_new_int64(g_x_high));
    json_object_object_add(request, "hm-left", json_object_new_int64(g_hm_left));
    json_object_object_add(request, "hm-pixel-count", json_object_new_int64(g_hm_pixel_count));
    json_object_object_add(request, "hm-pixel-pow", json_object_new_int64(g_hm_pixel_pow));
    json_object_object_add(request, "x-current", json_object_new_int64(g_x_current));
    const char *request_str = json_object_to_json_string(request);

    log_info("Sending request to server: %s", request_str);
    int socket_fd = socket(AF_INET, SOCK_STREAM, 0);
    sockaddr_in socket_addr;
    memset(&socket_addr, 0, sizeof(sockaddr_in));
    socket_addr.sin_family = AF_INET;
    socket_addr.sin_port = htons(PORT);
    inet_pton(AF_INET, IP, &socket_addr.sin_addr);
    if (connect(socket_fd, (sockaddr *)&socket_addr, sizeof(sockaddr_in))) assert(false);
    json_object_to_fd(socket_fd, request, 0);
    shutdown(socket_fd, SHUT_WR);

    json_object *response = json_object_from_fd(socket_fd);

    mtx_lock(&g_fetching_mutex);

    json_object_object_foreach(response, key, value) {
        size_t new_rows = json_object_array_length(value);

        if (!strcmp(key, g_x_axes[g_x_axis])) {
            log_info("Received %lu rows of data from server", new_rows);

            for (size_t i = 0; i < new_rows; i++) {
                ImS64 point = json_object_get_int64(json_object_array_get_idx(value, i));
                g_x_axis_double.push_back((double)point);
                g_zero_trace.push_back(0.);
            }
        }

        if (g_trace_map.contains(key)) {
            for (size_t i = 0; i < new_rows; i++) {
                ImS64 point = json_object_get_int64(json_object_array_get_idx(value, i));
                g_trace_map[key]->push_back(point);
            }
        }
    }

    g_x_current = g_trace_map[g_x_axes[g_x_axis]]->back();
    json_object_put(request);
    json_object_put(response);

#if !defined(NDEBUG)
    for (auto &trace : g_traces) trace->validate();
    g_x_axis_double.validate();
    g_zero_trace.validate();
#endif

    if ((int64_t)g_traces[0]->size() >= g_entries * 2) {
        log_info("Trimming traces & flagging plots for reset");
        for (auto &trace : g_traces) trace->trim();
        for (auto &plot : g_plots) plot->flag_for_reset();
        g_x_axis_double.trim();
        g_zero_trace.trim();
    }

#if !defined(NDEBUG)
    for (auto &trace : g_traces) trace->validate();
    g_x_axis_double.validate();
    g_zero_trace.validate();
#endif

    int64_t current_size = g_traces[0]->size();
    g_trace_len = std::min(current_size, g_entries);
    g_trace_offset = current_size > g_entries ? current_size - g_entries : 0l;
    data_update_stride();

    mtx_unlock(&g_fetching_mutex);
    g_status = STATUS_RUNNING;
}

int data_fetching_thread(void *data) {
    (void)data;

    assert(!data);
    assert(g_status == STATUS_RUNNING);

    while (g_status == STATUS_RUNNING) {
        data_fetch();

        for (int i = 0; i < DATA_FETCH_INTERVAL_SUBDIV && g_status == STATUS_RUNNING; i++) {
            usleep((DATA_FETCH_INTERVAL * 1000000) / DATA_FETCH_INTERVAL_SUBDIV);
        }
    }

    assert(g_status == STATUS_STOPPING);
    g_status = STATUS_STOPPED;
    return 0;
}

void data_start_fetching(void) {
    log_info("Starting data fetching thread");
    g_status = STATUS_RUNNING;
    thrd_create(&g_fetching_thread, (thrd_start_t)data_fetching_thread, nullptr);
}

void data_stop_fetching(void) {
    assert(g_status == STATUS_RUNNING || g_status == STATUS_FETCHING);
    log_info("Stopping data fetching thread");
    g_status = STATUS_STOPPING;
}

// ----------------------------------------------------------------------------
// [SECTION] GUI functions
// ----------------------------------------------------------------------------
void gui_render_data_input(const char *label, int64_t *target) {
    assert(target);

    if (ImGui::InputScalar(label, ImGuiDataType_U64, target, nullptr, nullptr, "%#lx")) {
        data_on_field_change();
    }
}

void gui_render_data_col(void) {
    const ImGuiViewport *viewport = ImGui::GetMainViewport();
    const ImVec2 win_pos = viewport->Pos;
    const ImVec2 win_size = ImVec2(-1.f, viewport->Size.y);

    ImGui::SetNextWindowPos(win_pos);
    ImGui::SetNextWindowSize(win_size);
    ImGui::Begin("data-col", nullptr, IMGUI_WINDOW_FLAGS);
    g_data_col_width = ImGui::GetWindowWidth();

    ImGui::SeparatorText("SALIS data client");
    ImGui::LabelText("name", NAME);
    ImGui::LabelText("seed", "%#lx", SEED);
    ImGui::LabelText("server", IP ":" PORT_STR);
    ImGui::LabelText("arch", ARCH);
    ImGui::LabelText("cores", "%d", CORES);
    ImGui::LabelText("mvec-size", "%#lx", MVEC_SIZE);
 #if defined(MVEC_LOOP)
    ImGui::LabelText("mvec-loop", "true");
 #else
    ImGui::LabelText("mvec-loop", "false");
 #endif
    ImGui::LabelText("data-push", "%#lx", DATA_PUSH_INTERVAL);
    ImGui::LabelText("fps", "%.1f", g_imgui_io->Framerate);

    ImGui::SeparatorText("Data fields");

    switch (g_status) {
    case STATUS_STOPPED:
        gui_render_data_input("entries", &g_entries);
        gui_render_data_input("nth", &g_nth);

        if (ImGui::BeginCombo("x-axis", g_x_axes[g_x_axis])) {
            for (int i = 0; i < CORES + 2; i++) {
                if (ImGui::Selectable(g_x_axes[i], g_x_axis == i)) {
                    data_reset_fields();
                    g_x_axis = i;
                }
            }

            ImGui::EndCombo();
        }

        gui_render_data_input("x-low", &g_x_low);
        gui_render_data_input("x-high", &g_x_high);
        gui_render_data_input("hm-left", &g_hm_left);
        gui_render_data_input("hm-pxl-count", &g_hm_pixel_count);
        gui_render_data_input("hm-pxl-pow", &g_hm_pixel_pow);
        break;
    case STATUS_RUNNING:
    case STATUS_FETCHING:
    case STATUS_STOPPING:
        ImGui::LabelText("entries", "%#lx", g_entries);
        ImGui::LabelText("nth", "%#lx", g_nth);
        ImGui::LabelText("x-axis", "%s", g_x_axes[g_x_axis]);
        ImGui::LabelText("x-low", "%#lx", g_x_low);
        ImGui::LabelText("x-high", "%#lx", g_x_high);
        ImGui::LabelText("hm-left", "%#lx", g_hm_left);
        ImGui::LabelText("hm-pxl-count", "%#lx", g_hm_pixel_count);
        ImGui::LabelText("hm-pxl-pow", "%#lx", g_hm_pixel_pow);
    }

    switch (g_status) {
    case STATUS_STOPPED:
        if (ImGui::Button("Run", ImVec2(-1.f, 0.f))) data_start_fetching();
        if (ImGui::Button("Reset", ImVec2(-1.f, 0.f))) data_reset_fields();
        break;
    case STATUS_RUNNING:
        if (ImGui::Button("Stop", ImVec2(-1.f, 0.f))) data_stop_fetching();
        ImGui::LabelText("##", "Running");
        break;
    case STATUS_FETCHING:
        if (ImGui::Button("Stop", ImVec2(-1.f, 0.f))) data_stop_fetching();
        ImGui::LabelText("##", "Fetching ...");
        break;
    case STATUS_STOPPING:
        ImGui::BeginDisabled();
        ImGui::Button("Stop", ImVec2(-1.f, 0.f));
        ImGui::EndDisabled();
        ImGui::LabelText("##", "Stopping");
        break;
    }

    ImGui::SeparatorText("Layout");
    ImGui::DragInt("cols", &g_plot_cols, 1, PLOT_MIN_COLS, PLOT_MAX_COLS);
    ImGui::DragFloat("plot-height", &g_plot_height, PLOT_HEIGHT_INTERVAL, PLOT_MIN_HEIGHT, PLOT_MAX_HEIGHT, "%.0f");

    ImGui::SeparatorText("Plots");
    if (ImGui::Button("Show all", ImVec2(-1.f, 0.f))) for (auto &plot : g_plots) plot->m_visible = true;
    if (ImGui::Button("Hide all", ImVec2(-1.f, 0.f))) for (auto &plot : g_plots) plot->m_visible = false;
    ImGui::BeginTable("plot-visibility-table", 3);

    for (auto &plot : g_plots) {
        ImGui::TableNextColumn();
        ImGui::Checkbox(plot->get_name(), &plot->m_visible);
    }

    ImGui::EndTable();
    ImGui::End();
}

size_t gui_plot_cell_index(size_t row, size_t col) {
    size_t index = row * PLOT_MAX_COLS + col;
    assert(index < g_plot_cells.size());
    assert(index < g_plot_cells_top.size());
    assert(index < g_plot_cells_bottom.size());
    return index;
}

size_t gui_plot_cell_row_up() {
    for (size_t row = g_plot_row_selected - 1; row < g_plot_row_selected; row--) {
        if (g_plot_cells[gui_plot_cell_index(row, g_plot_col_selected)]) {
            return row;
        }
    }

    return g_plot_row_selected;
}

size_t gui_plot_cell_row_down() {
    for (size_t row = g_plot_row_selected + 1; row < g_plots.size(); row++) {
        if (g_plot_cells[gui_plot_cell_index(row, g_plot_col_selected)]) {
            return row;
        }
    }

    return g_plot_row_selected;
}

void gui_render_plots(void) {
    const char *section_current = g_plots[0]->get_section();
    const char *section_next = nullptr;

    g_plots_covered.clear();
    g_plots_covered.resize(g_plots.size(), false);

    const ImGuiViewport *viewport = ImGui::GetMainViewport();
    const ImVec2 win_pos = g_data_col_visible ? ImVec2(g_data_col_width, viewport->Pos.y) : viewport->Pos;
    const ImVec2 win_size = g_data_col_visible ? ImVec2(viewport->Size.x - g_data_col_width, -1.f) : ImVec2(viewport->Size.x, -1.f);

    if (g_plot_scroll) {
        ImGui::SetNextWindowScroll(ImVec2(-1.f, g_plot_scroll_to));
        g_plot_scroll = false;
        g_plot_scroll_to = 0.f;
    }

    ImGui::SetNextWindowPos(win_pos);
    ImGui::SetNextWindowSize(win_size);
    ImGui::Begin("plots", nullptr, IMGUI_WINDOW_FLAGS);
    g_plot_scroll_current = ImGui::GetScrollY();
    g_plot_hovered = nullptr;

    if (!g_plot_selected->m_visible) {
        g_plot_selected = g_plots[0];
        g_plot_col_selected = 0;
        g_plot_row_selected = 0;

        for (auto &plot : g_plots) {
            if (plot->m_visible) {
                g_plot_selected = plot;
            }
        }
    }

    size_t row = 0;
    size_t col = 0;

    mtx_lock(&g_fetching_mutex);

    while (section_current) {
        ImGui::SeparatorText(section_current);
        ImGui::BeginTable("plots-table", g_plot_cols);

        for (size_t i = 0; i < g_plots.size(); i++) {
            if (strcmp(g_plots[i]->get_section(), section_current)) {
                section_next = (!section_next && !g_plots_covered[i]) ? g_plots[i]->get_section() : section_next;
                continue;
            }

            if (g_plots[i]->m_visible) {
                ImGui::TableNextColumn();
                ImVec2 frame_size = ImVec2(ImGui::GetContentRegionAvail().x, g_plot_height);
                g_plot_cells[gui_plot_cell_index(row, col)] = g_plots[i];
                g_plot_cells_top[gui_plot_cell_index(row, col)] = ImGui::GetCursorPosY();

                if (g_plots[i] == g_plot_selected) {
                    g_plot_col_selected = col;
                    g_plot_row_selected = row;
                    g_implot_style->Colors[ImPlotCol_FrameBg] = g_imgui_style->Colors[ImGuiCol_FrameBg];
                }

                g_plots[i]->render(frame_size);

                if (g_plots[i] == g_plot_selected) {
                    g_implot_style->Colors[ImPlotCol_FrameBg] = COLOR_BLACK;
                }

                g_plot_cells_bottom[gui_plot_cell_index(row, col)] = ImGui::GetCursorPosY();
                col = (col + 1) % g_plot_cols;
                row += col ? 0 : 1;
            }

            g_plots_covered[i] = true;
        }

        section_current = section_next;
        section_next = nullptr;
        ImGui::EndTable();
        row += col ? 1 : 0;
        col = 0;
    }

    mtx_unlock(&g_fetching_mutex);
    ImGui::End();
}

void gui_render_plot_maximized(void) {
    const ImGuiViewport *viewport = ImGui::GetMainViewport();
    ImGui::SetNextWindowPos(viewport->Pos);
    ImGui::SetNextWindowSize(viewport->Size);
    ImGui::Begin("plot-fullscreen", nullptr, IMGUI_WINDOW_FLAGS);

    ImVec2 frame_size = {
        viewport->Size.x - g_imgui_style->WindowPadding.x * 2,
        viewport->Size.y - g_imgui_style->WindowPadding.y * 2,
    };

    mtx_lock(&g_fetching_mutex);
    g_plot_selected->render(frame_size);
    mtx_unlock(&g_fetching_mutex);
    ImGui::End();
}

void gui_plot_queue_scroll_to_position(bool increased_plot_height) {
    size_t row = 0;
    float selected_plot_top = 0.f;

    for (row = 0; row < g_plots.size(); row++) {
        for (size_t col = 0; col < PLOT_MAX_COLS; col++) {
            if (g_plot_selected == g_plot_cells[gui_plot_cell_index(row, col)]) {
                selected_plot_top = g_plot_cells_top[gui_plot_cell_index(row, col)];
                goto loop_exit;
            }
        }
    }

    loop_exit:
    g_plot_scroll_to = selected_plot_top + (PLOT_HEIGHT_INTERVAL * (float)row * (increased_plot_height ? 1.f : -1.f)) - PLOT_SCROLL_MARGIN;
    g_plot_scroll = true;
}

void gui_plot_queue_scroll_to_selected() {
    const ImGuiViewport *viewport = ImGui::GetMainViewport();
    float plot_top = g_plot_cells_top[gui_plot_cell_index(g_plot_row_selected, g_plot_col_selected)];
    float plot_bottom = g_plot_cells_bottom[gui_plot_cell_index(g_plot_row_selected, g_plot_col_selected)];
    float win_bottom = g_plot_scroll_current + viewport->Size.y;

    if (plot_bottom > win_bottom) {
        g_plot_scroll_to = g_plot_scroll_current + (plot_bottom - win_bottom);
        g_plot_scroll = true;
    }

    if (plot_top < g_plot_scroll_current) {
        g_plot_scroll_to = plot_top - PLOT_SCROLL_MARGIN;
        g_plot_scroll = true;
    }
}

void gui_render(void) {
    if (g_plot_maximized) {
        gui_render_plot_maximized();
        return;
    }

    if (g_data_col_visible) gui_render_data_col();
    gui_render_plots();
}

// ----------------------------------------------------------------------------
// [SECTION] Main functions
// ----------------------------------------------------------------------------
void app_sig_handler(int signo) {
    (void)signo;

    log_warn("Signal received, will stop SALIS data client...");

    if (g_status == STATUS_RUNNING || g_status == STATUS_FETCHING) {
        data_stop_fetching();
    }

    glfwSetWindowShouldClose(g_window, GLFW_TRUE);
}

void app_error_callback(int error, const char* description) {
    log_warn("GLFW error %d: %s", error, description);
}

void app_toggle_state() {
    switch (g_status) {
    case STATUS_STOPPED:
        data_start_fetching();
        break;
    case STATUS_RUNNING:
    case STATUS_FETCHING:
        data_stop_fetching();
        break;
    }
}

void app_key_callback_plot_maximized(int key, int mods) {
    switch (mods) {
    case GLFW_MOD_CONTROL:
        switch (key) {
        case GLFW_KEY_C:
            glfwSetWindowShouldClose(g_window, GLFW_TRUE);
            break;
        }

        break;

    case 0:
        switch (key) {
        case GLFW_KEY_F:
            g_plot_maximized = false;
            data_update_stride();
            break;
        case GLFW_KEY_SPACE:
            app_toggle_state();
            break;
        }

        break;
    }

    if (g_plot_selected->m_visible) {
        g_plot_selected->handle_input(key, mods);
    }
}

void app_key_callback(GLFWwindow* window, int key, int scancode, int action, int mods) {
    (void)window;
    (void)scancode;

    if (ImGui::IsAnyItemActive()) {
        return;
    }

    if (action != GLFW_PRESS && action != GLFW_REPEAT) {
        return;
    }

    if (g_plot_maximized) {
        app_key_callback_plot_maximized(key, mods);
        return;
    }

    switch (mods) {
    case GLFW_MOD_CONTROL:
        switch (key) {
        case GLFW_KEY_C:
            glfwSetWindowShouldClose(g_window, GLFW_TRUE);
            break;
        case GLFW_KEY_N:
            g_data_col_visible = !g_data_col_visible;
            break;
        case GLFW_KEY_LEFT:
            g_plot_cols = std::max(g_plot_cols - 1, PLOT_MIN_COLS);
            data_reset_plot_cells();
            data_update_stride();
            break;
        case GLFW_KEY_RIGHT:
            g_plot_cols = std::min(g_plot_cols + 1, PLOT_MAX_COLS);
            data_reset_plot_cells();
            data_update_stride();
            break;
        case GLFW_KEY_UP:
            g_plot_height = std::min(g_plot_height + PLOT_HEIGHT_INTERVAL, PLOT_MAX_HEIGHT);
            gui_plot_queue_scroll_to_position(true);
            data_update_stride();
            break;
        case GLFW_KEY_DOWN:
            g_plot_height = std::max(g_plot_height - PLOT_HEIGHT_INTERVAL, PLOT_MIN_HEIGHT);
            gui_plot_queue_scroll_to_position(false);
            data_update_stride();
            break;
        }

        break;

    case 0:
        switch (key) {
        case GLFW_KEY_LEFT:
            g_plot_col_selected -= g_plot_col_selected ? 1 : 0;
            g_plot_selected = g_plot_cells[gui_plot_cell_index(g_plot_row_selected, g_plot_col_selected)];
            break;
        case GLFW_KEY_RIGHT:
            g_plot_col_selected += (g_plot_col_selected < PLOT_MAX_COLS - 1 && g_plot_cells[gui_plot_cell_index(g_plot_row_selected, g_plot_col_selected + 1)]) ? 1 : 0;
            g_plot_selected = g_plot_cells[gui_plot_cell_index(g_plot_row_selected, g_plot_col_selected)];
            break;
        case GLFW_KEY_UP:
            g_plot_row_selected = gui_plot_cell_row_up();
            g_plot_selected = g_plot_cells[gui_plot_cell_index(g_plot_row_selected, g_plot_col_selected)];
            gui_plot_queue_scroll_to_selected();
            break;
        case GLFW_KEY_DOWN:
            g_plot_row_selected = gui_plot_cell_row_down();
            g_plot_selected = g_plot_cells[gui_plot_cell_index(g_plot_row_selected, g_plot_col_selected)];
            gui_plot_queue_scroll_to_selected();
            break;
        case GLFW_KEY_F:
            if (g_plot_selected->m_visible) {
                g_plot_maximized = !g_plot_maximized;
                data_update_stride();
            }

            break;
        case GLFW_KEY_SPACE:
            app_toggle_state();
            break;
        }

        break;
    }

    if (g_plot_selected->m_visible) {
        g_plot_selected->handle_input(key, mods);
    }
}

void app_window_size_callback(GLFWwindow* window, int width, int height) {
    (void)window;
    (void)width;
    (void)height;

    data_update_stride();
}

void app_mouse_button_callback(GLFWwindow* window, int button, int action, int mods) {
    (void)window;
    (void)mods;

    if (button != GLFW_MOUSE_BUTTON_LEFT) return;

    switch (action) {
    case GLFW_PRESS:
        g_plot_selected = g_plot_hovered ? g_plot_hovered : g_plot_selected;
        break;
    }
}

void init() {
    signal(SIGINT, app_sig_handler);
    signal(SIGTERM, app_sig_handler);

    log_info("Starting SALIS data client");

    log_info("Initializing GLFW");
    glfwSetErrorCallback(app_error_callback);
    glfwInitHint(GLFW_WAYLAND_LIBDECOR, GLFW_WAYLAND_DISABLE_LIBDECOR);
    if (!glfwInit()) assert(false);

    float scale = ImGui_ImplGlfw_GetContentScaleForMonitor(glfwGetPrimaryMonitor());
    g_window = glfwCreateWindow((int)(800 * scale), (int)(600 * scale), "SALIS data client", nullptr, nullptr);
    assert(g_window);
    glfwSetKeyCallback(g_window, app_key_callback);
    glfwSetMouseButtonCallback(g_window, app_mouse_button_callback);
    glfwSetWindowSizeCallback(g_window, app_window_size_callback);
    glfwMakeContextCurrent(g_window);
#if defined(VSYNC)
    glfwSwapInterval(1);
#else
    glfwSwapInterval(0);
#endif

    glCopyImageSubData = (PFNGLCOPYIMAGESUBDATAPROC)glfwGetProcAddress("glCopyImageSubData");
    assert(glCopyImageSubData);

    log_info("Initializing ImGui");
    IMGUI_CHECKVERSION();
    ImGui::CreateContext();
    ImPlot::CreateContext();

    g_imgui_io = &ImGui::GetIO();
    g_imgui_io->Fonts->AddFontFromFileTTF(FONT_SOURCE, FONT_SIZE);
    g_imgui_io->IniFilename = nullptr;

    g_imgui_style = &ImGui::GetStyle();
    g_imgui_style->Colors[ImGuiCol_WindowBg] = COLOR_BLACK;
    g_imgui_style->FontScaleDpi = scale;
    g_imgui_style->FontSizeBase = FONT_SIZE;
    g_imgui_style->ItemSpacing = ImVec2(g_imgui_style->ItemSpacing.x, 2.f);
    g_imgui_style->ScaleAllSizes(scale);

    g_implot_style = &ImPlot::GetStyle();
    g_implot_style->Colors[ImPlotCol_FrameBg] = COLOR_BLACK;
    g_hm_colormap_id = ImPlot::AddColormap("heatmap", g_hm_colormap.data(), g_hm_colormap.size(), false);

    ImGui_ImplGlfw_InitForOpenGL(g_window, true);
    ImGui_ImplOpenGL3_Init(GLSL_VERSION);

    for (auto &trace : g_core_traces) g_traces.push_back(&trace);
    for (auto &trace : g_arch_traces) g_traces.push_back(&trace);
    for (auto &trace : g_core_traces_heatmaps) g_traces.push_back(&trace);
    for (auto &trace : g_arch_traces_heatmaps) g_traces.push_back(&trace);
    for (auto &plot : g_core_plots) g_plots.push_back(&plot);
    for (auto &plot : g_arch_plots) g_plots.push_back(&plot);
    for (auto &plot : g_arch_plots_stacked) g_plots.push_back(&plot);
    for (auto &plot : g_core_plots_heatmaps) g_plots.push_back(&plot);
    for (auto &plot : g_arch_plots_heatmaps) g_plots.push_back(&plot);
    for (auto &i : g_traces) g_trace_map[i->get_name()] = i;

    g_plot_cells = std::vector<Plot *>(g_plots.size() * PLOT_MAX_COLS);
    g_plot_cells_top = std::vector<float>(g_plots.size() * PLOT_MAX_COLS);
    g_plot_cells_bottom = std::vector<float>(g_plots.size() * PLOT_MAX_COLS);
    g_plot_selected = g_plots[0];

    g_hm_pixel_pow = data_max_hm_pixel_pow();
    data_update_stride();

    mtx_init(&g_fetching_mutex, mtx_plain);
}

void exec() {
    while (!glfwWindowShouldClose(g_window)) {
        glfwPollEvents();

        ImGui_ImplOpenGL3_NewFrame();
        ImGui_ImplGlfw_NewFrame();
        ImGui::NewFrame();

        gui_render();

        ImGui::Render();
        int display_w;
        int display_h;
        glfwGetFramebufferSize(g_window, &display_w, &display_h);
        glViewport(0, 0, display_w, display_h);
        glClearColor(0.f, 0.f, 0.f, 1.f);
        glClear(GL_COLOR_BUFFER_BIT);
        ImGui_ImplOpenGL3_RenderDrawData(ImGui::GetDrawData());
        glfwSwapBuffers(g_window);
    }
}

void quit() {
    mtx_destroy(&g_fetching_mutex);

    ImGui_ImplOpenGL3_Shutdown();
    ImGui_ImplGlfw_Shutdown();
    ImPlot::DestroyContext();
    ImGui::DestroyContext();

    log_info("Stopping SALIS data client");
    glfwDestroyWindow(g_window);
    glfwTerminate();
}

int main(int argc, char **argv) {
    (void)argc;
    (void)argv;

    init();
    exec();
    quit();

    return 0;
}