subsurface/stats/statsview.cpp

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// SPDX-License-Identifier: GPL-2.0
#include "statsview.h"
#include "barseries.h"
#include "boxseries.h"
#include "legend.h"
#include "pieseries.h"
#include "scatterseries.h"
#include "statsaxis.h"
#include "statscolors.h"
#include "statsgrid.h"
#include "statshelper.h"
#include "statsstate.h"
#include "statstranslations.h"
#include "statsvariables.h"
#include "zvalues.h"
#include "core/divefilter.h"
#include "core/subsurface-qt/divelistnotifier.h"
#include <cmath>
#include <QGraphicsScene>
#include <QGraphicsSceneHoverEvent>
#include <QGraphicsSimpleTextItem>
#include <QQuickItem>
#include <QQuickWindow>
#include <QSGImageNode>
#include <QSGTexture>
QSGNode *StatsView::updatePaintNode(QSGNode *oldNode, QQuickItem::UpdatePaintNodeData *)
{
// The QtQuick drawing interface is utterly bizzare with a distinct 1980ies-style memory management.
// This is just a copy of what is found in Qt's documentation.
QSGImageNode *n = static_cast<QSGImageNode *>(oldNode);
if (!n)
n = window()->createImageNode();
QRectF rect = boundingRect();
if (plotRect != rect) {
plotRect = rect;
plotAreaChanged(plotRect.size());
}
img->fill(backgroundColor);
scene.render(painter.get());
texture.reset(window()->createTextureFromImage(*img, QQuickWindow::TextureIsOpaque));
n->setTexture(texture.get());
n->setRect(rect);
return n;
}
// Constants that control the graph layouts
static const QColor quartileMarkerColor(Qt::red);
static const double quartileMarkerSize = 15.0;
static const double sceneBorder = 5.0; // Border between scene edges and statitistics view
static const double titleBorder = 2.0; // Border between title and chart
StatsView::StatsView(QQuickItem *parent) : QQuickItem(parent),
highlightedSeries(nullptr),
xAxis(nullptr),
yAxis(nullptr)
{
setFlag(ItemHasContents, true);
connect(&diveListNotifier, &DiveListNotifier::numShownChanged, this, &StatsView::replotIfVisible);
setAcceptHoverEvents(true);
QFont font;
titleFont = QFont(font.family(), font.pointSize(), QFont::Light); // Make configurable
}
StatsView::StatsView() : StatsView(nullptr)
{
}
StatsView::~StatsView()
{
}
void StatsView::plotAreaChanged(const QSizeF &s)
{
// Make sure that image is at least one pixel wide / high, otherwise
// the painter starts acting up.
int w = std::max(1, static_cast<int>(floor(s.width())));
int h = std::max(1, static_cast<int>(floor(s.height())));
scene.setSceneRect(QRectF(0, 0, static_cast<double>(w), static_cast<double>(h)));
painter.reset();
img.reset(new QImage(w, h, QImage::Format_RGB32));
painter.reset(new QPainter(img.get()));
painter->setRenderHint(QPainter::Antialiasing);
double left = sceneBorder;
double top = sceneBorder;
double right = s.width() - sceneBorder;
double bottom = s.height() - sceneBorder;
const double minSize = 30.0;
if (title)
top += title->boundingRect().height() + titleBorder;
// Currently, we only have either none, or an x- and a y-axis
std::pair<double,double> horizontalSpace{ 0.0, 0.0 };
if (xAxis) {
bottom -= xAxis->height();
horizontalSpace = xAxis->horizontalOverhang();
}
if (bottom - top < minSize)
return;
if (yAxis) {
yAxis->setSize(bottom - top);
horizontalSpace.first = std::max(horizontalSpace.first, yAxis->width());
}
left += horizontalSpace.first;
right -= horizontalSpace.second;
if (yAxis)
yAxis->setPos(QPointF(left, bottom));
if (right - left < minSize)
return;
if (xAxis) {
xAxis->setSize(right - left);
xAxis->setPos(QPointF(left, bottom));
}
if (grid)
grid->updatePositions();
for (auto &series: series)
series->updatePositions();
for (QuartileMarker &marker: quartileMarkers)
marker.updatePosition();
for (RegressionLine &line: regressionLines)
line.updatePosition();
for (HistogramMarker &marker: histogramMarkers)
marker.updatePosition();
if (legend)
legend->resize();
updateTitlePos();
}
void StatsView::replotIfVisible()
{
if (isVisible())
plot(state);
}
void StatsView::hoverEnterEvent(QHoverEvent *)
{
}
void StatsView::hoverMoveEvent(QHoverEvent *event)
{
QPointF pos(event->pos());
for (auto &series: series) {
if (series->hover(pos)) {
if (series.get() != highlightedSeries) {
if (highlightedSeries)
highlightedSeries->unhighlight();
highlightedSeries = series.get();
}
return update();
}
}
// No series was highlighted -> unhighlight any previously highlighted series.
if (highlightedSeries) {
highlightedSeries->unhighlight();
highlightedSeries = nullptr;
update();
}
}
template <typename T, class... Args>
T *StatsView::createSeries(Args&&... args)
{
T *res = new T(&scene, xAxis, yAxis, std::forward<Args>(args)...);
series.emplace_back(res);
series.back()->updatePositions();
return res;
}
void StatsView::setTitle(const QString &s)
{
if (s.isEmpty()) {
title.reset();
return;
}
title = createItemPtr<QGraphicsSimpleTextItem>(&scene, s);
title->setFont(titleFont);
}
void StatsView::updateTitlePos()
{
if (!title)
return;
QRectF rect = scene.sceneRect();
title->setPos(sceneBorder + (rect.width() - title->boundingRect().width()) / 2.0,
sceneBorder);
}
template <typename T, class... Args>
T *StatsView::createAxis(const QString &title, Args&&... args)
{
T *res = createItem<T>(&scene, title, std::forward<Args>(args)...);
axes.emplace_back(res);
return res;
}
void StatsView::setAxes(StatsAxis *x, StatsAxis *y)
{
xAxis = x;
yAxis = y;
if (x && y)
grid = std::make_unique<StatsGrid>(&scene, *x, *y);
}
void StatsView::reset()
{
highlightedSeries = nullptr;
xAxis = yAxis = nullptr;
legend.reset();
series.clear();
quartileMarkers.clear();
regressionLines.clear();
histogramMarkers.clear();
grid.reset();
axes.clear();
title.reset();
}
void StatsView::plot(const StatsState &stateIn)
{
state = stateIn;
plotChart();
plotAreaChanged(scene.sceneRect().size());
update();
}
void StatsView::plotChart()
{
if (!state.var1)
return;
reset();
const std::vector<dive *> dives = DiveFilter::instance()->visibleDives();
switch (state.type) {
case ChartType::DiscreteBar:
return plotBarChart(dives, state.subtype, state.var1, state.var1Binner, state.var2,
state.var2Binner, state.labels, state.legend);
case ChartType::DiscreteValue:
return plotValueChart(dives, state.subtype, state.var1, state.var1Binner, state.var2,
state.var2Operation, state.labels);
case ChartType::DiscreteCount:
return plotDiscreteCountChart(dives, state.subtype, state.var1, state.var1Binner, state.labels);
case ChartType::Pie:
return plotPieChart(dives, state.var1, state.var1Binner, state.labels, state.legend);
case ChartType::DiscreteBox:
return plotDiscreteBoxChart(dives, state.var1, state.var1Binner, state.var2);
case ChartType::DiscreteScatter:
return plotDiscreteScatter(dives, state.var1, state.var1Binner, state.var2, state.quartiles);
case ChartType::HistogramCount:
return plotHistogramCountChart(dives, state.subtype, state.var1, state.var1Binner,
state.labels, state.median, state.mean);
case ChartType::HistogramValue:
return plotHistogramValueChart(dives, state.subtype, state.var1, state.var1Binner, state.var2,
state.var2Operation, state.labels);
case ChartType::HistogramStacked:
return plotHistogramStackedChart(dives, state.subtype, state.var1, state.var1Binner,
state.var2, state.var2Binner, state.labels, state.legend);
case ChartType::HistogramBox:
return plotHistogramBoxChart(dives, state.var1, state.var1Binner, state.var2);
case ChartType::ScatterPlot:
return plotScatter(dives, state.var1, state.var2);
case ChartType::Invalid:
return;
default:
qWarning("Unknown chart type: %d", (int)state.type);
return;
}
}
template<typename T>
CategoryAxis *StatsView::createCategoryAxis(const QString &name, const StatsBinner &binner,
const std::vector<T> &bins, bool isHorizontal)
{
std::vector<QString> labels;
labels.reserve(bins.size());
for (const auto &[bin, dummy]: bins)
labels.push_back(binner.format(*bin));
return createAxis<CategoryAxis>(name, labels, isHorizontal);
}
CountAxis *StatsView::createCountAxis(int maxVal, bool isHorizontal)
{
return createAxis<CountAxis>(StatsTranslations::tr("No. dives"), maxVal, isHorizontal);
}
// For "two-dimensionally" binned plots (eg. stacked bar or grouped bar):
// Counts for each bin on the independent variable, including the total counts for that bin.
struct BinCounts {
StatsBinPtr bin;
std::vector<int> counts;
int total;
};
// The problem with bar plots is that for different category
// bins, we might get different value bins. So we have to keep track
// of our counts and adjust accordingly. That's a bit annoying.
// Perhaps we should determine the bins of all dives first and then
// query the counts for precisely those bins?
struct BarPlotData {
std::vector<BinCounts> hbin_counts; // For each category bin the counts for all value bins
std::vector<StatsBinPtr> vbins;
std::vector<QString> vbinNames;
int maxCount; // Highest count of any bin-combination
int maxCategoryCount; // Highest count of any category bin
// Attention: categoryBin argument will be consumed!
BarPlotData(std::vector<StatsBinDives> &categoryBins, const StatsBinner &valuebinner);
};
BarPlotData::BarPlotData(std::vector<StatsBinDives> &categoryBins, const StatsBinner &valueBinner) :
maxCount(0), maxCategoryCount(0)
{
for (auto &[bin, dives]: categoryBins) {
// This moves the bin - the original pointer is invalidated
hbin_counts.push_back({ std::move(bin), std::vector<int>(vbins.size(), 0), 0 });
for (auto &[vbin, count]: valueBinner.count_dives(dives, false)) {
// Note: we assume that the bins are sorted!
auto it = std::lower_bound(vbins.begin(), vbins.end(), vbin,
[] (const StatsBinPtr &p, const StatsBinPtr &bin)
{ return *p < *bin; });
ssize_t pos = it - vbins.begin();
if (it == vbins.end() || **it != *vbin) {
// Add a new value bin.
// Attn: this invalidates "vbin", which must not be used henceforth!
vbins.insert(it, std::move(vbin));
// Fix the old arrays
for (auto &[bin, v, total]: hbin_counts)
v.insert(v.begin() + pos, 0);
}
hbin_counts.back().counts[pos] = count;
hbin_counts.back().total += count;
if (count > maxCount)
maxCount = count;
}
maxCategoryCount = std::max(maxCategoryCount, hbin_counts.back().total);
}
vbinNames.reserve(vbins.size());
for (const auto &vbin: vbins)
vbinNames.push_back(valueBinner.formatWithUnit(*vbin));
}
// Formats "x (y%)" as either a single or two strings for horizontal and non-horizontal cases, respectively.
static std::vector<QString> makePercentageLabels(int count, int total, bool isHorizontal)
{
double percentage = count * 100.0 / total;
QString countString = QString("%L1").arg(count);
QString percentageString = QString("%L1%").arg(percentage, 0, 'f', 1);
if (isHorizontal)
return { QString("%1 (%2)").arg(countString, percentageString) };
else
return { countString, percentageString };
}
// From a list of counts, make (count, label) pairs, where the label
// formats the total number and the percentage of dives.
static std::vector<std::pair<int, std::vector<QString>>> makeCountLabels(const std::vector<int> &counts, int total,
bool labels, bool isHorizontal)
{
std::vector<std::pair<int, std::vector<QString>>> count_labels;
count_labels.reserve(counts.size());
for (int count: counts) {
std::vector<QString> label = labels ? makePercentageLabels(count, total, isHorizontal)
: std::vector<QString>();
count_labels.push_back(std::make_pair(count, label));
}
return count_labels;
}
void StatsView::plotBarChart(const std::vector<dive *> &dives,
ChartSubType subType,
const StatsVariable *categoryVariable, const StatsBinner *categoryBinner,
const StatsVariable *valueVariable, const StatsBinner *valueBinner, bool labels, bool showLegend)
{
if (!categoryBinner || !valueBinner)
return;
setTitle(valueVariable->nameWithBinnerUnit(*valueBinner));
std::vector<StatsBinDives> categoryBins = categoryBinner->bin_dives(dives, false);
bool isStacked = subType == ChartSubType::VerticalStacked || subType == ChartSubType::HorizontalStacked;
bool isHorizontal = subType == ChartSubType::HorizontalGrouped || subType == ChartSubType::HorizontalStacked;
// Construct the histogram axis now, because the pointers to the bins
// will be moved away when constructing BarPlotData below.
CategoryAxis *catAxis = createCategoryAxis(categoryVariable->nameWithBinnerUnit(*categoryBinner),
*categoryBinner, categoryBins, !isHorizontal);
BarPlotData data(categoryBins, *valueBinner);
int maxVal = isStacked ? data.maxCategoryCount : data.maxCount;
CountAxis *valAxis = createCountAxis(maxVal, isHorizontal);
if (isHorizontal)
setAxes(valAxis, catAxis);
else
setAxes(catAxis, valAxis);
// Paint legend first, because the bin-names will be moved away from.
if (showLegend)
legend = createItemPtr<Legend>(&scene, data.vbinNames);
std::vector<BarSeries::MultiItem> items;
items.reserve(data.hbin_counts.size());
double pos = 0.0;
for (auto &[hbin, counts, total]: data.hbin_counts) {
items.push_back({ pos - 0.5, pos + 0.5, makeCountLabels(counts, total, labels, isHorizontal),
categoryBinner->formatWithUnit(*hbin) });
pos += 1.0;
}
createSeries<BarSeries>(isHorizontal, isStacked, categoryVariable->name(), valueVariable, std::move(data.vbinNames), items);
}
const double NaN = std::numeric_limits<double>::quiet_NaN();
// These templates are used to extract min and max y-values of various lists.
// A bit too convoluted for my tastes - can we make that simpler?
static std::pair<double, double> getMinMaxValueBase(const std::vector<StatsValue> &values)
{
// Attention: this supposes that the list is sorted!
return values.empty() ? std::make_pair(NaN, NaN) : std::make_pair(values.front().v, values.back().v);
}
static std::pair<double, double> getMinMaxValueBase(double v)
{
return { v, v };
}
static std::pair<double, double> getMinMaxValueBase(const StatsQuartiles &q)
{
return { q.min, q.max };
}
static std::pair<double, double> getMinMaxValueBase(const StatsScatterItem &s)
{
return { s.y, s.y };
}
template <typename T1, typename T2>
static std::pair<double, double> getMinMaxValueBase(const std::pair<T1, T2> &p)
{
return getMinMaxValueBase(p.second);
}
template <typename T>
static std::pair<double, double> getMinMaxValueBase(const StatsBinValue<T> &v)
{
return getMinMaxValueBase(v.value);
}
template <typename T>
static void updateMinMax(double &min, double &max, bool &found, const T &v)
{
const auto [mi, ma] = getMinMaxValueBase(v);
if (!std::isnan(mi) && mi < min)
min = mi;
if (!std::isnan(ma) && ma > max)
max = ma;
if (!std::isnan(mi) || !std::isnan(ma))
found = true;
}
template <typename T>
static std::pair<double, double> getMinMaxValue(const std::vector<T> &values)
{
double min = 1e14, max = 0.0;
bool found = false;
for (const T &v: values)
updateMinMax(min, max, found, v);
return found ? std::make_pair(min, max) : std::make_pair(0.0, 0.0);
}
static std::pair<double, double> getMinMaxValue(const std::vector<StatsBinOp> &bins, StatsOperation op)
{
double min = 1e14, max = 0.0;
bool found = false;
for (auto &[bin, res]: bins) {
if (!res.isValid())
continue;
updateMinMax(min, max, found, res.get(op));
}
return found ? std::make_pair(min, max) : std::make_pair(0.0, 0.0);
}
void StatsView::plotValueChart(const std::vector<dive *> &dives,
ChartSubType subType,
const StatsVariable *categoryVariable, const StatsBinner *categoryBinner,
const StatsVariable *valueVariable, StatsOperation valueAxisOperation,
bool labels)
{
if (!categoryBinner)
return;
setTitle(QStringLiteral("%1 (%2)").arg(valueVariable->name(), StatsVariable::operationName(valueAxisOperation)));
std::vector<StatsBinOp> categoryBins = valueVariable->bin_operations(*categoryBinner, dives, false);
// If there is nothing to display, quit
if (categoryBins.empty())
return;
bool isHorizontal = subType == ChartSubType::Horizontal;
const auto [minValue, maxValue] = getMinMaxValue(categoryBins, valueAxisOperation);
int decimals = valueVariable->decimals();
CategoryAxis *catAxis = createCategoryAxis(categoryVariable->nameWithBinnerUnit(*categoryBinner),
*categoryBinner, categoryBins, !isHorizontal);
ValueAxis *valAxis = createAxis<ValueAxis>(valueVariable->nameWithUnit(),
0.0, maxValue, valueVariable->decimals(), isHorizontal);
if (isHorizontal)
setAxes(valAxis, catAxis);
else
setAxes(catAxis, valAxis);
std::vector<BarSeries::ValueItem> items;
items.reserve(categoryBins.size());
double pos = 0.0;
QString unit = valueVariable->unitSymbol();
for (auto &[bin, res]: categoryBins) {
if (res.isValid()) {
double height = res.get(valueAxisOperation);
QString value = QString("%L1").arg(height, 0, 'f', decimals);
std::vector<QString> label = labels ? std::vector<QString> { value }
: std::vector<QString>();
items.push_back({ pos - 0.5, pos + 0.5, height, label,
categoryBinner->formatWithUnit(*bin), res });
}
pos += 1.0;
}
createSeries<BarSeries>(isHorizontal, categoryVariable->name(), valueVariable, items);
}
static int getTotalCount(const std::vector<StatsBinCount> &bins)
{
int total = 0;
for (const auto &[bin, count]: bins)
total += count;
return total;
}
template<typename T>
static int getMaxCount(const std::vector<T> &bins)
{
int res = 0;
for (auto const &[dummy, val]: bins) {
if (val > res)
res = val;
}
return res;
}
void StatsView::plotDiscreteCountChart(const std::vector<dive *> &dives,
ChartSubType subType,
const StatsVariable *categoryVariable, const StatsBinner *categoryBinner,
bool labels)
{
if (!categoryBinner)
return;
setTitle(categoryVariable->nameWithBinnerUnit(*categoryBinner));
std::vector<StatsBinCount> categoryBins = categoryBinner->count_dives(dives, false);
// If there is nothing to display, quit
if (categoryBins.empty())
return;
int total = getTotalCount(categoryBins);
bool isHorizontal = subType != ChartSubType::Vertical;
CategoryAxis *catAxis = createCategoryAxis(categoryVariable->nameWithBinnerUnit(*categoryBinner),
*categoryBinner, categoryBins, !isHorizontal);
int maxCount = getMaxCount(categoryBins);
CountAxis *valAxis = createCountAxis(maxCount, isHorizontal);
if (isHorizontal)
setAxes(valAxis, catAxis);
else
setAxes(catAxis, valAxis);
std::vector<BarSeries::CountItem> items;
items.reserve(categoryBins.size());
double pos = 0.0;
for (auto const &[bin, count]: categoryBins) {
std::vector<QString> label = labels ? makePercentageLabels(count, total, isHorizontal)
: std::vector<QString>();
items.push_back({ pos - 0.5, pos + 0.5, count, label,
categoryBinner->formatWithUnit(*bin), total });
pos += 1.0;
}
createSeries<BarSeries>(isHorizontal, categoryVariable->name(), items);
}
void StatsView::plotPieChart(const std::vector<dive *> &dives,
const StatsVariable *categoryVariable, const StatsBinner *categoryBinner,
bool labels, bool showLegend)
{
if (!categoryBinner)
return;
setTitle(categoryVariable->nameWithBinnerUnit(*categoryBinner));
std::vector<StatsBinCount> categoryBins = categoryBinner->count_dives(dives, false);
// If there is nothing to display, quit
if (categoryBins.empty())
return;
std::vector<std::pair<QString, int>> data;
data.reserve(categoryBins.size());
for (auto const &[bin, count]: categoryBins)
data.emplace_back(categoryBinner->formatWithUnit(*bin), count);
bool keepOrder = categoryVariable->type() != StatsVariable::Type::Discrete;
PieSeries *series = createSeries<PieSeries>(categoryVariable->name(), data, keepOrder, labels);
if (showLegend)
legend = createItemPtr<Legend>(&scene, series->binNames());
}
void StatsView::plotDiscreteBoxChart(const std::vector<dive *> &dives,
const StatsVariable *categoryVariable, const StatsBinner *categoryBinner,
const StatsVariable *valueVariable)
{
if (!categoryBinner)
return;
setTitle(valueVariable->name());
std::vector<StatsBinQuartiles> categoryBins = valueVariable->bin_quartiles(*categoryBinner, dives, false);
// If there is nothing to display, quit
if (categoryBins.empty())
return;
CategoryAxis *catAxis = createCategoryAxis(categoryVariable->nameWithBinnerUnit(*categoryBinner),
*categoryBinner, categoryBins, true);
auto [minY, maxY] = getMinMaxValue(categoryBins);
ValueAxis *valueAxis = createAxis<ValueAxis>(valueVariable->nameWithUnit(),
minY, maxY, valueVariable->decimals(), false);
setAxes(catAxis, valueAxis);
BoxSeries *series = createSeries<BoxSeries>(valueVariable->name(), valueVariable->unitSymbol(), valueVariable->decimals());
double pos = 0.0;
for (auto &[bin, q]: categoryBins) {
if (q.isValid())
series->append(pos - 0.5, pos + 0.5, q, categoryBinner->formatWithUnit(*bin));
pos += 1.0;
}
}
void StatsView::plotDiscreteScatter(const std::vector<dive *> &dives,
const StatsVariable *categoryVariable, const StatsBinner *categoryBinner,
const StatsVariable *valueVariable, bool quartiles)
{
if (!categoryBinner)
return;
setTitle(valueVariable->name());
std::vector<StatsBinValues> categoryBins = valueVariable->bin_values(*categoryBinner, dives, false);
// If there is nothing to display, quit
if (categoryBins.empty())
return;
CategoryAxis *catAxis = createCategoryAxis(categoryVariable->nameWithBinnerUnit(*categoryBinner),
*categoryBinner, categoryBins, true);
auto [minValue, maxValue] = getMinMaxValue(categoryBins);
ValueAxis *valAxis = createAxis<ValueAxis>(valueVariable->nameWithUnit(),
minValue, maxValue, valueVariable->decimals(), false);
setAxes(catAxis, valAxis);
ScatterSeries *series = createSeries<ScatterSeries>(*categoryVariable, *valueVariable);
double x = 0.0;
for (const auto &[bin, array]: categoryBins) {
for (auto [v, d]: array)
series->append(d, x, v);
if (quartiles) {
StatsQuartiles quartiles = StatsVariable::quartiles(array);
if (quartiles.isValid()) {
quartileMarkers.emplace_back(x, quartiles.q1, &scene, catAxis, valAxis);
quartileMarkers.emplace_back(x, quartiles.q2, &scene, catAxis, valAxis);
quartileMarkers.emplace_back(x, quartiles.q3, &scene, catAxis, valAxis);
}
}
x += 1.0;
}
}
StatsView::QuartileMarker::QuartileMarker(double pos, double value, QGraphicsScene *scene, StatsAxis *xAxis, StatsAxis *yAxis) :
item(createItemPtr<QGraphicsLineItem>(scene)),
xAxis(xAxis), yAxis(yAxis),
pos(pos),
value(value)
{
item->setZValue(ZValues::chartFeatures);
item->setPen(QPen(quartileMarkerColor, 2.0));
updatePosition();
}
void StatsView::QuartileMarker::updatePosition()
{
if (!xAxis || !yAxis)
return;
double x = xAxis->toScreen(pos);
double y = yAxis->toScreen(value);
item->setLine(x - quartileMarkerSize / 2.0, y,
x + quartileMarkerSize / 2.0, y);
}
StatsView::RegressionLine::RegressionLine(const struct regression_data reg, QBrush brush, QGraphicsScene *scene, StatsAxis *xAxis, StatsAxis *yAxis) :
item(createItemPtr<QGraphicsPolygonItem>(scene)),
central(createItemPtr<QGraphicsPolygonItem>(scene)),
xAxis(xAxis), yAxis(yAxis),
reg(reg)
{
item->setZValue(ZValues::chartFeatures);
item->setPen(Qt::NoPen);
item->setBrush(brush);
central->setZValue(ZValues::chartFeatures+1);
central->setPen(QPen(Qt::red));
}
void StatsView::RegressionLine::updatePosition()
{
if (!xAxis || !yAxis)
return;
auto [minX, maxX] = xAxis->minMax();
auto [minY, maxY] = yAxis->minMax();
QPolygonF line;
line << QPoint(xAxis->toScreen(minX), yAxis->toScreen(reg.a * minX + reg.b))
<< QPoint(xAxis->toScreen(maxX), yAxis->toScreen(reg.a * maxX + reg.b));
// Draw the confidence interval according to http://www2.stat.duke.edu/~tjl13/s101/slides/unit6lec3H.pdf p.5 with t*=2 for 95% confidence
QPolygonF poly;
for (double x = minX; x <= maxX + 1; x += (maxX - minX) / 100)
poly << QPointF(xAxis->toScreen(x),
yAxis->toScreen(reg.a * x + reg.b + 2.0 * sqrt(reg.res2 / (reg.n - 2) * (1.0 / reg.n + (x - reg.xavg) * (x - reg.xavg) / (reg.n - 1) * (reg.n -2) / reg.sx2))));
for (double x = maxX; x >= minX - 1; x -= (maxX - minX) / 100)
poly << QPointF(xAxis->toScreen(x),
yAxis->toScreen(reg.a * x + reg.b - 2.0 * sqrt(reg.res2 / (reg.n - 2) * (1.0 / reg.n + (x - reg.xavg) * (x - reg.xavg) / (reg.n - 1) * (reg.n -2) / reg.sx2))));
QRectF box(QPoint(xAxis->toScreen(minX), yAxis->toScreen(minY)), QPoint(xAxis->toScreen(maxX), yAxis->toScreen(maxY)));
item->setPolygon(poly.intersected(box));
central->setPolygon(line.intersected(box));
}
StatsView::HistogramMarker::HistogramMarker(double val, bool horizontal, QPen pen, QGraphicsScene *scene, StatsAxis *xAxis, StatsAxis *yAxis) :
item(createItemPtr<QGraphicsLineItem>(scene)),
xAxis(xAxis), yAxis(yAxis),
val(val), horizontal(horizontal)
{
item->setZValue(ZValues::chartFeatures);
item->setPen(pen);
}
void StatsView::HistogramMarker::updatePosition()
{
if (!xAxis || !yAxis)
return;
if (horizontal) {
double y = yAxis->toScreen(val);
auto [x1, x2] = xAxis->minMaxScreen();
item->setLine(x1, y, x2, y);
} else {
double x = xAxis->toScreen(val);
auto [y1, y2] = yAxis->minMaxScreen();
item->setLine(x, y1, x, y2);
}
}
void StatsView::addHistogramMarker(double pos, const QPen &pen, bool isHorizontal, StatsAxis *xAxis, StatsAxis *yAxis)
{
histogramMarkers.emplace_back(pos, isHorizontal, pen, &scene, xAxis, yAxis);
}
void StatsView::addLinearRegression(const struct regression_data reg, StatsAxis *xAxis, StatsAxis *yAxis)
{
QColor red = QColor(Qt::red);
red.setAlphaF(reg.r2);
QPen pen(red);
QBrush brush(red);
brush.setStyle(Qt::SolidPattern);
regressionLines.emplace_back(reg, brush, &scene, xAxis, yAxis);
}
// Yikes, we get our data in different kinds of (bin, value) pairs.
// To create a category axis from this, we have to templatify the function.
template<typename T>
HistogramAxis *StatsView::createHistogramAxis(const QString &name, const StatsBinner &binner,
const std::vector<T> &bins, bool isHorizontal)
{
std::vector<HistogramAxisEntry> labels;
for (auto const &[bin, dummy]: bins) {
QString label = binner.formatLowerBound(*bin);
double lowerBound = binner.lowerBoundToFloat(*bin);
bool prefer = binner.preferBin(*bin);
labels.push_back({ label, lowerBound, prefer });
}
const StatsBin &lastBin = *bins.back().bin;
QString lastLabel = binner.formatUpperBound(lastBin);
double upperBound = binner.upperBoundToFloat(lastBin);
labels.push_back({ lastLabel, upperBound, false });
return createAxis<HistogramAxis>(name, std::move(labels), isHorizontal);
}
void StatsView::plotHistogramCountChart(const std::vector<dive *> &dives,
ChartSubType subType,
const StatsVariable *categoryVariable, const StatsBinner *categoryBinner,
bool labels, bool showMedian, bool showMean)
{
if (!categoryBinner)
return;
setTitle(categoryVariable->name());
std::vector<StatsBinCount> categoryBins = categoryBinner->count_dives(dives, true);
// If there is nothing to display, quit
if (categoryBins.empty())
return;
bool isHorizontal = subType == ChartSubType::Horizontal;
HistogramAxis *catAxis = createHistogramAxis(categoryVariable->nameWithBinnerUnit(*categoryBinner),
*categoryBinner, categoryBins, !isHorizontal);
int maxCategoryCount = getMaxCount(categoryBins);
int total = getTotalCount(categoryBins);
StatsAxis *valAxis = createCountAxis(maxCategoryCount, isHorizontal);
if (isHorizontal)
setAxes(valAxis, catAxis);
else
setAxes(catAxis, valAxis);
std::vector<BarSeries::CountItem> items;
items.reserve(categoryBins.size());
for (auto const &[bin, count]: categoryBins) {
double lowerBound = categoryBinner->lowerBoundToFloat(*bin);
double upperBound = categoryBinner->upperBoundToFloat(*bin);
std::vector<QString> label = labels ? makePercentageLabels(count, total, isHorizontal)
: std::vector<QString>();
items.push_back({ lowerBound, upperBound, count, label,
categoryBinner->formatWithUnit(*bin), total });
}
createSeries<BarSeries>(isHorizontal, categoryVariable->name(), items);
if (categoryVariable->type() == StatsVariable::Type::Numeric) {
if (showMean) {
double mean = categoryVariable->mean(dives);
QPen meanPen(Qt::green);
meanPen.setWidth(2);
if (!std::isnan(mean))
addHistogramMarker(mean, meanPen, isHorizontal, xAxis, yAxis);
}
if (showMedian) {
double median = categoryVariable->quartiles(dives).q2;
QPen medianPen(Qt::red);
medianPen.setWidth(2);
if (!std::isnan(median))
addHistogramMarker(median, medianPen, isHorizontal, xAxis, yAxis);
}
}
}
void StatsView::plotHistogramValueChart(const std::vector<dive *> &dives,
ChartSubType subType,
const StatsVariable *categoryVariable, const StatsBinner *categoryBinner,
const StatsVariable *valueVariable, StatsOperation valueAxisOperation,
bool labels)
{
if (!categoryBinner)
return;
setTitle(QStringLiteral("%1 (%2)").arg(valueVariable->name(), StatsVariable::operationName(valueAxisOperation)));
std::vector<StatsBinOp> categoryBins = valueVariable->bin_operations(*categoryBinner, dives, true);
// If there is nothing to display, quit
if (categoryBins.empty())
return;
bool isHorizontal = subType == ChartSubType::Horizontal;
HistogramAxis *catAxis = createHistogramAxis(categoryVariable->nameWithBinnerUnit(*categoryBinner),
*categoryBinner, categoryBins, !isHorizontal);
const auto [minValue, maxValue] = getMinMaxValue(categoryBins, valueAxisOperation);
int decimals = valueVariable->decimals();
ValueAxis *valAxis = createAxis<ValueAxis>(valueVariable->nameWithUnit(),
0.0, maxValue, decimals, isHorizontal);
if (isHorizontal)
setAxes(valAxis, catAxis);
else
setAxes(catAxis, valAxis);
std::vector<BarSeries::ValueItem> items;
items.reserve(categoryBins.size());
QString unit = valueVariable->unitSymbol();
for (auto const &[bin, res]: categoryBins) {
if (!res.isValid())
continue;
double height = res.get(valueAxisOperation);
double lowerBound = categoryBinner->lowerBoundToFloat(*bin);
double upperBound = categoryBinner->upperBoundToFloat(*bin);
QString value = QString("%L1").arg(height, 0, 'f', decimals);
std::vector<QString> label = labels ? std::vector<QString> { value }
: std::vector<QString>();
items.push_back({ lowerBound, upperBound, height, label,
categoryBinner->formatWithUnit(*bin), res });
}
createSeries<BarSeries>(isHorizontal, categoryVariable->name(), valueVariable, items);
}
void StatsView::plotHistogramStackedChart(const std::vector<dive *> &dives,
ChartSubType subType,
const StatsVariable *categoryVariable, const StatsBinner *categoryBinner,
const StatsVariable *valueVariable, const StatsBinner *valueBinner, bool labels, bool showLegend)
{
if (!categoryBinner || !valueBinner)
return;
setTitle(valueVariable->nameWithBinnerUnit(*valueBinner));
std::vector<StatsBinDives> categoryBins = categoryBinner->bin_dives(dives, true);
// Construct the histogram axis now, because the pointers to the bins
// will be moved away when constructing BarPlotData below.
bool isHorizontal = subType == ChartSubType::HorizontalStacked;
HistogramAxis *catAxis = createHistogramAxis(categoryVariable->nameWithBinnerUnit(*categoryBinner),
*categoryBinner, categoryBins, !isHorizontal);
BarPlotData data(categoryBins, *valueBinner);
if (showLegend)
legend = createItemPtr<Legend>(&scene, data.vbinNames);
CountAxis *valAxis = createCountAxis(data.maxCategoryCount, isHorizontal);
if (isHorizontal)
setAxes(valAxis, catAxis);
else
setAxes(catAxis, valAxis);
std::vector<BarSeries::MultiItem> items;
items.reserve(data.hbin_counts.size());
for (auto &[hbin, counts, total]: data.hbin_counts) {
double lowerBound = categoryBinner->lowerBoundToFloat(*hbin);
double upperBound = categoryBinner->upperBoundToFloat(*hbin);
items.push_back({ lowerBound, upperBound, makeCountLabels(counts, total, labels, isHorizontal),
categoryBinner->formatWithUnit(*hbin) });
}
createSeries<BarSeries>(isHorizontal, true, categoryVariable->name(), valueVariable, std::move(data.vbinNames), items);
}
void StatsView::plotHistogramBoxChart(const std::vector<dive *> &dives,
const StatsVariable *categoryVariable, const StatsBinner *categoryBinner,
const StatsVariable *valueVariable)
{
if (!categoryBinner)
return;
setTitle(valueVariable->name());
std::vector<StatsBinQuartiles> categoryBins = valueVariable->bin_quartiles(*categoryBinner, dives, true);
// If there is nothing to display, quit
if (categoryBins.empty())
return;
HistogramAxis *catAxis = createHistogramAxis(categoryVariable->nameWithBinnerUnit(*categoryBinner),
*categoryBinner, categoryBins, true);
auto [minY, maxY] = getMinMaxValue(categoryBins);
ValueAxis *valueAxis = createAxis<ValueAxis>(valueVariable->nameWithUnit(),
minY, maxY, valueVariable->decimals(), false);
setAxes(catAxis, valueAxis);
BoxSeries *series = createSeries<BoxSeries>(valueVariable->name(), valueVariable->unitSymbol(), valueVariable->decimals());
for (auto &[bin, q]: categoryBins) {
if (!q.isValid())
continue;
double lowerBound = categoryBinner->lowerBoundToFloat(*bin);
double upperBound = categoryBinner->upperBoundToFloat(*bin);
series->append(lowerBound, upperBound, q, categoryBinner->formatWithUnit(*bin));
}
}
static bool is_linear_regression(int sample_size, double cov, double sx2, double sy2)
{
// One point never, two points always form a line
if (sample_size < 2)
return false;
if (sample_size <= 2)
return true;
const double tval[] = { 12.709, 4.303, 3.182, 2.776, 2.571, 2.447, 2.201, 2.120, 2.080, 2.056, 2.021, 1.960, 1.960 };
const int t_df[] = { 1, 2, 3, 4, 5, 6, 11, 16, 21, 26, 40, 100, 100000 };
int df = sample_size - 2; // Following is the one-tailed t-value at p < 0.05 and [sample_size - 2] degrees of freedom for the dive data:
double t = (cov / sx2) / sqrt(((sy2 - cov * cov / sx2) / (double)df) / sx2);
for (int i = std::size(tval) - 2; i >= 0; i--) { // We do linear interpolation rather than having a large lookup table.
if (df >= t_df[i]) { // Look up the appropriate reference t-value at p < 0.05 and df degrees of freedom
double t_lookup = tval[i] - (tval[i] - tval[i+1]) * (df - t_df[i]) / (t_df[i+1] - t_df[i]);
return abs(t) >= t_lookup;
}
}
return true; // can't happen, as we tested for sample_size above.
}
// Returns the coefficients a,b of the line y = ax + b
// as well as the variance of the residuals (averaged residual squared) as res2
// and r^2 = 1.0 - variance of data / res2 which is the fraction of the variance of
// the data that is explained by the linear regression.
// If case of an undetermined regression or one with infinite slope, returns {nan, nan, 0.0, 0.0}
static struct regression_data linear_regression(const std::vector<StatsScatterItem> &v)
{
struct regression_data ret = { .a = NaN, .b = NaN, .res2 = 0.0, .r2 = 0.0, .sx2 = 0.0, .xavg = 0.0};
ret.n = v.size();
if (ret.n < 2)
return ret;
// First, calculate the x and y average
double avg_x = 0.0, avg_y = 0.0;
for (auto [x, y, d]: v) {
avg_x += x;
avg_y += y;
}
avg_x /= ret.n;
avg_y /= ret.n;
double cov = 0.0, sx2 = 0.0, sy2 = 0.0;
for (auto [x, y, d]: v) {
cov += (x - avg_x) * (y - avg_y);
sx2 += (x - avg_x) * (x - avg_x);
sy2 += (y - avg_y) * (y - avg_y);
}
bool is_linear = is_linear_regression((int)v.size(), cov, sx2, sy2);
if (fabs(sx2) < 1e-10 || !is_linear) // If t is not statistically significant, do not plot the regression line.
return ret;
ret.xavg = avg_x;
ret.sx2 = sx2;
ret.a = cov / sx2;
ret.b = avg_y - ret.a * avg_x;
for (auto [x, y, d]: v)
ret.res2 += (y - ret.a * x - ret.b) * (y - ret.a * x - ret.b);
ret.r2 = sy2 > 0.0 ? 1.0 - ret.res2 / sy2 : 1.0;
return ret;
}
void StatsView::plotScatter(const std::vector<dive *> &dives, const StatsVariable *categoryVariable, const StatsVariable *valueVariable)
{
setTitle(StatsTranslations::tr("%1 vs. %2").arg(valueVariable->name(), categoryVariable->name()));
std::vector<StatsScatterItem> points = categoryVariable->scatter(*valueVariable, dives);
if (points.empty())
return;
double minX = points.front().x;
double maxX = points.back().x;
auto [minY, maxY] = getMinMaxValue(points);
StatsAxis *axisX = categoryVariable->type() == StatsVariable::Type::Continuous ?
static_cast<StatsAxis *>(createAxis<DateAxis>(categoryVariable->nameWithUnit(),
minX, maxX, true)) :
static_cast<StatsAxis *>(createAxis<ValueAxis>(categoryVariable->nameWithUnit(),
minX, maxX, categoryVariable->decimals(), true));
StatsAxis *axisY = createAxis<ValueAxis>(valueVariable->nameWithUnit(), minY, maxY, valueVariable->decimals(), false);
setAxes(axisX, axisY);
ScatterSeries *series = createSeries<ScatterSeries>(*categoryVariable, *valueVariable);
for (auto [x, y, dive]: points)
series->append(dive, x, y);
// y = ax + b
struct regression_data reg = linear_regression(points);
if (!std::isnan(reg.a))
addLinearRegression(reg, xAxis, yAxis);
}