// SPDX-License-Identifier: GPL-2.0
#include "statsaxis.h"
#include "statstranslations.h"
#include "statsvariables.h"
#include "core/pref.h"
#include "core/subsurface-time.h"
#include <math.h> // for lrint
#include <numeric>
#include <QChart>
#include <QFontMetrics>
#include <QLocale>
StatsAxis::StatsAxis(QtCharts::QChart *chart, bool horizontal) : chart(chart), horizontal(horizontal)
{
}
StatsAxis::~StatsAxis()
{
}
std::pair<double, double> StatsAxis::minMax() const
{
return { 0.0, 1.0 };
}
// Guess the number of tick marks based on example strings.
// We will use minimum and maximum values, which are not necessarily the
// maximum-size strings especially, when using proportional fonts or for
// categorical data. Therefore, try to err on the safe side by adding enough
// margins.
int StatsAxis::guessNumTicks(const QtCharts::QAbstractAxis *axis, const std::vector<QString> &strings) const
{
QFont font = axis->labelsFont();
QFontMetrics fm(font);
int minSize = fm.height();
for (const QString &s: strings) {
QSize size = fm.size(Qt::TextSingleLine, s);
int needed = horizontal ? size.width() : size.height();
if (needed > minSize)
minSize = needed;
}
// Add space between labels
if (horizontal)
minSize = minSize * 3 / 2;
else
minSize *= 2;
QRectF chartSize = chart->plotArea();
double availableSpace = horizontal ? chartSize.width() : chartSize.height();
int numTicks = lrint(availableSpace / minSize);
return std::max(numTicks, 2);
}
ValueAxis::ValueAxis(QtCharts::QChart *chart, double min, double max, int decimals, bool horizontal) :
StatsAxisTemplate(chart, horizontal),
min(min), max(max), decimals(decimals)
{
}
std::pair<double, double> ValueAxis::minMax() const
{
return { QValueAxis::min(), QValueAxis::max() };
}
static QString makeFormatString(int decimals)
{
return QStringLiteral("%.%1f").arg(decimals < 0 ? 0 : decimals);
}
void ValueAxis::updateLabels()
{
using QtCharts::QValueAxis;
// Avoid degenerate cases
if (max - min < 0.0001) {
max += 0.5;
min -= 0.5;
}
QLocale loc;
QString minString = loc.toString(min, 'f', decimals);
QString maxString = loc.toString(max, 'f', decimals);
int numTicks = guessNumTicks(this, { minString, maxString});
// Use full decimal increments
double height = max - min;
double inc = height / numTicks;
double digits = floor(log10(inc));
int digits_int = lrint(digits);
double digits_factor = pow(10.0, digits);
int inc_int = std::max((int)ceil(inc / digits_factor), 1);
// Do "nice" increments of the leading digit: 1, 2, 4, 5.
if (inc_int > 5)
inc_int = 10;
if (inc_int == 3)
inc_int = 4;
inc = inc_int * digits_factor;
if (-digits_int > decimals)
decimals = -digits_int;
setLabelFormat(makeFormatString(decimals));
double actMin = floor(min / inc) * inc;
double actMax = ceil(max / inc) * inc;
int num = lrint((actMax - actMin) / inc);
setRange(actMin, actMax);
setTickCount(num + 1);
}
CountAxis::CountAxis(QtCharts::QChart *chart, int count, bool horizontal) :
ValueAxis(chart, 0.0, (double)count, 0, horizontal),
count(count)
{
}
void CountAxis::updateLabels()
{
QLocale loc;
QString countString = loc.toString(count);
int numTicks = guessNumTicks(this, { countString });
// Get estimate of step size
if (count <= 0)
count = 1;
// When determining the step size, make sure to round up
int step = (count + numTicks - 1) / numTicks;
if (step <= 0)
step = 1;
// Get the significant first or first two digits
int scale = 1;
int significant = step;
while (significant > 25) {
significant /= 10;
scale *= 10;
}
for (int increment: { 1, 2, 4, 5, 10, 15, 20, 25 }) {
if (increment >= significant) {
significant = increment;
break;
}
}
step = significant * scale;
// Make maximum an integer number of steps, equal or greater than the needed counts
int num = (count - 1) / step + 1;
int max = num * step;
numTicks = num + 1; // There is one more tick than steps
setLabelFormat("%.0f");
setRange(0, max);
setTickCount(numTicks);
}
CategoryAxis::CategoryAxis(QtCharts::QChart *chart, const std::vector<QString> &labels, bool horizontal) :
StatsAxisTemplate(chart, horizontal)
{
for (const QString &s: labels)
append(s);
}
void CategoryAxis::updateLabels()
{
}
// A small helper class that makes strings unique. We need this,
// because QCategoryAxis can only handle unique category names.
// Disambiguate strings by adding unicode zero-width spaces.
// Keep track of a list of strings and how many spaces have to
// be added.
class LabelDisambiguator {
using Pair = std::pair<QString, int>;
std::vector<Pair> entries;
public:
QString transmogrify(const QString &s);
};
QString LabelDisambiguator::transmogrify(const QString &s)
{
auto it = std::find_if(entries.begin(), entries.end(),
[&s](const Pair &p) { return p.first == s; });
if (it == entries.end()) {
entries.emplace_back(s, 0);
return s;
} else {
++(it->second);
return s + QString(it->second, QChar(0x200b));
}
}
HistogramAxis::HistogramAxis(QtCharts::QChart *chart, std::vector<HistogramAxisEntry> bins, bool horizontal) :
StatsAxisTemplate(chart, horizontal),
bin_values(std::move(bins))
{
if (bin_values.size() < 2) // Less than two makes no sense -> there must be at least one category
return;
LabelDisambiguator labeler;
for (HistogramAxisEntry &entry: bin_values)
entry.name = labeler.transmogrify(entry.name);
// The caller can declare some bin labels as preferred, when there are
// too many labels to show all. Try to infer the preferred step size
// by finding two consecutive preferred labels. This supposes that
// the preferred labels are equi-distant and that the caller does not
// use large prime (or nearly prime) steps.
auto it1 = std::find_if(bin_values.begin(), bin_values.end(),
[](const HistogramAxisEntry &e) { return e.recommended; });
auto next_it = it1 == bin_values.end() ? it1 : std::next(it1);
auto it2 = std::find_if(next_it, bin_values.end(),
[](const HistogramAxisEntry &e) { return e.recommended; });
preferred_step = it2 == bin_values.end() ? 1 : it2 - it1;
setMin(bin_values.front().value);
setMax(bin_values.back().value);
setStartValue(bin_values.front().value);
setLabelsPosition(QCategoryAxis::AxisLabelsPositionOnValue);
}
std::pair<double, double> HistogramAxis::minMax() const
{
if (bin_values.size() < 2) // Less than two makes no sense -> there must be at least one category
return { 0.0, 1.0 };
return { QValueAxis::min(), QValueAxis::max() };
}
// Initialize a histogram axis with the given labels. Labels are specified as (name, value, recommended) triplets.
// If labels are skipped, try to skip it in such a way that a recommended label is shown.
// The one example where this is relevant is the quarterly bins, which are formated as (2019, q1, q2, q3, 2020, ...).
// There, we obviously want to show the years and not the quarters.
void HistogramAxis::updateLabels()
{
if (bin_values.size() < 2) // Less than two makes no sense -> there must be at least one category
return;
// There is no clear all labels function in QCategoryAxis!? You must be kidding.
for (const QString &label: categoriesLabels())
remove(label);
if (count() > 0)
qWarning("HistogramAxis::updateLabels(): labels left after clearing!?");
std::vector<QString> strings;
strings.reserve(bin_values.size());
for (auto &[name, value, recommended]: bin_values)
strings.push_back(name);
int maxLabels = guessNumTicks(this, strings);
int step = ((int)bin_values.size() - 1) / maxLabels + 1;
if (step < preferred_step) {
if (step * 2 > preferred_step) {
step = preferred_step;
} else {
int gcd = std::gcd(step, preferred_step);
while (preferred_step % step != 0)
step += gcd;
}
} else if (step > preferred_step) {
int remainder = (step + preferred_step) % preferred_step;
if (remainder != 0)
step = step + preferred_step - remainder;
}
int first = 0;
if (step > 1) {
for (int i = 0; i < (int)bin_values.size(); ++i) {
const auto &[name, value, recommended] = bin_values[i];
if (recommended) {
first = i % step;
break;
}
}
}
for (int i = first; i < (int)bin_values.size(); i += step) {
const auto &[name, value, recommended] = bin_values[i];
append(name, value);
}
}
// Helper function to turn days since "Unix epoch" into a timestamp_t
static const double seconds_in_day = 86400.0;
static timestamp_t double_to_timestamp(double d)
{
return timestamp_t{ lrint(d * seconds_in_day) };
}
// Turn double to (year, month) pair
static std::pair<int, int> double_to_month(double d)
{
struct tm tm;
utc_mkdate(double_to_timestamp(d), &tm);
return { tm.tm_year, tm.tm_mon };
}
// Increase (year, month) pair by one month
static void inc(std::pair<int, int> &ym)
{
if (++ym.second >= 12) {
++ym.first;
ym.second = 0;
}
}
static std::array<int, 3> double_to_day(double d)
{
struct tm tm;
utc_mkdate(double_to_timestamp(d), &tm);
return { tm.tm_year, tm.tm_mon, tm.tm_mday };
}
// This is trashy: to increase a day, turn into timestamp and back.
// This surely can be done better.
static void inc(std::array<int, 3> &ymd)
{
struct tm tm = { 0 };
tm.tm_year = ymd[0];
tm.tm_mon = ymd[1];
tm.tm_mday = ymd[2] + 1;
timestamp_t t = utc_mktime(&tm);
utc_mkdate(t, &tm);
ymd = { tm.tm_year, tm.tm_mon, tm.tm_mday };
}
// Use heuristics to determine the preferred day/month format:
// Try to see whether day or month comes first and try to extract
// the separator character. Returns a (day_first, separator) pair.
static std::pair<bool, char> day_format()
{
const char *fmt = prefs.date_format;
const char *d, *m, *sep;
for (d = fmt; *d && *d != 'd' && *d != 'D'; ++d)
;
for (m = fmt; *m && *m != 'm' && *m != 'M'; ++m)
;
for(sep = std::min(m, d); *sep == 'm' || *sep == 'M' || *sep == 'd' || *sep == 'D'; ++sep)
;
return { d < m, *sep ? *sep : '.' };
}
// For now, misuse the histogram axis for creating a time axis. Depending on the range,
// create year, month or day-based bins. This is certainly not efficient and may need
// some tuning. However, it should ensure that no crazy number of bins is generated.
// Ultimately, this should be replaced by a better and dynamic scheme
// From and to are given in seconds since "epoch".
static std::vector<HistogramAxisEntry> timeRangeToBins(double from, double to)
{
// from and two are given in days since the "Unix epoch".
// The lowest precision we do is two days.
if (to - from < 2.0) {
double center = (from + to) / 2.0;
from = center + 1.0;
to = center - 1.0;
}
std::vector<HistogramAxisEntry> res;
if (to - from > 2.0 * 356.0) {
// For two years or more, do year based bins
int year_from = utc_year(double_to_timestamp(from));
int year_to = utc_year(double_to_timestamp(to)) + 1;
for (int year = year_from; year <= year_to; ++year)
res.push_back({ QString::number(year), date_to_double(year, 0, 0), true });
} else if (to - from > 2.0 * 30.0) {
// For two months or more, do month based bins
auto year_month_from = double_to_month(from);
auto year_month_to = double_to_month(to);
inc(year_month_to);
for (auto act = year_month_from; act <= year_month_to; inc(act)) {
double val = date_to_double(act.first, act.second, 0);
if (act.second == 0)
res.push_back({ QString::number(act.first), val, true });
else
res.push_back({ monthname(act.second), val, false });
}
} else {
// For less than two months, do date based bins
auto day_from = double_to_day(from);
auto day_to = double_to_day(to);
inc(day_to);
auto [day_before_month, separator] = day_format();
QString format = day_before_month ? QStringLiteral("%1%2%3")
: QStringLiteral("%3%2%1");
QString sep = QString(separator);
for (auto act = day_from; act < day_to; inc(act)) {
double val = date_to_double(act[0], act[1], act[2]);
if (act[1] == 0) {
res.push_back({ QString::number(act[0]), val, true });
} else if (act[2] == 0) {
res.push_back({ monthname(act[1]), val, true });
} else {
QString s = format.arg(QString::number(act[2]), sep, QString::number(act[1]));
res.push_back({s, val, true });
}
}
}
return res;
}
DateAxis::DateAxis(QtCharts::QChart *chart, double from, double to, bool horizontal) :
HistogramAxis(chart, timeRangeToBins(from, to), horizontal)
{
}