/* Copyright (c) 2012-2016 Stanislaw Halik * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. */ #include "opentrack-compat/options.hpp" using namespace options; #include "spline-widget/qfunctionconfigurator.h" #include #include #include #include #include #include QFunctionConfigurator::QFunctionConfigurator(QWidget *parent) : QWidget(parent), _config(nullptr), moving_control_point_idx(-1), snap_x(0), snap_y(0), _draw_function(true), _preview_only(false) { update_range(); setMouseTracking(true); } void QFunctionConfigurator::setConfig(Map* config, const QString& name) { mem iniFile = group::ini_file(); if (name != "") config->loadSettings(*iniFile, name); _config = config; _draw_function = true; update_range(); update(); } void QFunctionConfigurator::set_preview_only(bool val) { _preview_only = val; } bool QFunctionConfigurator::is_preview_only() const { return _preview_only; } void QFunctionConfigurator::drawBackground() { if (!_config) return; _background = QPixmap(width(), height()); QPainter painter(&_background); painter.fillRect(rect(), QColor::fromRgb(204, 204, 204)); QColor bg_color(112, 154, 209); if (!isEnabled() && !_preview_only) bg_color = QColor(176,176,180); painter.fillRect(pixel_bounds, bg_color); QFont font; font.setPointSize(8); painter.setFont(font); QFontMetrics metrics(font); QColor color__(176, 190, 209, 127); if (!isEnabled()) color__ = QColor(70, 90, 100, 96); QPen pen(color__, 1, Qt::SolidLine); const int xstep = 10, ystep = 10; const qreal maxx = _config->maxInput() + ystep; const qreal maxy = _config->maxOutput() + xstep; // horizontal grid for (int i = 0; i < maxy; i += xstep) { const qreal y = pixel_bounds.height() - i * c.y() + pixel_bounds.y(); drawLine(&painter, QPointF(pixel_bounds.x(), y), QPointF(pixel_bounds.x() + pixel_bounds.width(), y), pen); painter.drawText(QRectF(10, y - metrics.height()/2, pixel_bounds.left(), metrics.height()), QString::number(i)); } // vertical grid for (int i = 0; i < maxx; i += ystep) { const qreal x = pixel_bounds.x() + i * c.x(); drawLine(&painter, QPointF(x, pixel_bounds.y()), QPointF(x, pixel_bounds.y() + pixel_bounds.height()), pen); const QString text = QString::number(i); painter.drawText(QRectF(x - metrics.width(text)/2, pixel_bounds.height() + 10 + metrics.height(), metrics.width(text), metrics.height()), text); } } void QFunctionConfigurator::drawFunction() { if (!_config) return; _function = _background; QPainter painter(&_function); painter.setRenderHint(QPainter::Antialiasing, true); QList points = _config->getPoints(); const int alpha = !isEnabled() ? 64 : 120; if (!_preview_only) { for (int i = 0; i < points.size(); i++) { drawPoint(&painter, point_to_pixel(points[i]), QColor(200, 200, 210, alpha), isEnabled() ? QColor(50, 100, 120, 200) : QColor(200, 200, 200, 96)); } } QColor color = spline_color; if (!isEnabled() && !_preview_only) { const int avg = int(float(color.red() + color.green() + color.blue())/3); color = QColor(int(float(color.red() + avg) * .5f), int(float(color.green() + avg) * .5f), int(float(color.blue() + avg) * .5f), 96); } QPen pen(color, 1.2, Qt::SolidLine); const qreal step_ = line_length_pixels / c.x(); const qreal step = std::max(1e-2, step_); const qreal max = _config->maxInput(); painter.save(); painter.setPen(pen); painter.setBrush(Qt::NoBrush); QPointF prev = point_to_pixel(QPointF(0, 0)); for (qreal i = 0; i < max; i += step) { const qreal val = qreal(_config->getValue(float(i))); QPointF cur = point_to_pixel(QPointF(i, val)); painter.drawLine(prev, cur); prev = cur; } { const qreal val = _config->getValue(float(max)); QPointF last = point_to_pixel(QPointF(max, val)); painter.drawLine(prev, last); } painter.restore(); } void QFunctionConfigurator::paintEvent(QPaintEvent *e) { QPainter p(this); if (_background.isNull()) { _draw_function = true; drawBackground(); } if (_draw_function) { _draw_function = false; drawFunction(); } p.drawPixmap(e->rect(), _function); if (_config) { QPen pen(Qt::white, 1, Qt::SolidLine); QList points = _config->getPoints(); if (points.size() && moving_control_point_idx >= 0 && moving_control_point_idx < points.size()) { if (points[0].x() > 1e-2) points.prepend(QPointF(0, 0)); QPointF prev = point_to_pixel(points[0]); for (int i = 1; i < points.size(); i++) { auto tmp = point_to_pixel(points[i]); drawLine(&p, prev, tmp, pen); prev = tmp; } } // If the Tracker is active, the 'Last Point' it requested is recorded. // Show that point on the graph, with some lines to assist. // This new feature is very handy for tweaking the curves! QPointF last; if (_config->getLastPoint(last) && isEnabled()) { QPointF pixel_pos = point_to_pixel(last); drawPoint(&p, pixel_pos, QColor(255, 0, 0, 120)); } } } void QFunctionConfigurator::drawPoint(QPainter *painter, const QPointF &pos, QColor colBG, QColor border) { painter->save(); painter->setPen(border); painter->setBrush( colBG ); painter->drawEllipse(QRectF(pos.x() - point_size, pos.y() - point_size, point_size*2, point_size*2)); painter->restore(); } void QFunctionConfigurator::drawLine(QPainter *painter, const QPointF &start, const QPointF &end, QPen &pen) { painter->save(); painter->setPen(pen); painter->setBrush(Qt::NoBrush); painter->drawLine(start, end); painter->restore(); } void QFunctionConfigurator::mousePressEvent(QMouseEvent *e) { if (!_config || !isEnabled()) return; QList points = _config->getPoints(); if (e->button() == Qt::LeftButton) { bool bTouchingPoint = false; moving_control_point_idx = -1; if (_config) { for (int i = 0; i < points.size(); i++) { if (point_within_pixel(points[i], e->pos())) { bTouchingPoint = true; moving_control_point_idx = i; break; } } if (!bTouchingPoint) { bool too_close = false; const auto pos = e->pos(); for (int i = 0; i < points.size(); i++) { const QPointF pt = point_to_pixel(points[i]); const auto x = pt.x() - pos.x(); if (point_closeness_limit * point_closeness_limit >= x * x) { too_close = true; break; } } if (!too_close) _config->addPoint(pixel_coord_to_point(e->pos())); } } } if (e->button() == Qt::RightButton) { if (_config) { int found_pt = -1; for (int i = 0; i < points.size(); i++) { if (point_within_pixel(points[i], e->pos())) { found_pt = i; break; } } if (found_pt != -1) { _config->removePoint(found_pt); } moving_control_point_idx = -1; } } _draw_function = true; update(); } void QFunctionConfigurator::mouseMoveEvent(QMouseEvent *e) { if (!_config || !isEnabled()) return; QList points = _config->getPoints(); if (moving_control_point_idx != -1 && moving_control_point_idx < points.size()) { setCursor(Qt::ClosedHandCursor); bool overlap = false; QPointF pix = e->pos(); QPointF new_pt = pixel_coord_to_point(pix); for (int i = 0; i < 2; i++) { bool bad = false; if (moving_control_point_idx + 1 < points.size()) { auto other = points[moving_control_point_idx+1]; auto other_pix = point_to_pixel(other); bad = pix.x() + point_closeness_limit > other_pix.x(); if (i == 0 && bad) { pix.setX(other_pix.x() - point_closeness_limit); new_pt = pixel_coord_to_point(pix); } else overlap |= bad; } if (moving_control_point_idx != 0) { auto other = points[moving_control_point_idx-1]; auto other_pix = point_to_pixel(other); bad = pix.x() - point_closeness_limit < other_pix.x(); if (i == 0 && bad) { pix.setX(other_pix.x() + point_closeness_limit); new_pt = pixel_coord_to_point(pix); } else overlap |= bad; } if (!bad) break; } if (!overlap) { points[moving_control_point_idx] = new_pt; _config->movePoint(moving_control_point_idx, new_pt); _draw_function = true; update(); } } else { bool is_on_point = false; for (int i = 0; i < points.size(); i++) { const QPoint pos = e->pos(); if (point_within_pixel(points[i], pos)) { is_on_point = true; break; } } if (is_on_point) { setCursor(Qt::CrossCursor); } else { setCursor(Qt::ArrowCursor); } } } void QFunctionConfigurator::mouseReleaseEvent(QMouseEvent *e) { if (!_config || !isEnabled()) return; if (e->button() == Qt::LeftButton) { mouseMoveEvent(e); setCursor(Qt::ArrowCursor); moving_control_point_idx = -1; _draw_function = true; update(); } } void QFunctionConfigurator::update_range() { if (!_config) return; const int w = width(), h = height(); const int mwl = 40, mhl = 20; const int mwr = 15, mhr = 35; pixel_bounds = QRectF(mwl, mhl, (w - mwl - mwr), (h - mhl - mhr)); c = QPointF(pixel_bounds.width() / _config->maxInput(), pixel_bounds.height() / _config->maxOutput()); _draw_function = true; _background = QPixmap(); _function = QPixmap(); update(); } bool QFunctionConfigurator::point_within_pixel(const QPointF &pt, const QPointF &pixel) { QPointF tmp = pixel - point_to_pixel(pt); return sqrt(QPointF::dotProduct(tmp, tmp)) < point_size; } QPointF QFunctionConfigurator::pixel_coord_to_point(const QPointF& point) { if (!_config) return QPointF(-1, -1); using std::round; qreal x = round((point.x() - pixel_bounds.x()) / c.x()); qreal y = round((pixel_bounds.height() - point.y() + pixel_bounds.y()) / c.y()); if (snap_x > 0) x -= int(x) % snap_x; if (snap_y > 0) y -= int(y) % snap_y; if (x < 0) x = 0; if (x > _config->maxInput()) x = _config->maxInput(); if (y < 0) y = 0; if (y > _config->maxOutput()) y = _config->maxOutput(); return QPointF(x, y); } QPointF QFunctionConfigurator::point_to_pixel(const QPointF& point) { return QPointF(pixel_bounds.x() + point.x() * c.x(), pixel_bounds.y() + pixel_bounds.height() - point.y() * c.y()); } void QFunctionConfigurator::resizeEvent(QResizeEvent *) { update_range(); }