/**************************************************************************** ** ** Copyright (C) 2016 The Qt Company Ltd. ** Contact: https://www.qt.io/licensing/ ** ** This file is part of the Qt Charts module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:GPL$ ** Commercial License Usage ** Licensees holding valid commercial Qt licenses may use this file in ** accordance with the commercial license agreement provided with the ** Software or, alternatively, in accordance with the terms contained in ** a written agreement between you and The Qt Company. For licensing terms ** and conditions see https://www.qt.io/terms-conditions. For further ** information use the contact form at https://www.qt.io/contact-us. ** ** GNU General Public License Usage ** Alternatively, this file may be used under the terms of the GNU ** General Public License version 3 or (at your option) any later version ** approved by the KDE Free Qt Foundation. The licenses are as published by ** the Free Software Foundation and appearing in the file LICENSE.GPL3 ** included in the packaging of this file. Please review the following ** information to ensure the GNU General Public License requirements will ** be met: https://www.gnu.org/licenses/gpl-3.0.html. ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include #include #include #include #include QT_CHARTS_BEGIN_NAMESPACE LogXLogYDomain::LogXLogYDomain(QObject *parent) : AbstractDomain(parent), m_logLeftX(0), m_logRightX(1), m_logBaseX(10), m_logLeftY(0), m_logRightY(1), m_logBaseY(10) { } LogXLogYDomain::~LogXLogYDomain() { } void LogXLogYDomain::setRange(qreal minX, qreal maxX, qreal minY, qreal maxY) { bool axisXChanged = false; bool axisYChanged = false; adjustLogDomainRanges(minX, maxX); adjustLogDomainRanges(minY, maxY); if (!qFuzzyIsNull(m_minX - minX) || !qFuzzyIsNull(m_maxX - maxX)) { m_minX = minX; m_maxX = maxX; axisXChanged = true; qreal logMinX = std::log10(m_minX) / std::log10(m_logBaseX); qreal logMaxX = std::log10(m_maxX) / std::log10(m_logBaseX); m_logLeftX = logMinX < logMaxX ? logMinX : logMaxX; m_logRightX = logMinX > logMaxX ? logMinX : logMaxX; if(!m_signalsBlocked) emit rangeHorizontalChanged(m_minX, m_maxX); } if (!qFuzzyIsNull(m_minY - minY) || !qFuzzyIsNull(m_maxY - maxY)) { m_minY = minY; m_maxY = maxY; axisYChanged = true; qreal logMinY = std::log10(m_minY) / std::log10(m_logBaseY); qreal logMaxY = std::log10(m_maxY) / std::log10(m_logBaseY); m_logLeftY = logMinY < logMaxY ? logMinY : logMaxY; m_logRightY = logMinY > logMaxY ? logMinY : logMaxY; if (!m_signalsBlocked) emit rangeVerticalChanged(m_minY, m_maxY); } if (axisXChanged || axisYChanged) emit updated(); } void LogXLogYDomain::zoomIn(const QRectF &rect) { storeZoomReset(); QRectF fixedRect = fixZoomRect(rect); qreal logLeftX = fixedRect.left() * (m_logRightX - m_logLeftX) / m_size.width() + m_logLeftX; qreal logRightX = fixedRect.right() * (m_logRightX - m_logLeftX) / m_size.width() + m_logLeftX; qreal leftX = qPow(m_logBaseX, logLeftX); qreal rightX = qPow(m_logBaseX, logRightX); qreal minX = leftX < rightX ? leftX : rightX; qreal maxX = leftX > rightX ? leftX : rightX; qreal logLeftY = m_logRightY - fixedRect.bottom() * (m_logRightY - m_logLeftY) / m_size.height(); qreal logRightY = m_logRightY - fixedRect.top() * (m_logRightY - m_logLeftY) / m_size.height(); qreal leftY = qPow(m_logBaseY, logLeftY); qreal rightY = qPow(m_logBaseY, logRightY); qreal minY = leftY < rightY ? leftY : rightY; qreal maxY = leftY > rightY ? leftY : rightY; setRange(minX, maxX, minY, maxY); } void LogXLogYDomain::zoomOut(const QRectF &rect) { storeZoomReset(); QRectF fixedRect = fixZoomRect(rect); const qreal factorX = m_size.width() / fixedRect.width(); const qreal factorY = m_size.height() / fixedRect.height(); qreal logLeftX = m_logLeftX + (m_logRightX - m_logLeftX) / 2 * (1 - factorX); qreal logRIghtX = m_logLeftX + (m_logRightX - m_logLeftX) / 2 * (1 + factorX); qreal leftX = qPow(m_logBaseX, logLeftX); qreal rightX = qPow(m_logBaseX, logRIghtX); qreal minX = leftX < rightX ? leftX : rightX; qreal maxX = leftX > rightX ? leftX : rightX; qreal newLogMinY = m_logLeftY + (m_logRightY - m_logLeftY) / 2 * (1 - factorY); qreal newLogMaxY = m_logLeftY + (m_logRightY - m_logLeftY) / 2 * (1 + factorY); qreal leftY = qPow(m_logBaseY, newLogMinY); qreal rightY = qPow(m_logBaseY, newLogMaxY); qreal minY = leftY < rightY ? leftY : rightY; qreal maxY = leftY > rightY ? leftY : rightY; setRange(minX, maxX, minY, maxY); } void LogXLogYDomain::move(qreal dx, qreal dy) { if (m_reverseX) dx = -dx; if (m_reverseY) dy = -dy; qreal stepX = dx * qAbs(m_logRightX - m_logLeftX) / m_size.width(); qreal leftX = qPow(m_logBaseX, m_logLeftX + stepX); qreal rightX = qPow(m_logBaseX, m_logRightX + stepX); qreal minX = leftX < rightX ? leftX : rightX; qreal maxX = leftX > rightX ? leftX : rightX; qreal stepY = dy * (m_logRightY - m_logLeftY) / m_size.height(); qreal leftY = qPow(m_logBaseY, m_logLeftY + stepY); qreal rightY = qPow(m_logBaseY, m_logRightY + stepY); qreal minY = leftY < rightY ? leftY : rightY; qreal maxY = leftY > rightY ? leftY : rightY; setRange(minX, maxX, minY, maxY); } QPointF LogXLogYDomain::calculateGeometryPoint(const QPointF &point, bool &ok) const { const qreal deltaX = m_size.width() / qAbs(m_logRightX - m_logLeftX); const qreal deltaY = m_size.height() / qAbs(m_logRightY - m_logLeftY); qreal x(0); qreal y(0); if (point.x() > 0 && point.y() > 0) { x = ((std::log10(point.x()) / std::log10(m_logBaseX)) - m_logLeftX) * deltaX; y = ((std::log10(point.y()) / std::log10(m_logBaseY)) - m_logLeftY) * deltaY; ok = true; } else { qWarning() << "Logarithms of zero and negative values are undefined."; ok = false; if (point.x() > 0) x = ((std::log10(point.x()) / std::log10(m_logBaseX)) - m_logLeftX) * deltaX; else x = 0; if (point.y() > 0) y = ((std::log10(point.y()) / std::log10(m_logBaseY)) - m_logLeftY) * deltaY; else y = 0; } if (m_reverseX) x = m_size.width() - x; if (!m_reverseY) y = m_size.height() - y; return QPointF(x, y); } QVector LogXLogYDomain::calculateGeometryPoints(const QVector &vector) const { const qreal deltaX = m_size.width() / qAbs(m_logRightX - m_logLeftX); const qreal deltaY = m_size.height() / qAbs(m_logRightY - m_logLeftY); QVector result; result.resize(vector.count()); for (int i = 0; i < vector.count(); ++i) { if (vector[i].x() > 0 && vector[i].y() > 0) { qreal x = ((std::log10(vector[i].x()) / std::log10(m_logBaseX)) - m_logLeftX) * deltaX; if (m_reverseX) x = m_size.width() - x; qreal y = ((std::log10(vector[i].y()) / std::log10(m_logBaseY)) - m_logLeftY) * deltaY; if (!m_reverseY) y = m_size.height() - y; result[i].setX(x); result[i].setY(y); } else { qWarning() << "Logarithms of zero and negative values are undefined."; return QVector(); } } return result; } QPointF LogXLogYDomain::calculateDomainPoint(const QPointF &point) const { const qreal deltaX = m_size.width() / qAbs(m_logRightX - m_logLeftX); const qreal deltaY = m_size.height() / qAbs(m_logRightY - m_logLeftY); qreal x = m_reverseX ? (m_size.width() - point.x()) : point.x(); x = qPow(m_logBaseX, m_logLeftX + x / deltaX); qreal y = m_reverseY ? point.y() : (m_size.height() - point.y()); y = qPow(m_logBaseY, m_logLeftY + y / deltaY); return QPointF(x, y); } bool LogXLogYDomain::attachAxis(QAbstractAxis *axis) { AbstractDomain::attachAxis(axis); QLogValueAxis *logAxis = qobject_cast(axis); if (logAxis && logAxis->orientation() == Qt::Vertical) { QObject::connect(logAxis, SIGNAL(baseChanged(qreal)), this, SLOT(handleVerticalAxisBaseChanged(qreal))); handleVerticalAxisBaseChanged(logAxis->base()); } if (logAxis && logAxis->orientation() == Qt::Horizontal) { QObject::connect(logAxis, SIGNAL(baseChanged(qreal)), this, SLOT(handleHorizontalAxisBaseChanged(qreal))); handleHorizontalAxisBaseChanged(logAxis->base()); } return true; } bool LogXLogYDomain::detachAxis(QAbstractAxis *axis) { AbstractDomain::detachAxis(axis); QLogValueAxis *logAxis = qobject_cast(axis); if (logAxis && logAxis->orientation() == Qt::Vertical) QObject::disconnect(logAxis, SIGNAL(baseChanged(qreal)), this, SLOT(handleVerticalAxisBaseChanged(qreal))); if (logAxis && logAxis->orientation() == Qt::Horizontal) QObject::disconnect(logAxis, SIGNAL(baseChanged(qreal)), this, SLOT(handleHorizontalAxisBaseChanged(qreal))); return true; } void LogXLogYDomain::handleVerticalAxisBaseChanged(qreal baseY) { m_logBaseY = baseY; qreal logMinY = std::log10(m_minY) / std::log10(m_logBaseY); qreal logMaxY = std::log10(m_maxY) / std::log10(m_logBaseY); m_logLeftY = logMinY < logMaxY ? logMinY : logMaxY; m_logRightY = logMinY > logMaxY ? logMinY : logMaxY; emit updated(); } void LogXLogYDomain::handleHorizontalAxisBaseChanged(qreal baseX) { m_logBaseX = baseX; qreal logMinX = std::log10(m_minX) / std::log10(m_logBaseX); qreal logMaxX = std::log10(m_maxX) / std::log10(m_logBaseX); m_logLeftX = logMinX < logMaxX ? logMinX : logMaxX; m_logRightX = logMinX > logMaxX ? logMinX : logMaxX; emit updated(); } // operators bool Q_AUTOTEST_EXPORT operator== (const LogXLogYDomain &domain1, const LogXLogYDomain &domain2) { return (qFuzzyIsNull(domain1.m_maxX - domain2.m_maxX) && qFuzzyIsNull(domain1.m_maxY - domain2.m_maxY) && qFuzzyIsNull(domain1.m_minX - domain2.m_minX) && qFuzzyIsNull(domain1.m_minY - domain2.m_minY)); } bool Q_AUTOTEST_EXPORT operator!= (const LogXLogYDomain &domain1, const LogXLogYDomain &domain2) { return !(domain1 == domain2); } QDebug Q_AUTOTEST_EXPORT operator<<(QDebug dbg, const LogXLogYDomain &domain) { #ifdef QT_NO_TEXTSTREAM Q_UNUSED(domain) #else dbg.nospace() << "AbstractDomain(" << domain.m_minX << ',' << domain.m_maxX << ',' << domain.m_minY << ',' << domain.m_maxY << ')' << domain.m_size; #endif return dbg.maybeSpace(); } #include "moc_logxlogydomain_p.cpp" QT_CHARTS_END_NAMESPACE