/**************************************************************************** ** ** Copyright (C) 2015 The Qt Company Ltd ** All rights reserved. ** For any questions to The Qt Company, please use contact form at http://qt.io ** ** This file is part of the Qt Charts module. ** ** Licensees holding valid commercial license for Qt may use this file in ** accordance with the Qt License Agreement provided with the Software ** or, alternatively, in accordance with the terms contained in a written ** agreement between you and The Qt Company. ** ** If you have questions regarding the use of this file, please use ** contact form at http://qt.io ** ****************************************************************************/ #include #include #include #include QT_CHARTS_BEGIN_NAMESPACE AbstractDomain::AbstractDomain(QObject *parent) : QObject(parent), m_minX(0), m_maxX(0), m_minY(0), m_maxY(0), m_signalsBlocked(false), m_zoomed(false), m_zoomResetMinX(0), m_zoomResetMaxX(0), m_zoomResetMinY(0), m_zoomResetMaxY(0) { } AbstractDomain::~AbstractDomain() { } void AbstractDomain::setSize(const QSizeF &size) { if (m_size != size) { m_size=size; emit updated(); } } QSizeF AbstractDomain::size() const { return m_size; } void AbstractDomain::setRangeX(qreal min, qreal max) { setRange(min, max, m_minY, m_maxY); } void AbstractDomain::setRangeY(qreal min, qreal max) { setRange(m_minX, m_maxX, min, max); } void AbstractDomain::setMinX(qreal min) { setRange(min, m_maxX, m_minY, m_maxY); } void AbstractDomain::setMaxX(qreal max) { setRange(m_minX, max, m_minY, m_maxY); } void AbstractDomain::setMinY(qreal min) { setRange(m_minX, m_maxX, min, m_maxY); } void AbstractDomain::setMaxY(qreal max) { setRange(m_minX, m_maxX, m_minY, max); } qreal AbstractDomain::spanX() const { Q_ASSERT(m_maxX >= m_minX); return m_maxX - m_minX; } qreal AbstractDomain::spanY() const { Q_ASSERT(m_maxY >= m_minY); return m_maxY - m_minY; } bool AbstractDomain::isEmpty() const { return qFuzzyCompare(spanX(), 0) || qFuzzyCompare(spanY(), 0) || m_size.isEmpty(); } QPointF AbstractDomain::calculateDomainPoint(const QPointF &point) const { const qreal deltaX = m_size.width() / (m_maxX - m_minX); const qreal deltaY = m_size.height() / (m_maxY - m_minY); qreal x = point.x() / deltaX + m_minX; qreal y = (point.y() - m_size.height()) / (-deltaY) + m_minY; return QPointF(x, y); } // handlers void AbstractDomain::handleVerticalAxisRangeChanged(qreal min, qreal max) { setRangeY(min, max); } void AbstractDomain::handleHorizontalAxisRangeChanged(qreal min, qreal max) { setRangeX(min, max); } void AbstractDomain::blockRangeSignals(bool block) { if (m_signalsBlocked!=block) { m_signalsBlocked=block; if (!block) { emit rangeHorizontalChanged(m_minX,m_maxX); emit rangeVerticalChanged(m_minY,m_maxY); } } } void AbstractDomain::zoomReset() { if (m_zoomed) { setRange(m_zoomResetMinX, m_zoomResetMaxX, m_zoomResetMinY, m_zoomResetMaxY); m_zoomed = false; } } void AbstractDomain::storeZoomReset() { if (!m_zoomed) { m_zoomed = true; m_zoomResetMinX = m_minX; m_zoomResetMaxX = m_maxX; m_zoomResetMinY = m_minY; m_zoomResetMaxY = m_maxY; } } //algorithm defined by Paul S.Heckbert GraphicalGems I void AbstractDomain::looseNiceNumbers(qreal &min, qreal &max, int &ticksCount) { qreal range = niceNumber(max - min, true); //range with ceiling qreal step = niceNumber(range / (ticksCount - 1), false); min = qFloor(min / step); max = qCeil(max / step); ticksCount = int(max - min) + 1; min *= step; max *= step; } //nice numbers can be expressed as form of 1*10^n, 2* 10^n or 5*10^n qreal AbstractDomain::niceNumber(qreal x, bool ceiling) { qreal z = qPow(10, qFloor(std::log10(x))); //find corresponding number of the form of 10^n than is smaller than x qreal q = x / z; //q<10 && q>=1; if (ceiling) { if (q <= 1.0) q = 1; else if (q <= 2.0) q = 2; else if (q <= 5.0) q = 5; else q = 10; } else { if (q < 1.5) q = 1; else if (q < 3.0) q = 2; else if (q < 7.0) q = 5; else q = 10; } return q * z; } bool AbstractDomain::attachAxis(QAbstractAxis *axis) { if (axis->orientation() == Qt::Vertical) { QObject::connect(axis->d_ptr.data(), SIGNAL(rangeChanged(qreal,qreal)), this, SLOT(handleVerticalAxisRangeChanged(qreal,qreal))); QObject::connect(this, SIGNAL(rangeVerticalChanged(qreal,qreal)), axis->d_ptr.data(), SLOT(handleRangeChanged(qreal,qreal))); } if (axis->orientation() == Qt::Horizontal) { QObject::connect(axis->d_ptr.data(), SIGNAL(rangeChanged(qreal,qreal)), this, SLOT(handleHorizontalAxisRangeChanged(qreal,qreal))); QObject::connect(this, SIGNAL(rangeHorizontalChanged(qreal,qreal)), axis->d_ptr.data(), SLOT(handleRangeChanged(qreal,qreal))); } return true; } bool AbstractDomain::detachAxis(QAbstractAxis *axis) { if (axis->orientation() == Qt::Vertical) { QObject::disconnect(axis->d_ptr.data(), SIGNAL(rangeChanged(qreal,qreal)), this, SLOT(handleVerticalAxisRangeChanged(qreal,qreal))); QObject::disconnect(this, SIGNAL(rangeVerticalChanged(qreal,qreal)), axis->d_ptr.data(), SLOT(handleRangeChanged(qreal,qreal))); } if (axis->orientation() == Qt::Horizontal) { QObject::disconnect(axis->d_ptr.data(), SIGNAL(rangeChanged(qreal,qreal)), this, SLOT(handleHorizontalAxisRangeChanged(qreal,qreal))); QObject::disconnect(this, SIGNAL(rangeHorizontalChanged(qreal,qreal)), axis->d_ptr.data(), SLOT(handleRangeChanged(qreal,qreal))); } return true; } // operators bool QT_CHARTS_AUTOTEST_EXPORT operator== (const AbstractDomain &domain1, const AbstractDomain &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 QT_CHARTS_AUTOTEST_EXPORT operator!= (const AbstractDomain &domain1, const AbstractDomain &domain2) { return !(domain1 == domain2); } QDebug QT_CHARTS_AUTOTEST_EXPORT operator<<(QDebug dbg, const AbstractDomain &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(); } // This function adjusts min/max ranges to failsafe values if negative/zero values are attempted. void AbstractDomain::adjustLogDomainRanges(qreal &min, qreal &max) { if (min <= 0) { min = 1.0; if (max <= min) max = min + 1.0; } } #include "moc_abstractdomain_p.cpp" QT_CHARTS_END_NAMESPACE