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Mac install_name_tool corrected to find dynamic libraries from correct place, if INSTALL_ROOT is used....
Mac install_name_tool corrected to find dynamic libraries from correct place, if INSTALL_ROOT is used. MAC: make install INSTALL_ROOT=<path_to_install_dir> failed, because install_name_tool expects the libraries to be in wrong place. Change-Id: I0025a0cb22b9c394694ece977053516c91028895 Reviewed-by: Sergio Ahumada <sergio.ahumada@digia.com> Reviewed-by: Miikka Heikkinen <miikka.heikkinen@digia.com>

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r2620:bcd8645639fe
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xlogydomain.cpp
241 lines | 7.5 KiB | text/x-c | CppLexer
/****************************************************************************
**
** Copyright (C) 2013 Digia Plc
** All rights reserved.
** For any questions to Digia, please use contact form at http://qt.digia.com
**
** This file is part of the Qt Enterprise Charts Add-on.
**
** $QT_BEGIN_LICENSE$
** Licensees holding valid Qt Enterprise licenses may use this file in
** accordance with the Qt Enterprise License Agreement provided with the
** Software or, alternatively, in accordance with the terms contained in
** a written agreement between you and Digia.
**
** If you have questions regarding the use of this file, please use
** contact form at http://qt.digia.com
** $QT_END_LICENSE$
**
****************************************************************************/
#include "xlogydomain_p.h"
#include "qabstractaxis_p.h"
#include "qlogvalueaxis.h"
#include <qmath.h>
QTCOMMERCIALCHART_BEGIN_NAMESPACE
XLogYDomain::XLogYDomain(QObject *parent)
: AbstractDomain(parent),
m_logLeftY(0),
m_logRightY(1),
m_logBaseY(10)
{
}
XLogYDomain::~XLogYDomain()
{
}
void XLogYDomain::setRange(qreal minX, qreal maxX, qreal minY, qreal maxY)
{
bool axisXChanged = false;
bool axisYChanged = false;
adjustLogDomainRanges(minY, maxY);
if (!qFuzzyIsNull(m_minX - minX) || !qFuzzyIsNull(m_maxX - maxX)) {
m_minX = minX;
m_maxX = maxX;
axisXChanged = true;
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 = log10(m_minY) / log10(m_logBaseY);
qreal logMaxY = log10(m_maxY) / 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 XLogYDomain::zoomIn(const QRectF &rect)
{
storeZoomReset();
qreal dx = spanX() / m_size.width();
qreal maxX = m_maxX;
qreal minX = m_minX;
maxX = minX + dx * rect.right();
minX = minX + dx * rect.left();
qreal logLeftY = m_logRightY - rect.bottom() * (m_logRightY - m_logLeftY) / m_size.height();
qreal logRightY = m_logRightY - rect.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 XLogYDomain::zoomOut(const QRectF &rect)
{
storeZoomReset();
qreal dx = spanX() / rect.width();
qreal maxX = m_maxX;
qreal minX = m_minX;
minX = maxX - dx * rect.right();
maxX = minX + dx * m_size.width();
const qreal factorY = m_size.height() / rect.height();
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 XLogYDomain::move(qreal dx, qreal dy)
{
qreal x = spanX() / m_size.width();
qreal maxX = m_maxX;
qreal minX = m_minX;
if (dx != 0) {
minX = minX + x * dx;
maxX = maxX + x * dx;
}
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 XLogYDomain::calculateGeometryPoint(const QPointF &point, bool &ok) const
{
const qreal deltaX = m_size.width() / (m_maxX - m_minX);
const qreal deltaY = m_size.height() / qAbs(m_logRightY - m_logLeftY);
qreal x = (point.x() - m_minX) * deltaX;
qreal y(0);
if (point.y() > 0) {
y = (log10(point.y()) / log10(m_logBaseY)) * -deltaY - m_logLeftY * -deltaY + m_size.height();
ok = true;
} else {
y = m_size.height();
qWarning() << "Logarithms of zero and negative values are undefined.";
ok = false;
}
return QPointF(x, y);
}
QVector<QPointF> XLogYDomain::calculateGeometryPoints(const QList<QPointF> &vector) const
{
const qreal deltaX = m_size.width() / (m_maxX - m_minX);
const qreal deltaY = m_size.height() / qAbs(m_logRightY - m_logLeftY);
QVector<QPointF> result;
result.resize(vector.count());
for (int i = 0; i < vector.count(); ++i) {
if (vector[i].y() > 0) {
qreal x = (vector[i].x() - m_minX) * deltaX;
qreal y = (log10(vector[i].y()) / log10(m_logBaseY)) * -deltaY - m_logLeftY * -deltaY + m_size.height();
result[i].setX(x);
result[i].setY(y);
} else {
qWarning() << "Logarithms of zero and negative values are undefined.";
return QVector<QPointF>();
}
}
return result;
}
QPointF XLogYDomain::calculateDomainPoint(const QPointF &point) const
{
const qreal deltaX = m_size.width() / (m_maxX - m_minX);
const qreal deltaY = m_size.height() / qAbs(m_logRightY - m_logLeftY);
qreal x = point.x() / deltaX + m_minX;
qreal y = qPow(m_logBaseY, m_logLeftY + (m_size.height() - point.y()) / deltaY);
return QPointF(x, y);
}
bool XLogYDomain::attachAxis(QAbstractAxis *axis)
{
QLogValueAxis *logAxis = qobject_cast<QLogValueAxis *>(axis);
if (logAxis && logAxis->orientation() == Qt::Vertical) {
QObject::connect(logAxis, SIGNAL(baseChanged(qreal)), this, SLOT(handleVerticalAxisBaseChanged(qreal)));
handleVerticalAxisBaseChanged(logAxis->base());
}
return AbstractDomain::attachAxis(axis);
}
bool XLogYDomain::detachAxis(QAbstractAxis *axis)
{
QLogValueAxis *logAxis = qobject_cast<QLogValueAxis *>(axis);
if (logAxis && logAxis->orientation() == Qt::Vertical)
QObject::disconnect(logAxis, SIGNAL(baseChanged(qreal)), this, SLOT(handleVerticalAxisBaseChanged(qreal)));
return AbstractDomain::detachAxis(axis);
}
void XLogYDomain::handleVerticalAxisBaseChanged(qreal baseY)
{
m_logBaseY = baseY;
qreal logMinY = log10(m_minY) / log10(m_logBaseY);
qreal logMaxY = log10(m_maxY) / log10(m_logBaseY);
m_logLeftY = logMinY < logMaxY ? logMinY : logMaxY;
m_logRightY = logMinY > logMaxY ? logMinY : logMaxY;
emit updated();
}
// operators
bool QTCOMMERCIALCHART_AUTOTEST_EXPORT operator== (const XLogYDomain &domain1, const XLogYDomain &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 QTCOMMERCIALCHART_AUTOTEST_EXPORT operator!= (const XLogYDomain &domain1, const XLogYDomain &domain2)
{
return !(domain1 == domain2);
}
QDebug QTCOMMERCIALCHART_AUTOTEST_EXPORT operator<<(QDebug dbg, const XLogYDomain &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_xlogydomain_p.cpp"
QTCOMMERCIALCHART_END_NAMESPACE