HG_REPOSITORIES/LPP/INSTRUMENTATION/USERS/JEANDET/qtcharts Files · src/domain/xlogydomain.cpp

Optimize polar chart radius calculation a bit....

Optimize polar chart radius calculation a bit. Current algorithm still results in an occasional extra unneeded iteration, as it uses only crude approximation for radius reduction. However, any speedup gained by accurately calculating needed reduction would be very minor compared to approximations used, so it doesn't seem worth the effort to figure out the complex math. Change-Id: If670a1b058a85cd0305b93f62e6388b463bafd0d Reviewed-by: Tomi Korpipää <tomi.korpipaa@digia.com>

Miikka Heikkinen - - Load All Authors

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r2483:f494279b6366


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             xlogydomain.cpp
        
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      /****************************************************************************

      **

      ** 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 Commercial Charts Add-on.

      **

      ** $QT_BEGIN_LICENSE$

      ** Licensees holding valid Qt Commercial licenses may use this file in

      ** accordance with the Qt Commercial 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)

      {

          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)

      {

          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

      {

          if (point.y() > 0) {

              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 = (log10(point.y()) / log10(m_logBaseY)) * -deltaY - m_logLeftY * -deltaY + m_size.height();

              ok = true;

              return QPointF(x, y);

          } else {

              qWarning() << "Logarithm of negative value is undefined. Empty layout returned.";

              ok = false;

              return QPointF();

          }

      }

      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() << "Logarithm of negative value is undefined. Empty layout returned.";

                  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)

      {

          dbg.nospace() << "AbstractDomain(" << domain.m_minX << ',' << domain.m_maxX << ',' << domain.m_minY << ',' << domain.m_maxY << ')' << domain.m_size;

          return dbg.maybeSpace();

      }

      #include "moc_xlogydomain_p.cpp"

      QTCOMMERCIALCHART_END_NAMESPACE

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				/****************************************************************************
				**
				** 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 Commercial Charts Add-on.
				**
				** $QT_BEGIN_LICENSE$
				** Licensees holding valid Qt Commercial licenses may use this file in
				** accordance with the Qt Commercial 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)
				{
				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)
				{
				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
				{
				if (point.y() > 0) {
				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 = (log10(point.y()) / log10(m_logBaseY)) * -deltaY - m_logLeftY * -deltaY + m_size.height();
				ok = true;
				return QPointF(x, y);
				} else {
				qWarning() << "Logarithm of negative value is undefined. Empty layout returned.";
				ok = false;
				return QPointF();
				}
				}

				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() << "Logarithm of negative value is undefined. Empty layout returned.";
				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)
				{
				dbg.nospace() << "AbstractDomain(" << domain.m_minX << ',' << domain.m_maxX << ',' << domain.m_minY << ',' << domain.m_maxY << ')' << domain.m_size;
				return dbg.maybeSpace();
				}

				#include "moc_xlogydomain_p.cpp"

				QTCOMMERCIALCHART_END_NAMESPACE