/* -*- mode: C++ ; c-file-style: "stroustrup" -*- ***************************** * Qwt Widget Library * Copyright (C) 1997 Josef Wilgen * Copyright (C) 2002 Uwe Rathmann * * This library is free software; you can redistribute it and/or * modify it under the terms of the Qwt License, Version 1.0 *****************************************************************************/ #include "qwt_wheel.h" #include "qwt_math.h" #include "qwt_painter.h" #include #include #include #include #define NUM_COLORS 30 class QwtWheel::PrivateData { public: PrivateData() { viewAngle = 175.0; totalAngle = 360.0; tickCnt = 10; intBorder = 2; borderWidth = 2; wheelWidth = 20; }; QRect sliderRect; double viewAngle; double totalAngle; int tickCnt; int intBorder; int borderWidth; int wheelWidth; QColor colors[NUM_COLORS]; }; //! Constructor QwtWheel::QwtWheel( QWidget *parent ): QwtAbstractSlider( Qt::Horizontal, parent ) { initWheel(); } void QwtWheel::initWheel() { d_data = new PrivateData; setSizePolicy( QSizePolicy::Preferred, QSizePolicy::Fixed ); setAttribute( Qt::WA_WState_OwnSizePolicy, false ); setUpdateTime( 50 ); } //! Destructor QwtWheel::~QwtWheel() { delete d_data; } //! Set up the color array for the background pixmap. void QwtWheel::setColorArray() { if ( !d_data->colors ) return; const QColor light = palette().color( QPalette::Light ); const QColor dark = palette().color( QPalette::Dark ); if ( !d_data->colors[0].isValid() || d_data->colors[0] != light || d_data->colors[NUM_COLORS - 1] != dark ) { d_data->colors[0] = light; d_data->colors[NUM_COLORS - 1] = dark; int dh, ds, dv, lh, ls, lv; d_data->colors[0].getRgb( &lh, &ls, &lv ); d_data->colors[NUM_COLORS - 1].getRgb( &dh, &ds, &dv ); for ( int i = 1; i < NUM_COLORS - 1; ++i ) { const double factor = double( i ) / double( NUM_COLORS ); d_data->colors[i].setRgb( lh + int( double( dh - lh ) * factor ), ls + int( double( ds - ls ) * factor ), lv + int( double( dv - lv ) * factor ) ); } } } /*! \brief Adjust the number of grooves in the wheel's surface. The number of grooves is limited to 6 <= cnt <= 50. Values outside this range will be clipped. The default value is 10. \param cnt Number of grooves per 360 degrees \sa tickCnt() */ void QwtWheel::setTickCnt( int cnt ) { d_data->tickCnt = qwtLim( cnt, 6, 50 ); update(); } /*! \return Number of grooves in the wheel's surface. \sa setTickCnt() */ int QwtWheel::tickCnt() const { return d_data->tickCnt; } /*! \return mass */ double QwtWheel::mass() const { return QwtAbstractSlider::mass(); } /*! \brief Set the internal border width of the wheel. The internal border must not be smaller than 1 and is limited in dependence on the wheel's size. Values outside the allowed range will be clipped. The internal border defaults to 2. \param w border width \sa internalBorder() */ void QwtWheel::setInternalBorder( int w ) { const int d = qMin( width(), height() ) / 3; w = qMin( w, d ); d_data->intBorder = qMax( w, 1 ); layoutWheel(); } /*! \return Internal border width of the wheel. \sa setInternalBorder() */ int QwtWheel::internalBorder() const { return d_data->intBorder; } /*! Draw the Wheel's background gradient \param painter Painter \param r Bounding rectangle */ void QwtWheel::drawWheelBackground( QPainter *painter, const QRect &r ) { painter->save(); // // initialize pens // const QColor light = palette().color( QPalette::Light ); const QColor dark = palette().color( QPalette::Dark ); QPen lightPen; lightPen.setColor( light ); lightPen.setWidth( d_data->intBorder ); QPen darkPen; darkPen.setColor( dark ); darkPen.setWidth( d_data->intBorder ); setColorArray(); // // initialize auxiliary variables // const int nFields = NUM_COLORS * 13 / 10; const int hiPos = nFields - NUM_COLORS + 1; if ( orientation() == Qt::Horizontal ) { const int rx = r.x(); int ry = r.y() + d_data->intBorder; const int rh = r.height() - 2 * d_data->intBorder; const int rw = r.width(); // // draw shaded background // int x1 = rx; for ( int i = 1; i < nFields; i++ ) { const int x2 = rx + ( rw * i ) / nFields; painter->fillRect( x1, ry, x2 - x1 + 1 , rh, d_data->colors[qAbs( i-hiPos )] ); x1 = x2 + 1; } painter->fillRect( x1, ry, rw - ( x1 - rx ), rh, d_data->colors[NUM_COLORS - 1] ); // // draw internal border // painter->setPen( lightPen ); ry = r.y() + d_data->intBorder / 2; painter->drawLine( r.x(), ry, r.x() + r.width() , ry ); painter->setPen( darkPen ); ry = r.y() + r.height() - ( d_data->intBorder - d_data->intBorder / 2 ); painter->drawLine( r.x(), ry , r.x() + r.width(), ry ); } else // Qt::Vertical { int rx = r.x() + d_data->intBorder; const int ry = r.y(); const int rh = r.height(); const int rw = r.width() - 2 * d_data->intBorder; // // draw shaded background // int y1 = ry; for ( int i = 1; i < nFields; i++ ) { const int y2 = ry + ( rh * i ) / nFields; painter->fillRect( rx, y1, rw, y2 - y1 + 1, d_data->colors[qAbs( i-hiPos )] ); y1 = y2 + 1; } painter->fillRect( rx, y1, rw, rh - ( y1 - ry ), d_data->colors[NUM_COLORS - 1] ); // // draw internal borders // painter->setPen( lightPen ); rx = r.x() + d_data->intBorder / 2; painter->drawLine( rx, r.y(), rx, r.y() + r.height() ); painter->setPen( darkPen ); rx = r.x() + r.width() - ( d_data->intBorder - d_data->intBorder / 2 ); painter->drawLine( rx, r.y(), rx , r.y() + r.height() ); } painter->restore(); } /*! \brief Set the total angle which the wheel can be turned. One full turn of the wheel corresponds to an angle of 360 degrees. A total angle of n*360 degrees means that the wheel has to be turned n times around its axis to get from the minimum value to the maximum value. The default setting of the total angle is 360 degrees. \param angle total angle in degrees \sa totalAngle() */ void QwtWheel::setTotalAngle( double angle ) { if ( angle < 0.0 ) angle = 0.0; d_data->totalAngle = angle; update(); } /*! \return Total angle which the wheel can be turned. \sa setTotalAngle() */ double QwtWheel::totalAngle() const { return d_data->totalAngle; } /*! \brief Set the wheel's orientation. \param o Orientation. Allowed values are Qt::Horizontal and Qt::Vertical. Defaults to Qt::Horizontal. \sa QwtAbstractSlider::orientation() */ void QwtWheel::setOrientation( Qt::Orientation o ) { if ( orientation() == o ) return; if ( !testAttribute( Qt::WA_WState_OwnSizePolicy ) ) { QSizePolicy sp = sizePolicy(); sp.transpose(); setSizePolicy( sp ); setAttribute( Qt::WA_WState_OwnSizePolicy, false ); } QwtAbstractSlider::setOrientation( o ); layoutWheel(); } /*! \brief Specify the visible portion of the wheel. You may use this function for fine-tuning the appearance of the wheel. The default value is 175 degrees. The value is limited from 10 to 175 degrees. \param angle Visible angle in degrees \sa viewAngle(), setTotalAngle() */ void QwtWheel::setViewAngle( double angle ) { d_data->viewAngle = qwtLim( angle, 10.0, 175.0 ); update(); } /*! \return Visible portion of the wheel \sa setViewAngle(), totalAngle() */ double QwtWheel::viewAngle() const { return d_data->viewAngle; } /*! \brief Redraw the wheel \param painter painter \param r contents rectangle */ void QwtWheel::drawWheel( QPainter *painter, const QRect &r ) { // // draw background gradient // drawWheelBackground( painter, r ); if ( maxValue() == minValue() || d_data->totalAngle == 0.0 ) return; const QColor light = palette().color( QPalette::Light ); const QColor dark = palette().color( QPalette::Dark ); const double sign = ( minValue() < maxValue() ) ? 1.0 : -1.0; double cnvFactor = qAbs( d_data->totalAngle / ( maxValue() - minValue() ) ); const double halfIntv = 0.5 * d_data->viewAngle / cnvFactor; const double loValue = value() - halfIntv; const double hiValue = value() + halfIntv; const double tickWidth = 360.0 / double( d_data->tickCnt ) / cnvFactor; const double sinArc = qSin( d_data->viewAngle * M_PI / 360.0 ); cnvFactor *= M_PI / 180.0; // // draw grooves // if ( orientation() == Qt::Horizontal ) { const double halfSize = double( r.width() ) * 0.5; int l1 = r.y() + d_data->intBorder; int l2 = r.y() + r.height() - d_data->intBorder - 1; // draw one point over the border if border > 1 if ( d_data->intBorder > 1 ) { l1 --; l2 ++; } const int maxpos = r.x() + r.width() - 2; const int minpos = r.x() + 2; // // draw tick marks // for ( double tickValue = qCeil( loValue / tickWidth ) * tickWidth; tickValue < hiValue; tickValue += tickWidth ) { // // calculate position // const int tickPos = r.x() + r.width() - int( halfSize * ( sinArc + sign * qSin( ( tickValue - value() ) * cnvFactor ) ) / sinArc ); // // draw vertical line // if ( ( tickPos <= maxpos ) && ( tickPos > minpos ) ) { painter->setPen( dark ); painter->drawLine( tickPos - 1 , l1, tickPos - 1, l2 ); painter->setPen( light ); painter->drawLine( tickPos, l1, tickPos, l2 ); } } } else if ( orientation() == Qt::Vertical ) { const double halfSize = double( r.height() ) * 0.5; int l1 = r.x() + d_data->intBorder; int l2 = r.x() + r.width() - d_data->intBorder - 1; if ( d_data->intBorder > 1 ) { l1--; l2++; } const int maxpos = r.y() + r.height() - 2; const int minpos = r.y() + 2; // // draw tick marks // for ( double tickValue = qCeil( loValue / tickWidth ) * tickWidth; tickValue < hiValue; tickValue += tickWidth ) { // // calculate position // const int tickPos = r.y() + int( halfSize * ( sinArc + sign * qSin( ( tickValue - value() ) * cnvFactor ) ) / sinArc ); // // draw horizontal line // if ( ( tickPos <= maxpos ) && ( tickPos > minpos ) ) { painter->setPen( dark ); painter->drawLine( l1, tickPos - 1 , l2, tickPos - 1 ); painter->setPen( light ); painter->drawLine( l1, tickPos, l2, tickPos ); } } } } //! Determine the value corresponding to a specified point double QwtWheel::getValue( const QPoint &p ) { // The reference position is arbitrary, but the // sign of the offset is important int w, dx; if ( orientation() == Qt::Vertical ) { w = d_data->sliderRect.height(); dx = d_data->sliderRect.y() - p.y(); } else { w = d_data->sliderRect.width(); dx = p.x() - d_data->sliderRect.x(); } // w pixels is an arc of viewAngle degrees, // so we convert change in pixels to change in angle const double ang = dx * d_data->viewAngle / w; // value range maps to totalAngle degrees, // so convert the change in angle to a change in value const double val = ang * ( maxValue() - minValue() ) / d_data->totalAngle; // Note, range clamping and rasterizing to step is automatically // handled by QwtAbstractSlider, so we simply return the change in value return val; } //! Qt Resize Event void QwtWheel::resizeEvent( QResizeEvent * ) { layoutWheel( false ); } //! Recalculate the slider's geometry and layout based on // the current rect and fonts. // \param update_geometry notify the layout system and call update // to redraw the scale void QwtWheel::layoutWheel( bool update_geometry ) { const QRect r = this->rect(); d_data->sliderRect.setRect( r.x() + d_data->borderWidth, r.y() + d_data->borderWidth, r.width() - 2*d_data->borderWidth, r.height() - 2*d_data->borderWidth ); if ( update_geometry ) { updateGeometry(); update(); } } //! Qt Paint Event void QwtWheel::paintEvent( QPaintEvent *e ) { // Use double-buffering const QRect &ur = e->rect(); if ( ur.isValid() ) { QPainter painter( this ); draw( &painter, ur ); } } /*! Redraw panel and wheel \param painter Painter */ void QwtWheel::draw( QPainter *painter, const QRect& ) { qDrawShadePanel( painter, rect().x(), rect().y(), rect().width(), rect().height(), palette(), true, d_data->borderWidth ); drawWheel( painter, d_data->sliderRect ); if ( hasFocus() ) QwtPainter::drawFocusRect( painter, this ); } //! Notify value change void QwtWheel::valueChange() { QwtAbstractSlider::valueChange(); update(); } /*! \brief Determine the scrolling mode and direction corresponding to a specified point \param p point \param scrollMode scrolling mode \param direction direction */ void QwtWheel::getScrollMode( const QPoint &p, int &scrollMode, int &direction ) { if ( d_data->sliderRect.contains( p ) ) scrollMode = ScrMouse; else scrollMode = ScrNone; direction = 0; } /*! \brief Set the mass of the wheel Assigning a mass turns the wheel into a flywheel. \param val the wheel's mass */ void QwtWheel::setMass( double val ) { QwtAbstractSlider::setMass( val ); } /*! \brief Set the width of the wheel Corresponds to the wheel height for horizontal orientation, and the wheel width for vertical orientation. \param w the wheel's width */ void QwtWheel::setWheelWidth( int w ) { d_data->wheelWidth = w; layoutWheel(); } /*! \return a size hint */ QSize QwtWheel::sizeHint() const { return minimumSizeHint(); } /*! \brief Return a minimum size hint \warning The return value is based on the wheel width. */ QSize QwtWheel::minimumSizeHint() const { QSize sz( 3*d_data->wheelWidth + 2*d_data->borderWidth, d_data->wheelWidth + 2*d_data->borderWidth ); if ( orientation() != Qt::Horizontal ) sz.transpose(); return sz; } /*! \brief Call update() when the palette changes */ void QwtWheel::paletteChange( const QPalette& ) { update(); }