Exemple #1
0
QSizeF QgsTextDiagram::diagramSize( const QgsFeature& feature, const QgsRenderContext& c, const QgsDiagramSettings& s, const QgsDiagramInterpolationSettings& is )
{
  QgsExpressionContext expressionContext = c.expressionContext();
  expressionContext.setFeature( feature );
  if ( feature.fields() )
    expressionContext.setFields( *feature.fields() );

  QVariant attrVal;
  if ( is.classificationAttributeIsExpression )
  {
    QgsExpression* expression = getExpression( is.classificationAttributeExpression, expressionContext );
    attrVal = expression->evaluate( &expressionContext );
  }
  else
  {
    attrVal = feature.attributes().at( is.classificationAttribute );
  }

  bool ok = false;
  double val = attrVal.toDouble( &ok );
  if ( !ok )
  {
    return QSizeF(); //zero size if attribute is missing
  }

  return sizeForValue( val, s, is );
}
QSizeF QgsHistogramDiagram::diagramSize( const QgsFeature& feature, const QgsRenderContext& c, const QgsDiagramSettings& s, const QgsDiagramInterpolationSettings& is )
{
  QSizeF size;
  if ( feature.attributes().isEmpty() )
  {
    return size; //zero size if no attributes
  }

  if ( qgsDoubleNear( is.upperValue, is.lowerValue ) )
    return size; // invalid value range => zero size

  double maxValue = 0;

  QgsExpressionContext expressionContext = c.expressionContext();
  expressionContext.setFeature( feature );
  if ( !feature.fields().isEmpty() )
    expressionContext.setFields( feature.fields() );

  Q_FOREACH ( const QString& cat, s.categoryAttributes )
  {
    QgsExpression* expression = getExpression( cat, expressionContext );
    maxValue = qMax( expression->evaluate( &expressionContext ).toDouble(), maxValue );
  }

  // Scale, if extension is smaller than the specified minimum
  if ( maxValue < s.minimumSize )
  {
    maxValue = s.minimumSize;
  }

  switch ( s.diagramOrientation )
  {
    case QgsDiagramSettings::Up:
    case QgsDiagramSettings::Down:
      mScaleFactor = (( is.upperSize.width() - is.lowerSize.height() ) / ( is.upperValue - is.lowerValue ) );
      size.scale( s.barWidth * s.categoryAttributes.size(), maxValue * mScaleFactor, Qt::IgnoreAspectRatio );
      break;

    case QgsDiagramSettings::Right:
    case QgsDiagramSettings::Left:
      mScaleFactor = (( is.upperSize.width() - is.lowerSize.width() ) / ( is.upperValue - is.lowerValue ) );
      size.scale( maxValue * mScaleFactor, s.barWidth * s.categoryAttributes.size(), Qt::IgnoreAspectRatio );
      break;
  }

  return size;
}
void QgsEditorWidgetWrapper::updateConstraint( const QgsFeature &ft )
{
  bool toEmit( false );
  QString errStr( tr( "predicate is True" ) );
  QString expression = layer()->editFormConfig().constraintExpression( mFieldIdx );
  QString description;
  QVariant value = ft.attribute( mFieldIdx );

  if ( ! expression.isEmpty() )
  {
    description = layer()->editFormConfig().constraintDescription( mFieldIdx );

    QgsExpressionContext context = layer()->createExpressionContext();
    context.setFeature( ft );

    QgsExpression expr( expression );

    mValidConstraint = expr.evaluate( &context ).toBool();

    if ( expr.hasParserError() )
      errStr = expr.parserErrorString();
    else if ( expr.hasEvalError() )
      errStr = expr.evalErrorString();
    else if ( ! mValidConstraint )
      errStr = tr( "predicate is False" );

    toEmit = true;
  }
  else
    mValidConstraint = true;

  if ( layer()->editFormConfig().notNull( mFieldIdx ) )
  {
    if ( !expression.isEmpty() )
    {
      QString fieldName = ft.fields().field( mFieldIdx ).name();
      expression = "( " + expression + " ) AND ( " + fieldName + " IS NOT NULL)";
      description = "( " + description + " ) AND NotNull";
    }
    else
    {
      description = QStringLiteral( "NotNull" );
      expression = QStringLiteral( "NotNull" );
    }

    mValidConstraint = mValidConstraint && !value.isNull();

    if ( value.isNull() )
      errStr = tr( "predicate is False" );

    toEmit = true;
  }

  if ( toEmit )
  {
    updateConstraintWidgetStatus( mValidConstraint );
    emit constraintStatusChanged( expression, description, errStr, mValidConstraint );
  }
}
Exemple #4
0
void QgsActionManager::doAction( const QUuid& actionId, const QgsFeature& feature, int defaultValueIndex )
{
  QgsExpressionContext context = createExpressionContext();
  QgsExpressionContextScope* actionScope = new QgsExpressionContextScope();
  actionScope->addVariable( QgsExpressionContextScope::StaticVariable( QStringLiteral( "field_index" ), defaultValueIndex, true ) );
  if ( defaultValueIndex >= 0 && defaultValueIndex < feature.fields().size() )
    actionScope->addVariable( QgsExpressionContextScope::StaticVariable( QStringLiteral( "field_name" ), feature.fields().at( defaultValueIndex ).name(), true ) );
  actionScope->addVariable( QgsExpressionContextScope::StaticVariable( QStringLiteral( "field_value" ), feature.attribute( defaultValueIndex ), true ) );
  context << actionScope;
  doAction( actionId, feature, context );
}
Exemple #5
0
QSizeF QgsTextDiagram::diagramSize( const QgsFeature& feature, const QgsRenderContext& c, const QgsDiagramSettings& s, const QgsDiagramInterpolationSettings& is )
{
  Q_UNUSED( c );

  QVariant attrVal;
  if ( is.classificationAttributeIsExpression )
  {
    QgsExpression* expression = getExpression( is.classificationAttributeExpression, feature.fields() );
    attrVal = expression->evaluate( feature );
  }
  else
  {
    attrVal = feature.attributes()[is.classificationAttribute];
  }

  if ( !attrVal.isValid() )
  {
    return QSizeF(); //zero size if attribute is missing
  }

  double scaledValue = attrVal.toDouble();
  double scaledLowerValue = is.lowerValue;
  double scaledUpperValue = is.upperValue;
  double scaledLowerSizeWidth = is.lowerSize.width();
  double scaledLowerSizeHeight = is.lowerSize.height();
  double scaledUpperSizeWidth = is.upperSize.width();
  double scaledUpperSizeHeight = is.upperSize.height();

  // interpolate the squared value if scale by area
  if ( s.scaleByArea )
  {
    scaledValue = sqrt( scaledValue );
    scaledLowerValue = sqrt( scaledLowerValue );
    scaledUpperValue = sqrt( scaledUpperValue );
    scaledLowerSizeWidth = sqrt( scaledLowerSizeWidth );
    scaledLowerSizeHeight = sqrt( scaledLowerSizeHeight );
    scaledUpperSizeWidth = sqrt( scaledUpperSizeWidth );
    scaledUpperSizeHeight = sqrt( scaledUpperSizeHeight );
  }

  //interpolate size
  double scaledRatio = ( scaledValue - scaledLowerValue ) / ( scaledUpperValue - scaledLowerValue );

  QSizeF size = QSizeF( is.upperSize.width() * scaledRatio + is.lowerSize.width() * ( 1 - scaledRatio ),
                        is.upperSize.height() * scaledRatio + is.lowerSize.height() * ( 1 - scaledRatio ) );

  // Scale, if extension is smaller than the specified minimum
  if ( size.width() <= s.minimumSize && size.height() <= s.minimumSize )
  {
    size.scale( s.minimumSize, s.minimumSize, Qt::KeepAspectRatio );
  }

  return size;
}
void QgsHistogramDiagram::renderDiagram( const QgsFeature& feature, QgsRenderContext& c, const QgsDiagramSettings& s, QPointF position )
{
  QPainter* p = c.painter();
  if ( !p )
  {
    return;
  }

  QList<double> values;
  double maxValue = 0;

  QgsExpressionContext expressionContext = c.expressionContext();
  expressionContext.setFeature( feature );
  if ( !feature.fields().isEmpty() )
    expressionContext.setFields( feature.fields() );

  Q_FOREACH ( const QString& cat, s.categoryAttributes )
  {
    QgsExpression* expression = getExpression( cat, expressionContext );
    double currentVal = expression->evaluate( &expressionContext ).toDouble();
    values.push_back( currentVal );
    maxValue = qMax( currentVal, maxValue );
  }

  double scaledMaxVal = sizePainterUnits( maxValue * mScaleFactor, s, c );

  double currentOffset = 0;
  double scaledWidth = sizePainterUnits( s.barWidth, s, c );

  double baseX = position.x();
  double baseY = position.y();

  mPen.setColor( s.penColor );
  setPenWidth( mPen, s, c );
  p->setPen( mPen );

  QList<double>::const_iterator valIt = values.constBegin();
  QList< QColor >::const_iterator colIt = s.categoryColors.constBegin();
  for ( ; valIt != values.constEnd(); ++valIt, ++colIt )
  {
    double length = sizePainterUnits( *valIt * mScaleFactor, s, c );

    mCategoryBrush.setColor( *colIt );
    p->setBrush( mCategoryBrush );

    switch ( s.diagramOrientation )
    {
      case QgsDiagramSettings::Up:
        p->drawRect( baseX + currentOffset, baseY, scaledWidth, length * -1 );
        break;

      case QgsDiagramSettings::Down:
        p->drawRect( baseX + currentOffset, baseY - scaledMaxVal, scaledWidth, length );
        break;

      case QgsDiagramSettings::Right:
        p->drawRect( baseX, baseY - currentOffset, length, scaledWidth * -1 );
        break;

      case QgsDiagramSettings::Left:
        p->drawRect( baseX + scaledMaxVal, baseY - currentOffset, 0 - length, scaledWidth * -1 );
        break;
    }

    currentOffset += scaledWidth;
  }
}
Exemple #7
0
void QgsTextDiagram::renderDiagram( const QgsFeature& feature, QgsRenderContext& c, const QgsDiagramSettings& s, QPointF position )
{
  QPainter* p = c.painter();
  if ( !p )
  {
    return;
  }

  //convert from mm / map units to painter units
  QSizeF spu = sizePainterUnits( s.size, s, c );
  double w = spu.width();
  double h = spu.height();

  double baseX = position.x();
  double baseY = position.y() - h;

  QVector<QPointF> textPositions; //midpoints for text placement
  int nCategories = s.categoryAttributes.size();
  for ( int i = 0; i < nCategories; ++i )
  {
    if ( mOrientation == Horizontal )
    {
      textPositions.push_back( QPointF( baseX + ( w / nCategories ) * i + w / nCategories / 2.0, baseY + h / 2.0 ) );
    }
    else //vertical
    {
      textPositions.push_back( QPointF( baseX + w / 2.0, baseY + h / nCategories * i + w / nCategories / 2.0 ) );
    }
  }

  mPen.setColor( s.penColor );
  setPenWidth( mPen, s, c );
  p->setPen( mPen );
  mBrush.setColor( s.backgroundColor );
  p->setBrush( mBrush );

  //draw shapes and separator lines first
  if ( mShape == Circle )
  {
    p->drawEllipse( baseX, baseY, w, h );

    //draw separator lines
    QList<QPointF> intersect; //intersections between shape and separation lines
    QPointF center( baseX + w / 2.0, baseY + h / 2.0 );
    double r1 = w / 2.0;
    double r2 = h / 2.0;

    for ( int i = 1; i < nCategories; ++i )
    {
      if ( mOrientation == Horizontal )
      {
        lineEllipseIntersection( QPointF( baseX + w / nCategories * i, baseY ), QPointF( baseX + w / nCategories * i, baseY + h ), center, r1, r2, intersect );
      }
      else //vertical
      {
        lineEllipseIntersection( QPointF( baseX, baseY + h / nCategories * i ), QPointF( baseX + w, baseY + h / nCategories * i ), center, r1, r2, intersect );
      }
      if ( intersect.size() > 1 )
      {
        p->drawLine( intersect.at( 0 ), intersect.at( 1 ) );
      }
    }
  }
  else if ( mShape == Rectangle )
  {
    p->drawRect( QRectF( baseX, baseY, w, h ) );
    for ( int i = 1; i < nCategories; ++i )
    {
      if ( mOrientation == Horizontal )
      {
        p->drawLine( QPointF( baseX + w / nCategories * i, baseY ), QPointF( baseX + w / nCategories * i, baseY + h ) );
      }
      else
      {
        p->drawLine( QPointF( baseX, baseY + h / nCategories * i ), QPointF( baseX + w, baseY + h / nCategories * i ) );
      }
    }
  }
  else //triangle
  {
    QPolygonF triangle;
    triangle << QPointF( baseX, baseY + h ) << QPointF( baseX + w, baseY + h ) << QPointF( baseX + w / 2.0, baseY );
    p->drawPolygon( triangle );

    QLineF triangleEdgeLeft( baseX + w / 2.0, baseY, baseX, baseY + h );
    QLineF triangleEdgeRight( baseX + w, baseY + h, baseX + w / 2.0, baseY );
    QPointF intersectionPoint1, intersectionPoint2;

    for ( int i = 1; i < nCategories; ++i )
    {
      if ( mOrientation == Horizontal )
      {
        QLineF verticalLine( baseX + w / nCategories * i, baseY + h, baseX + w / nCategories * i, baseY );
        if ( baseX + w / nCategories * i < baseX + w / 2.0 )
        {
          verticalLine.intersect( triangleEdgeLeft, &intersectionPoint1 );
        }
        else
        {
          verticalLine.intersect( triangleEdgeRight, &intersectionPoint1 );
        }
        p->drawLine( QPointF( baseX + w / nCategories * i, baseY + h ), intersectionPoint1 );
      }
      else //vertical
      {
        QLineF horizontalLine( baseX, baseY + h / nCategories * i, baseX + w, baseY + h / nCategories * i );
        horizontalLine.intersect( triangleEdgeLeft, &intersectionPoint1 );
        horizontalLine.intersect( triangleEdgeRight, &intersectionPoint2 );
        p->drawLine( intersectionPoint1, intersectionPoint2 );
      }
    }
  }

  //draw text
  QFont sFont = scaledFont( s, c );
  QFontMetricsF fontMetrics( sFont );
  p->setFont( sFont );

  QgsExpressionContext expressionContext = c.expressionContext();
  expressionContext.setFeature( feature );
  if ( feature.fields() )
    expressionContext.setFields( *feature.fields() );

  for ( int i = 0; i < textPositions.size(); ++i )
  {
    QgsExpression* expression = getExpression( s.categoryAttributes.at( i ), expressionContext );
    QString val = expression->evaluate( &expressionContext ).toString();

    //find out dimesions
    double textWidth = fontMetrics.width( val );
    double textHeight = fontMetrics.height();

    mPen.setColor( s.categoryColors.at( i ) );
    p->setPen( mPen );
    QPointF position = textPositions.at( i );

    // Calculate vertical placement
    double xOffset = 0;

    switch ( s.labelPlacementMethod )
    {
      case QgsDiagramSettings::Height:
        xOffset = textHeight / 2.0;
        break;

      case QgsDiagramSettings::XHeight:
        xOffset = fontMetrics.xHeight();
        break;
    }
    p->drawText( QPointF( position.x() - textWidth / 2.0, position.y() + xOffset ), val );
  }
}
void QgsPieDiagram::renderDiagram( const QgsFeature& feature, QgsRenderContext& c, const QgsDiagramSettings& s, const QPointF& position )
{
  QPainter* p = c.painter();
  if ( !p )
  {
    return;
  }

  //get sum of values
  QList<double> values;
  double currentVal = 0;
  double valSum = 0;
  int valCount = 0;

  QList<QString>::const_iterator catIt = s.categoryAttributes.constBegin();
  for ( ; catIt != s.categoryAttributes.constEnd(); ++catIt )
  {
    QgsExpression* expression = getExpression( *catIt, feature.fields() );
    currentVal = expression->evaluate( feature ).toDouble();
    values.push_back( currentVal );
    valSum += currentVal;
    if ( currentVal ) valCount++;
  }

  //draw the slices
  double totalAngle = 0;
  double currentAngle;

  //convert from mm / map units to painter units
  QSizeF spu = sizePainterUnits( s.size, s, c );
  double w = spu.width();
  double h = spu.height();

  double baseX = position.x();
  double baseY = position.y() - h;

  mPen.setColor( s.penColor );
  setPenWidth( mPen, s, c );
  p->setPen( mPen );

  // there are some values > 0 available
  if ( valSum > 0 )
  {
    QList<double>::const_iterator valIt = values.constBegin();
    QList< QColor >::const_iterator colIt = s.categoryColors.constBegin();
    for ( ; valIt != values.constEnd(); ++valIt, ++colIt )
    {
      if ( *valIt )
      {
        currentAngle = *valIt / valSum * 360 * 16;
        mCategoryBrush.setColor( *colIt );
        p->setBrush( mCategoryBrush );
        // if only 1 value is > 0, draw a circle
        if ( valCount == 1 )
        {
          p->drawEllipse( baseX, baseY, w, h );
        }
        else
        {
          p->drawPie( baseX, baseY, w, h, totalAngle + s.angleOffset, currentAngle );
        }
        totalAngle += currentAngle;
      }
    }
  }
  else // valSum > 0
  {
    // draw empty circle if no values are defined at all
    mCategoryBrush.setColor( Qt::transparent );
    p->setBrush( mCategoryBrush );
    p->drawEllipse( baseX, baseY, w, h );
  }
}