void UIGraphicsZoomButton::updateAnimation() { QRectF oldRect = geometry(); QRectF newRect = oldRect; if (m_iDirection & UIGraphicsZoomDirection_Top) newRect.setTop(newRect.top() - m_iIndent); if (m_iDirection & UIGraphicsZoomDirection_Bottom) newRect.setBottom(newRect.bottom() + m_iIndent); if (m_iDirection & UIGraphicsZoomDirection_Left) newRect.setLeft(newRect.left() - m_iIndent); if (m_iDirection & UIGraphicsZoomDirection_Right) newRect.setRight(newRect.right() + m_iIndent); if (!(m_iDirection & UIGraphicsZoomDirection_Left) && !(m_iDirection & UIGraphicsZoomDirection_Right)) { newRect.setLeft(newRect.left() - m_iIndent / 2); newRect.setRight(newRect.right() + m_iIndent / 2); } if (!(m_iDirection & UIGraphicsZoomDirection_Top) && !(m_iDirection & UIGraphicsZoomDirection_Bottom)) { newRect.setTop(newRect.top() - m_iIndent / 2); newRect.setBottom(newRect.bottom() + m_iIndent / 2); } m_pForwardAnimation->setStartValue(oldRect); m_pForwardAnimation->setEndValue(newRect); m_pBackwardAnimation->setStartValue(newRect); m_pBackwardAnimation->setEndValue(oldRect); }
/** * 功能 * 当前单元格子元素布局 */ void WinDigitalDelegate::doLayout(const QStyleOptionViewItem & option, QRectF &valRect, QRectF &unitRect, QRectF &tagRect, QRectF &alarmRect, qreal &alarmSpan) const { /***********测量值***********/ valRect = option.rect; valRect.setHeight(valRect.height()/3); valRect.moveTop(valRect.bottom()); valRect.setRight(valRect.right() - valRect.width()/18- 3); /************标记**********/ tagRect = valRect; tagRect.moveBottom(tagRect.top()); tagRect.setTop(tagRect.top() + option.rect.height()/10); /************单位***********/ unitRect = valRect; unitRect.moveTop(unitRect.bottom()); unitRect.setRight(unitRect.right() - 15); /*************报警标记**********/ alarmRect = unitRect; alarmRect.setHeight(alarmRect.height()/3); alarmRect.moveTop(alarmRect.bottom()); alarmRect.setLeft(alarmRect.center().x() - 4*alarmRect.height()); alarmRect.setWidth(alarmRect.height()); alarmSpan = alarmRect.width() * 2; }
QRectF addBBox(QRectF r1, QRectF r2) { // Find smallest QRectF containing given rectangles QRectF n; // Set left border if (r1.left() <= r2.left() ) n.setLeft(r1.left() ); else n.setLeft(r2.left() ); // Set top border if (r1.top() <= r2.top() ) n.setTop(r1.top() ); else n.setTop(r2.top() ); // Set right border if (r1.right() <= r2.right() ) n.setRight(r2.right() ); else n.setRight(r1.right() ); // Set bottom if (r1.bottom() <= r2.bottom() ) n.setBottom(r2.bottom() ); else n.setBottom(r1.bottom() ); return n; }
static void blitTexture(QGLContext *ctx, GLuint texture, const QSize &viewport, const QSize &texSize, const QRect &targetRect, const QRect &sourceRect) { glDisable(GL_DEPTH_TEST); glDisable(GL_SCISSOR_TEST); glDisable(GL_BLEND); glViewport(0, 0, viewport.width(), viewport.height()); QGLShaderProgram *blitProgram = QGLEngineSharedShaders::shadersForContext(ctx)->blitProgram(); blitProgram->bind(); blitProgram->setUniformValue("imageTexture", 0 /*QT_IMAGE_TEXTURE_UNIT*/); // The shader manager's blit program does not multiply the // vertices by the pmv matrix, so we need to do the effect // of the orthographic projection here ourselves. QRectF r; qreal w = viewport.width(); qreal h = viewport.height(); r.setLeft((targetRect.left() / w) * 2.0f - 1.0f); if (targetRect.right() == (viewport.width() - 1)) r.setRight(1.0f); else r.setRight((targetRect.right() / w) * 2.0f - 1.0f); r.setBottom((targetRect.top() / h) * 2.0f - 1.0f); if (targetRect.bottom() == (viewport.height() - 1)) r.setTop(1.0f); else r.setTop((targetRect.bottom() / w) * 2.0f - 1.0f); drawTexture(r, texture, texSize, sourceRect); }
void QOpacityTransferFunctionGraphicalView::setOpacityTransferFunction(const OpacityTransferFunction &opacityTransferFunction) { scene()->clear(); QList<double> keys = opacityTransferFunction.keys(); QRectF rect; bool first = true; QOpacityTransferFunctionGraphicalViewNode *previousNode = 0; foreach (double x, keys) { double opacity = opacityTransferFunction.get(x); QOpacityTransferFunctionGraphicalViewNode *node = new QOpacityTransferFunctionGraphicalViewNode(); node->setX(x); node->setY(opacity); node->setToolTip(QString("(%1, %2)").arg(x).arg(opacity)); scene()->addItem(node); if (previousNode) { QOpacityTransferFunctionGraphicalViewLine *line = new QOpacityTransferFunctionGraphicalViewLine(); line->setLeftNode(previousNode); line->setRightNode(node); previousNode->setRightLine(line); node->setLeftLine(line); scene()->addItem(line); } if (first) { first = false; rect.setLeft(x); rect.setRight(x); rect.setTop(opacity); rect.setBottom(opacity); } else { if (x < rect.left()) { rect.setLeft(x); } if (x > rect.right()) { rect.setRight(x); } if (opacity < rect.top()) { rect.setTop(opacity); } if (opacity > rect.bottom()) { rect.setBottom(opacity); } } previousNode = node; }
void RenderedItemInterface::redraw(bool withChildren) { QRectF itemPixelRect = convertUnit(d_ptr->rect, Millimeter, Pixel, d_ptr->dpi); #if QT_VERSION >= 0x050000 itemPixelRect.setBottom(itemPixelRect.bottom() -1); itemPixelRect.setRight(itemPixelRect.right() -1); #endif QPointF absPos = absolutePixelPos(); QPointF pos; if (parentItem()) { pos = parentItem()->mapFromScene(absPos); // qDebug() << "parentPos" << parentItem()->pos(); } else { pos = absPos; } // qDebug() << "pos" << pos; setRect(0,0, itemPixelRect.width(), itemPixelRect.height()); setRotation(-d_ptr->rotation); QPointF transPos = BaseItemInterface::transformedPos(d_ptr, QRectF(pos, itemPixelRect.size())); setPos(transPos); if (withChildren) { QList<QGraphicsItem *> list = childItems(); foreach (QGraphicsItem * item, list) { if (item->parentItem() == this && item->type() == RenderedItemInterface::Type) { RenderedItemInterface * rendItem = static_cast<RenderedItemInterface *>(item); rendItem->redraw(true); } } } }
void CallbackBoundingRects::mergeCoordinates (const QPointF &pos, QRectF &boundingRect) { bool newGraphLeft = m_isEmpty; bool newGraphTop = m_isEmpty; bool newGraphRight = m_isEmpty; bool newGraphBottom = m_isEmpty; if (!newGraphLeft) { newGraphLeft = (pos.x() < boundingRect.left()); } if (!newGraphTop) { newGraphTop = (pos.y() < boundingRect.top()); } if (!newGraphRight) { newGraphRight = (boundingRect.right() < pos.x()); } if (!newGraphBottom) { newGraphBottom = (boundingRect.bottom() < pos.y()); } if (newGraphLeft) { boundingRect.setLeft (pos.x()); } if (newGraphTop) { boundingRect.setTop (pos.y()); } if (newGraphRight) { boundingRect.setRight (pos.x()); } if (newGraphBottom) { boundingRect.setBottom (pos.y()); } }
void BlurItem::mouseMoveEvent(QGraphicsSceneMouseEvent *event) { QGraphicsRectItem::mouseMoveEvent(event); const QPointF pos = event->scenePos(); QRectF r; r.setTopLeft(m_point); r.setBottomRight(event->scenePos()); if (r.width() < 0) { r.setLeft(pos.x()); r.setRight(m_point.x()); } if (r.height() < 0) { r.setTop(pos.y()); r.setBottom(m_point.y()); } r = r.intersected(m_item->scene()->sceneRect()); setRect(r); setSelected(true); m_item->setOffset(r.topLeft()); reload(m_pixmap); }
void PDFSelection::copy() { if(d->textReply) { d->textReply->close(); delete d->textReply; d->textReply = 0; } PDFPage *page = d->currentPage; if(!page) { qDebug() << "Invalid page"; return; } QRectF geom = geometry(); geom.setLeft(geom.left() + d->documentOffset.x()); geom.setRight(geom.right() + d->documentOffset.x()); geom.setTop((geom.top() + d->documentOffset.y()) - page->positionInDocument() ); geom.setBottom((geom.bottom() + d->documentOffset.y()) - page->positionInDocument() ); QRectF sel(QPointF(geom.left() / page->width(), geom.top() / page->height()), QPointF(geom.right() / page->width(), geom.bottom() / page->height())); QString arguments = QString("page=%1&top=%2&right=%3&bottom=%4&left=%5").arg(page->pageNumber()).arg(sel.top()).arg(sel.right()).arg(sel.bottom()).arg(sel.left()); d->textReply = d->document->networkManager()->get(d->document->buildRequest("text", arguments)); connect(d->textReply, SIGNAL(finished()), SLOT(textRequestFinished())); }
static void qsgsimpletexturenode_update(QSGGeometry *g, QSGTexture *texture, const QRectF &rect, QRectF sourceRect, QSGSimpleTextureNode::TextureCoordinatesTransformMode texCoordMode) { if (!texture) return; if (!sourceRect.width() || !sourceRect.height()) { QSize ts = texture->textureSize(); sourceRect = QRectF(0, 0, ts.width(), ts.height()); } // Maybe transform the texture coordinates if (texCoordMode.testFlag(QSGSimpleTextureNode::MirrorHorizontally)) { float tmp = sourceRect.left(); sourceRect.setLeft(sourceRect.right()); sourceRect.setRight(tmp); } if (texCoordMode.testFlag(QSGSimpleTextureNode::MirrorVertically)) { float tmp = sourceRect.top(); sourceRect.setTop(sourceRect.bottom()); sourceRect.setBottom(tmp); } QSGGeometry::updateTexturedRectGeometry(g, rect, texture->convertToNormalizedSourceRect(sourceRect)); }
QRectF QWidgetWindowPrivate::closestAcceptableGeometry(const QRectF &rect) const { Q_Q(const QWidgetWindow); const QWidget *widget = q->widget(); if (!widget->isWindow() || !widget->hasHeightForWidth()) return QRect(); const QSize oldSize = rect.size().toSize(); const QSize newSize = QLayout::closestAcceptableSize(widget, oldSize); if (newSize == oldSize) return QRectF(); const int dw = newSize.width() - oldSize.width(); const int dh = newSize.height() - oldSize.height(); QRectF result = rect; const QRectF currentGeometry(widget->geometry()); const qreal topOffset = result.top() - currentGeometry.top(); const qreal bottomOffset = result.bottom() - currentGeometry.bottom(); if (qAbs(topOffset) > qAbs(bottomOffset)) result.setTop(result.top() - dh); // top edge drag else result.setBottom(result.bottom() + dh); // bottom edge drag const qreal leftOffset = result.left() - currentGeometry.left(); const qreal rightOffset = result.right() - currentGeometry.right(); if (qAbs(leftOffset) > qAbs(rightOffset)) result.setLeft(result.left() - dw); // left edge drag else result.setRight(result.right() + dw); // right edge drag return result; }
void VLCStatsView::addValue( float value ) { value /= 1000; QPolygonF shape = totalbitrateShape->polygon(); if ( shape.count() > ( STATS_LENGTH + 2 ) ) /* keep only STATS_LENGTH samples */ { shape.remove( 1 ); for(int i=1; i<( STATS_LENGTH + 2 ); i++) ( (QPointF &) shape.at(i) ).setX( i - 1 ); /*move back values*/ } int count = shape.count(); if ( count == 0 ) { shape << QPointF( 0, 0 ); /* begin and close shape */ shape << QPointF( count, 0 ); } shape.insert( shape.end() - 1, QPointF( count, value ) ); ( (QPointF &) shape.last() ).setX( count ); totalbitrateShape->setPolygon( shape ); addHistoryValue( value ); QRectF maxsizes = scene()->itemsBoundingRect(); maxsizes.setRight( STATS_LENGTH ); fitInView( maxsizes ); /* fix viewport */ drawRulers( maxsizes ); }
/** If needed, recalculate the cached bounding rectangles of all assemblies. */ void UnwrappedSurface::cacheAllAssemblies() { if (!m_assemblies.empty()) return; for (size_t i = 0; i < m_unwrappedDetectors.size(); ++i) { const UnwrappedDetector &udet = m_unwrappedDetectors[i]; if (!udet.detector) continue; // Get the BARE parent (not parametrized) to speed things up. const Mantid::Geometry::IComponent *bareDet = udet.detector->getComponentID(); const Mantid::Geometry::IComponent *parent = bareDet->getBareParent(); if (parent) { QRectF detRect; detRect.setLeft(udet.u - udet.width); detRect.setRight(udet.u + udet.width); detRect.setBottom(udet.v - udet.height); detRect.setTop(udet.v + udet.height); Mantid::Geometry::ComponentID id = parent->getComponentID(); QRectF &r = m_assemblies[id]; r |= detRect; calcAssemblies(parent, r); } } }
QRectF ODrawClient::getRect(const MSO::OfficeArtClientAnchor& clientAnchor) { const MSO::XlsOfficeArtClientAnchor* anchor = clientAnchor.anon.get<MSO::XlsOfficeArtClientAnchor>(); if (anchor) { QRectF r; qreal colWidth = columnWidth(m_sheet, anchor->colL); r.setLeft(offset(colWidth, anchor->dxL, 1024)); if (anchor->colR == anchor->colL) { r.setRight(offset(colWidth, anchor->dxR, 1024)); } else { qreal width = colWidth - r.left(); for (int col = anchor->colL + 1; col < anchor->colR; ++col) { width += columnWidth(m_sheet, col); } width += offset(columnWidth(m_sheet, anchor->colR), anchor->dxR, 1024); r.setWidth(width); } qreal rowHgt = rowHeight(m_sheet, anchor->rwT); r.setTop(offset(rowHgt, anchor->dyT, 256)); if (anchor->rwT == anchor->rwB) { r.setBottom(offset(rowHgt, anchor->dyB, 256)); } else { qreal height = rowHgt - r.top(); for (int row = anchor->rwT + 1; row < anchor->rwB; ++row) { height += rowHeight(m_sheet, row); } height += offset(rowHeight(m_sheet, anchor->rwB), anchor->dyB, 256); r.setHeight(height); } return r; } else { qDebug() << "Invalid client anchor!"; } return QRectF(); }
void SearchDocumentJob::run() { Q_ASSERT(m_document); for (int i = 0; i < m_document->numPages(); ++i) { int ipage = (startPage + i) % m_document->numPages(); Poppler::Page *page = m_document->page(ipage); double sLeft, sTop, sRight, sBottom; float scaleW = 1.f / page->pageSizeF().width(); float scaleH = 1.f / page->pageSizeF().height(); bool found; found = page->search(m_search, sLeft, sTop, sRight, sBottom, Poppler::Page::FromTop, Poppler::Page::IgnoreCase); while (found) { QRectF result; result.setLeft(sLeft * scaleW); result.setTop(sTop * scaleH); result.setRight(sRight * scaleW); result.setBottom(sBottom * scaleH); m_matches.append(QPair<int, QRectF>(ipage, result)); found = page->search(m_search, sLeft, sTop, sRight, sBottom, Poppler::Page::NextResult, Poppler::Page::IgnoreCase); } delete page; } }
void FormCheckBox::draw( QPainter * painter, const QPen & pen, const QFont & font, const QRectF & rect, qreal width, bool isChecked, const QString & text ) { painter->setPen( pen ); painter->drawRect( rect ); if( isChecked ) { painter->drawLine( QLineF( rect.topLeft().x() + 4.0, rect.topLeft().y() + rect.height() / 2.0, rect.topLeft().x() + rect.width() / 2.0, rect.bottomLeft().y() - 4.0 ) ); painter->drawLine( QLineF( rect.topLeft().x() + rect.width() / 2.0, rect.bottomLeft().y() - 4.0, rect.topRight().x() - 4.0, rect.topRight().y() + 4.0 ) ); } painter->setFont( font ); QRectF r = rect; r.setRight( rect.x() + width ); r.moveLeft( rect.x() + rect.height() + 4.0 ); painter->drawText( r, Qt::AlignLeft | Qt::AlignVCenter, text ); }
/*! Draw the symbol when it is in Box style. \param painter Painter \param rect Directed rectangle \sa draw() */ void QwtColumnSymbol::drawBox( QPainter *painter, const QwtColumnRect &rect ) const { QRectF r = rect.toRect(); if ( QwtPainter::roundingAlignment( painter ) ) { r.setLeft( qRound( r.left() ) ); r.setRight( qRound( r.right() ) ); r.setTop( qRound( r.top() ) ); r.setBottom( qRound( r.bottom() ) ); } switch ( d_data->frameStyle ) { case QwtColumnSymbol::Raised: { qwtDrawPanel( painter, r, d_data->palette, d_data->lineWidth ); break; } case QwtColumnSymbol::Plain: { qwtDrawBox( painter, r, d_data->palette, d_data->lineWidth ); break; } default: { painter->fillRect( r, d_data->palette.window() ); } } }
TimelineBar::Marker *TimelineBar::findMarker(QVector<Marker> &markers, QRectF markerRect, QPointF pos) { QFontMetrics fm(Formatter::PreferredFont()); for(Marker &m : markers) { QRectF r = markerRect; r.setLeft(qMax(m_markerRect.left() + borderWidth * 2, offsetOf(m.eidStart))); r.setRight(qMin(m_markerRect.right() - borderWidth, offsetOf(m.eidEnd + 1))); r.setHeight(fm.height() + borderWidth * 2); if(r.width() <= borderWidth * 2) continue; if(r.contains(pos)) { return &m; } if(!m.children.isEmpty() && m.expanded) { QRectF childRect = r; childRect.setTop(r.bottom() + borderWidth * 2); childRect.setBottom(markerRect.bottom()); Marker *res = findMarker(m.children, childRect, pos); if(res) return res; } } return NULL; }
void ResizeHandler::expandByChildren(QRectF &contents) const { QVector<int> const sizeOfForestalling = mElementType.sizeOfForestalling(); for (const QGraphicsItem * const childItem : mTargetNode.childItems()) { QRectF curChildItemBoundingRect = childBoundingRect(childItem, contents); if (curChildItemBoundingRect.width() == 0 || curChildItemBoundingRect.height() == 0) { continue; } // it seems to be more appropriate to use childItem->pos() but it causes // bad behaviour when dropping one element to another curChildItemBoundingRect.translate(childItem->scenePos() - mTargetNode.scenePos()); contents.setLeft(qMin(curChildItemBoundingRect.left() - sizeOfForestalling[0] , contents.left())); contents.setRight(qMax(curChildItemBoundingRect.right() + sizeOfForestalling[2] , contents.right())); contents.setTop(qMin(curChildItemBoundingRect.top() - sizeOfForestalling[1] , contents.top())); contents.setBottom(qMax(curChildItemBoundingRect.bottom() + sizeOfForestalling[3] , contents.bottom())); } }
/*! \return Bounding rectangle of all samples. For an empty series the rectangle is invalid. */ QRectF QwtPlotHistogram::boundingRect() const { QRectF rect = d_series->boundingRect(); if ( !rect.isValid() ) return rect; if ( orientation() == Qt::Horizontal ) { rect = QRectF( rect.y(), rect.x(), rect.height(), rect.width() ); if ( rect.left() > d_data->baseline ) rect.setLeft( d_data->baseline ); else if ( rect.right() < d_data->baseline ) rect.setRight( d_data->baseline ); } else { if ( rect.bottom() < d_data->baseline ) rect.setBottom( d_data->baseline ); else if ( rect.top() > d_data->baseline ) rect.setTop( d_data->baseline ); } return rect; }
void HeightMapEditor::onViewChanged(const QRectF & rect) { if (!myGraph) return; if (myUi->renderView->scene()->children().count() > 50) { QList<QGraphicsItem *> items = myUi->renderView->scene()->items(); for (QGraphicsItem * i : items) if (!i->isVisible()) myUi->renderView->scene()->removeItem(i); } QRectF trect; trect.setLeft(rect.left() - fmod(rect.left(), myCellSize.width())); trect.setTop(rect.top() - fmod(rect.top(), myCellSize.height())); trect.setRight(rect.right() - fmod(rect.right(), myCellSize.width())); trect.setBottom(rect.bottom() - fmod(rect.bottom(), myCellSize.height())); for (double y = trect.top() - fmod(trect.top(), myCellSize.height()); y < trect.bottom() + myCellSize.height() - fmod(trect.bottom(), myCellSize.height()); y += myCellSize.height()) for (double x = trect.left() - fmod(trect.left(), myCellSize.width()); x < trect.right() + myCellSize.width() - fmod(trect.right(), myCellSize.width()); x += myCellSize.width()) { QRectF r(x,y,myCellSize.width(), myCellSize.height()); generateRect(r); } }
void QGraphVizPIP::drawForeground(QPainter *painter, const QRectF &rect) { if(!rect.intersects(m_ViewPortRect)) { return; } if(m_ViewPortRect.contains(scene()->sceneRect())) { return; } QColor color(Qt::red); QPen pen; pen.setColor(color); painter->setPen(pen); QBrush brush; color.setAlphaF(.1); brush.setColor(color); brush.setStyle(Qt::SolidPattern); painter->setBrush(brush); QRectF sceneRect = this->sceneRect().adjusted(-10,-10,20,20); QRectF viewPortRect; viewPortRect.setLeft(qMax(sceneRect.left(), m_ViewPortRect.left())); viewPortRect.setTop(qMax(sceneRect.top(), m_ViewPortRect.top())); viewPortRect.setRight(qMin(sceneRect.right(), m_ViewPortRect.right())); viewPortRect.setBottom(qMin(sceneRect.bottom(), m_ViewPortRect.bottom())); painter->drawRect(viewPortRect); }
void MiniMap::updateMap() { QRectF maxRect; maxRect.setLeft( sceneRect().x() < visibleRect.x() ? sceneRect().x() : visibleRect.x() ); maxRect.setTop( sceneRect().y() < visibleRect.y() ? sceneRect().y() : visibleRect.y() ); maxRect.setRight( (sceneRect().x() + sceneRect().width()) > (visibleRect.x()+visibleRect.width()) ? (sceneRect().x() + sceneRect().width()) : (visibleRect.x()+visibleRect.width())); maxRect.setBottom( (sceneRect().y() + sceneRect().height()) > (visibleRect.y()+visibleRect.height()) ? (sceneRect().y() + sceneRect().height()) : (visibleRect.y()+visibleRect.height())); qreal xScale = (width() - 2*frameWidth() - 2*margin) / maxRect.width(); qreal yScale = (height() - 2*frameWidth() - 2*margin) / maxRect.height(); qreal scale = xScale < yScale ? xScale : yScale; qreal rectX = margin + (visibleRect.x() - maxRect.x())*scale; qreal rectY = margin + (visibleRect.y() - maxRect.y())*scale; if (xScale < yScale) rectY += (height() - 2*(frameWidth() + margin) - maxRect.height()*scale) / 2; else rectX += (width() - 2*(frameWidth() + margin) - maxRect.width()*scale) / 2; // Below we subtract 0.5 and take the ceiling. This rounds the number. We further subtract 1 in order to compensate // for the pen width of the drawn rectangle. drawnRect.setRect(rectX, rectY, ceil(visibleRect.width()*scale - 1.5), ceil(visibleRect.height()*scale - 1.5)); setTransform(QTransform::fromScale(scale,scale).translate(margin, margin)); viewport()->update(); }
void QReportWidgetResizer::handleMoving(QPointF point) { QReportResizeHandle *s = qobject_cast<QReportResizeHandle*> (sender()); QRectF rc = resizeRect; QReportMoveEvent e(point, point); emit pointGridNeeded(&e); if (!e.isAccepted()) return; if (s->resizeDirection() & ::Top) rc.setTop(e.point().y()); if (s->resizeDirection() & ::Left) rc.setLeft(e.point().x()); if (s->resizeDirection() & ::Right) rc.setRight(e.point().x()); if (s->resizeDirection() & ::Bottom) rc.setBottom(e.point().y()); if(_selectedWidgets.count() == 1){ if(rc.width() < _selectedWidgets.at(0)->minimumSize().width()) rc.setWidth(_selectedWidgets.at(0)->minimumSize().width()); if(rc.height() < _selectedWidgets.at(0)->minimumSize().height()) rc.setHeight(_selectedWidgets.at(0)->minimumSize().height()); } if (rc.isValid()) { setResezeHandlePos(s, e.point()); resizeRect = rc; proccessNewRect(rc); setHandlesOnItem(rc); }//if }
static QRectF qwtExpandedZoomRect( const QRectF &zoomRect, const QSizeF &minSize, const QwtTransform* transformX, const QwtTransform* transformY ) { QRectF r = zoomRect; if ( minSize.width() > r.width() ) { const QwtInterval intv = qwtExpandedZoomInterval( r.left(), r.right(), minSize.width(), transformX ); r.setLeft( intv.minValue() ); r.setRight( intv.maxValue() ); } if ( minSize.height() > r.height() ) { const QwtInterval intv = qwtExpandedZoomInterval( zoomRect.top(), zoomRect.bottom(), minSize.height(), transformY ); r.setTop( intv.minValue() ); r.setBottom( intv.maxValue() ); } return r; }
/*! \return Bounding rectangle of the data \sa QwtPlotRasterItem::interval() */ QRectF QwtPlotRasterItem::boundingRect() const { const QwtInterval intervalX = interval( Qt::XAxis ); const QwtInterval intervalY = interval( Qt::YAxis ); if ( !intervalX.isValid() && !intervalY.isValid() ) return QRectF(); // no bounding rect QRectF r; if ( intervalX.isValid() ) { r.setLeft( intervalX.minValue() ); r.setRight( intervalX.maxValue() ); } else { r.setLeft(-0.5 * FLT_MAX); r.setWidth(FLT_MAX); } if ( intervalY.isValid() ) { r.setTop( intervalY.minValue() ); r.setBottom( intervalY.maxValue() ); } else { r.setTop(-0.5 * FLT_MAX); r.setHeight(FLT_MAX); } return r.normalized(); }
void LineSegmentPlot::updateDataLimits() { qDebug() << Q_FUNC_INFO; int xLen = xSize(), yLen = ySize(), endXLen = m_endX.size(), endYLen = m_endY.size(); int N = qMin( qMin(xLen, yLen), qMin(endXLen, endYLen) ); m_dataSize = N; qreal minX = Inf, maxX = -Inf, minY = Inf, maxY = -Inf; // Calculate the y limits RangeValues yrng = ArrayUtil::limits(yData()); minY = yrng.min; maxY = yrng.max; yrng = ArrayUtil::limits(m_endY); minY = qMin(minY, yrng.min); maxY = qMax(maxY, yrng.max); RangeValues xrng = ArrayUtil::limits(xData()); minX = xrng.min; maxX = xrng.max; xrng = ArrayUtil::limits(m_endX); minX = qMin(minX, xrng.min); maxX = qMax(maxX, xrng.max); QRectF newLim; newLim.setLeft(minX); newLim.setTop(minY); newLim.setRight(maxX); newLim.setBottom(maxY); setDataLimits(newLim); }
void AbstractScrollArea::adjustScrollBars() { if (m_horizontalScrollBarPolicy == Qt::ScrollBarAlwaysOff) { m_horizontalScrollBar->hide(); } else { m_horizontalScrollBar->show(); QRectF sbgeom = boundingRect(); sbgeom.setTop(sbgeom.bottom() - m_horizontalScrollBar->boundingRect().height()); sbgeom.setRight(sbgeom.right() - m_verticalScrollBar->boundingRect().width()); m_horizontalScrollBar->setGeometry(sbgeom); } if (m_verticalScrollBarPolicy == Qt::ScrollBarAlwaysOff) { m_verticalScrollBar->hide(); QRectF sbgeom = boundingRect(); sbgeom.setLeft(sbgeom.right()); sbgeom.setBottom(sbgeom.bottom()); m_verticalScrollBar->setGeometry(sbgeom); } else { m_verticalScrollBar->show(); QRectF sbgeom = boundingRect(); sbgeom.setLeft(sbgeom.right() - m_verticalScrollBar->boundingRect().width()); if (m_horizontalScrollBarPolicy != Qt::ScrollBarAlwaysOff) sbgeom.setBottom(sbgeom.bottom() - m_horizontalScrollBar->boundingRect().height()); m_verticalScrollBar->setGeometry(sbgeom); } }
void VpGrid::drawReference(GridGC &gridGC) { int x,y; VpGC *vpgc = gridGC.m_gc; QPainter *gc = vpgc->getGC(); // Assuming QPainter has already established begin(). gc->setRenderHint(QPainter::Antialiasing, true); if (m_referenceStyle == VpGrid::REFSTYLE_SQUARE) { // Set the pen. QPen pen; pen.setStyle(Qt::NoPen); gc->setPen(pen); // Set the brush. QBrush brush; brush.setColor(m_referenceColor); brush.setStyle(Qt::SolidPattern); gc->setBrush(brush); QRectF origin; origin.setLeft(-1.5 + m_xAlignment); origin.setRight(1.5 + m_xAlignment); origin.setBottom(-1.5 + m_yAlignment); origin.setTop(1.5 + m_yAlignment); gc->drawRect(origin); } else if (m_referenceStyle == VpGrid::REFSTYLE_CIRCLE) { // Set the pen. QPen pen; pen.setStyle(Qt::NoPen); gc->setPen(pen); // Set the brush. QBrush brush; brush.setColor(m_referenceColor); brush.setStyle(Qt::SolidPattern); gc->setBrush(brush); gc->drawEllipse(QPoint(m_xAlignment, m_yAlignment), 2, 2); } else { // Set the pen, no brush. QPen pen; pen.setColor(m_referenceColor); pen.setStyle(Qt::SolidLine); pen.setWidth(2); gc->setPen(pen); // Create a 'X' pattern. QLineF cross[2]; cross[0].setLine(-1.5 + m_xAlignment, -1.5 + m_yAlignment, 1.5 + m_xAlignment, 1.5 + m_yAlignment); cross[1].setLine(-1.5 + m_xAlignment, 1.5 + m_yAlignment, 1.5 + m_xAlignment, -1.5 + m_yAlignment); gc->drawLines(cross, 2); } //delete gc; }
void KoTextBlockBorderData::paint(QPainter &painter, const QRectF &bounds) const { QRectF innerBounds = bounds; if (d->edges[Top].outerPen.widthF() > 0) { QPen pen = d->edges[Top].outerPen; painter.setPen(pen); const qreal t = bounds.top() + pen.widthF() / 2.0; painter.drawLine(QLineF(bounds.left(), t, bounds.right(), t)); innerBounds.setTop(bounds.top() + d->edges[Top].distance + pen.widthF()); } if (d->edges[Bottom].outerPen.widthF() > 0) { QPen pen = d->edges[Bottom].outerPen; painter.setPen(pen); const qreal b = bounds.bottom() - pen.widthF() / 2.0; innerBounds.setBottom(bounds.bottom() - d->edges[Bottom].distance - pen.widthF()); painter.drawLine(QLineF(bounds.left(), b, bounds.right(), b)); } if (d->edges[Left].outerPen.widthF() > 0) { QPen pen = d->edges[Left].outerPen; painter.setPen(pen); const qreal l = bounds.left() + pen.widthF() / 2.0; innerBounds.setLeft(bounds.left() + d->edges[Left].distance + pen.widthF()); painter.drawLine(QLineF(l, bounds.top(), l, bounds.bottom())); } if (d->edges[Right].outerPen.widthF() > 0) { QPen pen = d->edges[Right].outerPen; painter.setPen(pen); const qreal r = bounds.right() - pen.widthF() / 2.0; innerBounds.setRight(bounds.right() - d->edges[Right].distance - pen.widthF()); painter.drawLine(QLineF(r, bounds.top(), r, bounds.bottom())); } // inner lines if (d->edges[Top].innerPen.widthF() > 0) { QPen pen = d->edges[Top].innerPen; painter.setPen(pen); const qreal t = innerBounds.top() + pen.widthF() / 2.0; painter.drawLine(QLineF(innerBounds.left(), t, innerBounds.right(), t)); } if (d->edges[Bottom].innerPen.widthF() > 0) { QPen pen = d->edges[Bottom].innerPen; painter.setPen(pen); const qreal b = innerBounds.bottom() - pen.widthF() / 2.0; painter.drawLine(QLineF(innerBounds.left(), b, innerBounds.right(), b)); } if (d->edges[Left].innerPen.widthF() > 0) { QPen pen = d->edges[Left].innerPen; painter.setPen(pen); const qreal l = innerBounds.left() + pen.widthF() / 2.0; painter.drawLine(QLineF(l, innerBounds.top(), l, innerBounds.bottom())); } if (d->edges[Right].innerPen.widthF() > 0) { QPen pen = d->edges[Right].innerPen; painter.setPen(pen); const qreal r = innerBounds.right() - pen.widthF() / 2.0; painter.drawLine(QLineF(r, innerBounds.top(), r, innerBounds.bottom())); } }