/**************************************************************************** ** ** Copyright (C) 2009 Nokia Corporation and/or its subsidiary(-ies). ** Contact: Qt Software Information (qt-info@nokia.com) ** ** This file is part of the QtGui module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** No Commercial Usage ** This file contains pre-release code and may not be distributed. ** You may use this file in accordance with the terms and conditions ** contained in the either Technology Preview License Agreement or the ** Beta Release License Agreement. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 2.1 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 2.1 requirements ** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Nokia gives you certain ** additional rights. These rights are described in the Nokia Qt LGPL ** Exception version 1.0, included in the file LGPL_EXCEPTION.txt in this ** package. ** ** GNU General Public License Usage ** Alternatively, this file may be used under the terms of the GNU ** General Public License version 3.0 as published by the Free Software ** Foundation and appearing in the file LICENSE.GPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU General Public License version 3.0 requirements will be ** met: http://www.gnu.org/copyleft/gpl.html. ** ** If you are unsure which license is appropriate for your use, please ** contact the sales department at qt-sales@nokia.com. ** $QT_END_LICENSE$ ** ****************************************************************************/ static const int QGRAPHICSVIEW_REGION_RECT_THRESHOLD = 50; static const int QGRAPHICSVIEW_PREALLOC_STYLE_OPTIONS = 503; // largest prime < 2^9 /*! \class QGraphicsView \brief The QGraphicsView class provides a widget for displaying the contents of a QGraphicsScene. \since 4.2 \ingroup multimedia \ingroup graphicsview-api \mainclass QGraphicsView visualizes the contents of a QGraphicsScene in a scrollable viewport. To create a scene with geometrical items, see QGraphicsScene's documentation. QGraphicsView is part of \l{The Graphics View Framework}. To visualize a scene, you start by constructing a QGraphicsView object, passing the address of the scene you want to visualize to QGraphicsView's constructor. Alternatively, you can call setScene() to set the scene at a later point. After you call show(), the view will by default scroll to the center of the scene and display any items that are visible at this point. For example: \snippet doc/src/snippets/code/src_gui_graphicsview_qgraphicsview.cpp 0 You can explicitly scroll to any position on the scene by using the scroll bars, or by calling centerOn(). By passing a point to centerOn(), QGraphicsView will scroll its viewport to ensure that the point is centered in the view. An overload is provided for scrolling to a QGraphicsItem, in which case QGraphicsView will see to that the center of the item is centered in the view. If all you want is to ensure that a certain area is visible, (but not necessarily centered,) you can call ensureVisible() instead. QGraphicsView can be used to visualize a whole scene, or only parts of it. The visualized area is by default detected automatically when the view is displayed for the first time (by calling QGraphicsScene::itemsBoundingRect()). To set the visualized area rectangle yourself, you can call setSceneRect(). This will adjust the scroll bars' ranges appropriately. Note that although the scene supports a virtually unlimited size, the range of the scroll bars will never exceed the range of an integer (INT_MIN, INT_MAX). When the scene is larger than the scroll bars' values, you can choose to use translate() to navigate the scene instead. QGraphicsView visualizes the scene by calling render(). By default, the items are drawn onto the viewport by using a regular QPainter, and using default render hints. To change the default render hints that QGraphicsView passes to QPainter when painting items, you can call setRenderHints(). By default, QGraphicsView provides a regular QWidget for the viewport widget. You can access this widget by calling viewport(), or you can replace it by calling setViewport(). To render using OpenGL, simply call setViewport(new QGLWidget). QGraphicsView takes ownership of the viewport widget. QGraphicsView supports affine transformations, using QMatrix. You can either pass a matrix to setMatrix(), or you can call one of the convenience functions rotate(), scale(), translate() or shear(). The most two common transformations are scaling, which is used to implement zooming, and rotation. QGraphicsView keeps the center of the view fixed during a transformation. You can interact with the items on the scene by using the mouse and keyboard. QGraphicsView translates the mouse and key events into \e scene events, (events that inherit QGraphicsSceneEvent,), and forward them to the visualized scene. In the end, it's the individual item that handles the events and reacts to them. For example, if you click on a selectable item, the item will typically let the scene know that it has been selected, and it will also redraw itself to display a selection rectangle. Similiary, if you click and drag the mouse to move a movable item, it's the item that handles the mouse moves and moves itself. Item interaction is enabled by default, and you can toggle it by calling setInteractive(). You can also provide your own custom scene interaction, by creating a subclass of QGraphicsView, and reimplementing the mouse and key event handlers. To simplify how you programmatically interact with items in the view, QGraphicsView provides the mapping functions mapToScene() and mapFromScene(), and the item accessors items() and itemAt(). These functions allow you to map points, rectangles, polygons and paths between view coordinates and scene coordinates, and to find items on the scene using view coordinates. \img graphicsview-view.png \sa QGraphicsScene, QGraphicsItem, QGraphicsSceneEvent */ /*! \enum QGraphicsView::ViewportAnchor This enums describe the possible anchors that QGraphicsView can use when the user resizes the view or when the view is transformed. \value NoAnchor No anchor, i.e. the view leaves the scene's position unchanged. \value AnchorViewCenter The scene point at the center of the view is used as the anchor. \value AnchorUnderMouse The point under the mouse is used as the anchor. \sa resizeAnchor, transformationAnchor */ /*! \enum QGraphicsView::ViewportUpdateMode \since 4.3 This enum describes how QGraphicsView updates its viewport when the scene contents change or are exposed. \value FullViewportUpdate When any visible part of the scene changes or is reexposed, QGraphicsView will update the entire viewport. This approach is fastest when QGraphicsView spends more time figuring out what to draw than it would spend drawing (e.g., when very many small items are repeatedly updated). This is the preferred update mode for viewports that do not support partial updates, such as QGLWidget, and for viewports that need to disable scroll optimization. \value MinimalViewportUpdate QGraphicsView will determine the minimal viewport region that requires a redraw, minimizing the time spent drawing by avoiding a redraw of areas that have not changed. This is QGraphicsView's default mode. Although this approach provides the best performance in general, if there are many small visible changes on the scene, QGraphicsView might end up spending more time finding the minimal approach than it will spend drawing. \value SmartViewportUpdate QGraphicsView will attempt to find an optimal update mode by analyzing the areas that require a redraw. \value BoundingRectViewportUpdate The bounding rectangle of all changes in the viewport will be redrawn. This mode has the advantage that QGraphicsView searches only one region for changes, minimizing time spent determining what needs redrawing. The disadvantage is that areas that have not changed also need to be redrawn. \value NoViewportUpdate QGraphicsView will never update its viewport when the scene changes; the user is expected to control all updates. This mode disables all (potentially slow) item visibility testing in QGraphicsView, and is suitable for scenes that either require a fixed frame rate, or where the viewport is otherwise updated externally. \sa viewportUpdateMode */ /*! \enum QGraphicsView::OptimizationFlag \since 4.3 This enum describes flags that you can enable to improve rendering performance in QGraphicsView. By default, none of these flags are set. Note that setting a flag usually imposes a side effect, and this effect can vary between paint devices and platforms. \value DontClipPainter This value is obsolete and has no effect. \value DontSavePainterState When rendering, QGraphicsView protects the painter state (see QPainter::save()) when rendering the background or foreground, and when rendering each item. This allows you to leave the painter in an altered state (i.e., you can call QPainter::setPen() or QPainter::setBrush() without restoring the state after painting). However, if the items consistently do restore the state, you should enable this flag to prevent QGraphicsView from doing the same. \value DontAdjustForAntialiasing Disables QGraphicsView's antialiasing auto-adjustment of exposed areas. Items that render antialiased lines on the boundaries of their QGraphicsItem::boundingRect() can end up rendering parts of the line outside. To prevent rendering artifacts, QGraphicsView expands all exposed regions by 2 pixels in all directions. If you enable this flag, QGraphicsView will no longer perform these adjustments, minimizing the areas that require redrawing, which improves performance. A common side effect is that items that do draw with antialiasing can leave painting traces behind on the scene as they are moved. */ /*! \enum QGraphicsView::CacheModeFlag This enum describes the flags that you can set for a QGraphicsView's cache mode. \value CacheNone All painting is done directly onto the viewport. \value CacheBackground The background is cached. This affects both custom backgrounds, and backgrounds based on the backgroundBrush property. When this flag is enabled, QGraphicsView will allocate one pixmap with the full size of the viewport. \sa cacheMode */ /*! \enum QGraphicsView::DragMode This enum describes the default action for the view when pressing and dragging the mouse over the viewport. \value NoDrag Nothing happens; the mouse event is ignored. \value ScrollHandDrag The cursor changes into a pointing hand, and dragging the mouse around will scroll the scrolbars. This mode works both in \l{QGraphicsView::interactive}{interactive} and non-interactive mode. \value RubberBandDrag A rubber band will appear. Dragging the mouse will set the rubber band geometry, and all items covered by the rubber band are selected. This mode is disabled for non-interactive views. \sa dragMode, QGraphicsScene::setSelectionArea() */ #include "qgraphicsview.h" #include "qgraphicsview_p.h" #ifndef QT_NO_GRAPHICSVIEW #include "qgraphicsitem.h" #include "qgraphicsitem_p.h" #include "qgraphicsscene.h" #include "qgraphicsscene_p.h" #include "qgraphicssceneevent.h" #include "qgraphicswidget.h" #include #include #include #include #include #include #include #include #include #include #include #include #ifdef Q_WS_X11 #include #endif QT_BEGIN_NAMESPACE inline int q_round_bound(qreal d) //### (int)(qreal) INT_MAX != INT_MAX for single precision { if (d <= (qreal) INT_MIN) return INT_MIN; else if (d >= (qreal) INT_MAX) return INT_MAX; return d >= 0.0 ? int(d + 0.5) : int(d - int(d-1) + 0.5) + int(d-1); } /*! \internal */ QGraphicsViewPrivate::QGraphicsViewPrivate() : renderHints(QPainter::TextAntialiasing), dragMode(QGraphicsView::NoDrag), sceneInteractionAllowed(true), hasSceneRect(false), connectedToScene(false), mousePressButton(Qt::NoButton), identityMatrix(true), dirtyScroll(true), accelerateScrolling(true), leftIndent(0), topIndent(0), lastMouseEvent(QEvent::None, QPoint(), Qt::NoButton, 0, 0), useLastMouseEvent(false), keepLastCenterPoint(true), alignment(Qt::AlignCenter), transforming(false), transformationAnchor(QGraphicsView::AnchorViewCenter), resizeAnchor(QGraphicsView::NoAnchor), viewportUpdateMode(QGraphicsView::MinimalViewportUpdate), optimizationFlags(0), scene(0), #ifndef QT_NO_RUBBERBAND rubberBanding(false), rubberBandSelectionMode(Qt::IntersectsItemShape), #endif handScrolling(false), handScrollMotions(0), cacheMode(0), mustAllocateStyleOptions(false), mustResizeBackgroundPixmap(true), #ifndef QT_NO_CURSOR hasStoredOriginalCursor(false), #endif lastDragDropEvent(0), fullUpdatePending(true), updateSceneSlotReimplementedChecked(false) { styleOptions.reserve(QGRAPHICSVIEW_PREALLOC_STYLE_OPTIONS); } /*! \internal */ void QGraphicsViewPrivate::recalculateContentSize() { Q_Q(QGraphicsView); QSize maxSize = q->maximumViewportSize(); int width = maxSize.width(); int height = maxSize.height(); QRectF viewRect = matrix.mapRect(q->sceneRect()); bool frameOnlyAround = (q->style()->styleHint(QStyle::SH_ScrollView_FrameOnlyAroundContents, 0, q)); if (frameOnlyAround) { if (hbarpolicy == Qt::ScrollBarAlwaysOn) height -= frameWidth * 2; if (vbarpolicy == Qt::ScrollBarAlwaysOn) width -= frameWidth * 2; } // Adjust the maximum width and height of the viewport based on the width // of visible scroll bars. int scrollBarExtent = q->style()->pixelMetric(QStyle::PM_ScrollBarExtent, 0, q); if (frameOnlyAround) scrollBarExtent += frameWidth * 2; bool useHorizontalScrollBar = (viewRect.width() > width) && hbarpolicy != Qt::ScrollBarAlwaysOff; bool useVerticalScrollBar = (viewRect.height() > height) && vbarpolicy != Qt::ScrollBarAlwaysOff; if (useHorizontalScrollBar && !useVerticalScrollBar) { if (viewRect.height() > height - scrollBarExtent) useVerticalScrollBar = true; } if (useVerticalScrollBar && !useHorizontalScrollBar) { if (viewRect.width() > width - scrollBarExtent) useHorizontalScrollBar = true; } if (useHorizontalScrollBar && hbarpolicy != Qt::ScrollBarAlwaysOn) height -= scrollBarExtent; if (useVerticalScrollBar && vbarpolicy != Qt::ScrollBarAlwaysOn) width -= scrollBarExtent; // Setting the ranges of these scroll bars can/will cause the values to // change, and scrollContentsBy() will be called correspondingly. This // will reset the last center point. QPointF savedLastCenterPoint = lastCenterPoint; // Remember the former indent settings qreal oldLeftIndent = leftIndent; qreal oldTopIndent = topIndent; // If the whole scene fits horizontally, we center the scene horizontally, // and ignore the horizontal scroll bars. int left = q_round_bound(viewRect.left()); int right = q_round_bound(viewRect.right() - width); if (left >= right) { hbar->setRange(0, 0); switch (alignment & Qt::AlignHorizontal_Mask) { case Qt::AlignLeft: leftIndent = -viewRect.left(); break; case Qt::AlignRight: leftIndent = width - viewRect.width() - viewRect.left() - 1; break; case Qt::AlignHCenter: default: leftIndent = width / 2 - (viewRect.left() + viewRect.right()) / 2; break; } } else { hbar->setRange(left, right); hbar->setPageStep(width); hbar->setSingleStep(width / 20); leftIndent = 0; } // If the whole scene fits vertically, we center the scene vertically, and // ignore the vertical scroll bars. int top = q_round_bound(viewRect.top()); int bottom = q_round_bound(viewRect.bottom() - height); if (top >= bottom) { vbar->setRange(0, 0); switch (alignment & Qt::AlignVertical_Mask) { case Qt::AlignTop: topIndent = -viewRect.top(); break; case Qt::AlignBottom: topIndent = height - viewRect.height() - viewRect.top() - 1; break; case Qt::AlignVCenter: default: topIndent = height / 2 - (viewRect.top() + viewRect.bottom()) / 2; break; } } else { vbar->setRange(top, bottom); vbar->setPageStep(height); vbar->setSingleStep(height / 20); topIndent = 0; } // Restorethe center point from before the ranges changed. lastCenterPoint = savedLastCenterPoint; // Issue a full update if the indents change. // ### If the transform is still the same, we can get away with just a // scroll instead. if (oldLeftIndent != leftIndent || oldTopIndent != topIndent) { dirtyScroll = true; viewport->update(); } else if (q->isRightToLeft() && !leftIndent) { // In reverse mode, the horizontal scroll always changes after the content // size has changed, as the scroll is calculated by summing the min and // max values of the range and subtracting the current value. In normal // mode the scroll remains unchanged unless the indent has changed. dirtyScroll = true; } if (cacheMode & QGraphicsView::CacheBackground) { // Invalidate the background pixmap mustResizeBackgroundPixmap = true; } } /*! \internal */ void QGraphicsViewPrivate::centerView(QGraphicsView::ViewportAnchor anchor) { Q_Q(QGraphicsView); switch (anchor) { case QGraphicsView::AnchorUnderMouse: { if (q->underMouse()) { // Last scene pos: lastMouseMoveScenePoint // Current mouse pos: QPointF transformationDiff = q->mapToScene(viewport->rect().center()) - q->mapToScene(q->mapFromGlobal(QCursor::pos())); q->centerOn(lastMouseMoveScenePoint + transformationDiff);; } else { q->centerOn(lastCenterPoint); } break; } case QGraphicsView::AnchorViewCenter: q->centerOn(lastCenterPoint); break; case QGraphicsView::NoAnchor: break; } } /*! \internal */ void QGraphicsViewPrivate::updateLastCenterPoint() { Q_Q(QGraphicsView); lastCenterPoint = q->mapToScene(viewport->rect().center()); } /*! \internal Returns the horizontal scroll value (the X value of the left edge of the viewport). */ qint64 QGraphicsViewPrivate::horizontalScroll() const { if (dirtyScroll) const_cast(this)->updateScroll(); return scrollX; } /*! \internal Returns the vertical scroll value (the X value of the top edge of the viewport). */ qint64 QGraphicsViewPrivate::verticalScroll() const { if (dirtyScroll) const_cast(this)->updateScroll(); return scrollY; } /*! \internal */ void QGraphicsViewPrivate::updateScroll() { Q_Q(QGraphicsView); scrollX = qint64(-leftIndent); if (q->isRightToLeft()) { if (!leftIndent) { scrollX += hbar->minimum(); scrollX += hbar->maximum(); scrollX -= hbar->value(); } } else { scrollX += hbar->value(); } scrollY = qint64(vbar->value() - topIndent); dirtyScroll = false; } /*! \internal */ void QGraphicsViewPrivate::replayLastMouseEvent() { if (!useLastMouseEvent || !scene) return; mouseMoveEventHandler(&lastMouseEvent); } /*! \internal */ void QGraphicsViewPrivate::storeMouseEvent(QMouseEvent *event) { useLastMouseEvent = true; lastMouseEvent = QMouseEvent(QEvent::MouseMove, event->pos(), event->globalPos(), event->button(), event->buttons(), event->modifiers()); } void QGraphicsViewPrivate::mouseMoveEventHandler(QMouseEvent *event) { Q_Q(QGraphicsView); storeMouseEvent(event); lastMouseEvent.setAccepted(false); if (!sceneInteractionAllowed) return; if (handScrolling) return; if (!scene) return; QGraphicsSceneMouseEvent mouseEvent(QEvent::GraphicsSceneMouseMove); mouseEvent.setWidget(viewport); mouseEvent.setButtonDownScenePos(mousePressButton, mousePressScenePoint); mouseEvent.setButtonDownScreenPos(mousePressButton, mousePressScreenPoint); mouseEvent.setScenePos(q->mapToScene(event->pos())); mouseEvent.setScreenPos(event->globalPos()); mouseEvent.setLastScenePos(lastMouseMoveScenePoint); mouseEvent.setLastScreenPos(lastMouseMoveScreenPoint); mouseEvent.setButtons(event->buttons()); mouseEvent.setButton(event->button()); mouseEvent.setModifiers(event->modifiers()); lastMouseMoveScenePoint = mouseEvent.scenePos(); lastMouseMoveScreenPoint = mouseEvent.screenPos(); mouseEvent.setAccepted(false); QApplication::sendEvent(scene, &mouseEvent); // Remember whether the last event was accepted or not. lastMouseEvent.setAccepted(mouseEvent.isAccepted()); if (mouseEvent.isAccepted() && mouseEvent.buttons() != 0) { // The event was delivered to a mouse grabber; the press is likely to // have set a cursor, and we must not change it. return; } #ifndef QT_NO_CURSOR // If all the items ignore hover events, we don't look-up any items // in QGraphicsScenePrivate::dispatchHoverEvent, hence the // cachedItemsUnderMouse list will be empty. We therefore do the look-up // for cursor items here if not all items use the default cursor. if (scene->d_func()->allItemsIgnoreHoverEvents && !scene->d_func()->allItemsUseDefaultCursor && scene->d_func()->cachedItemsUnderMouse.isEmpty()) { scene->d_func()->cachedItemsUnderMouse = scene->d_func()->itemsAtPosition(mouseEvent.screenPos(), mouseEvent.scenePos(), mouseEvent.widget()); } // Find the topmost item under the mouse with a cursor. foreach (QGraphicsItem *item, scene->d_func()->cachedItemsUnderMouse) { if (item->hasCursor()) { _q_setViewportCursor(item->cursor()); return; } } // No items with cursors found; revert to the view cursor. if (hasStoredOriginalCursor) { // Restore the original viewport cursor. hasStoredOriginalCursor = false; viewport->setCursor(originalCursor); } #endif } /*! \internal */ #ifndef QT_NO_RUBBERBAND QRegion QGraphicsViewPrivate::rubberBandRegion(const QWidget *widget, const QRect &rect) const { QStyleHintReturnMask mask; QStyleOptionRubberBand option; option.initFrom(widget); option.rect = rect; option.opaque = false; option.shape = QRubberBand::Rectangle; QRegion tmp; tmp += rect; if (widget->style()->styleHint(QStyle::SH_RubberBand_Mask, &option, widget, &mask)) tmp &= mask.region; return tmp; } #endif /*! \internal */ #ifndef QT_NO_CURSOR void QGraphicsViewPrivate::_q_setViewportCursor(const QCursor &cursor) { if (!hasStoredOriginalCursor) { hasStoredOriginalCursor = true; originalCursor = viewport->cursor(); } viewport->setCursor(cursor); } #endif /*! \internal */ #ifndef QT_NO_CURSOR void QGraphicsViewPrivate::_q_unsetViewportCursor() { Q_Q(QGraphicsView); foreach (QGraphicsItem *item, q->items(lastMouseEvent.pos())) { if (item->hasCursor()) { _q_setViewportCursor(item->cursor()); return; } } // Restore the original viewport cursor. hasStoredOriginalCursor = false; if (dragMode == QGraphicsView::ScrollHandDrag) viewport->setCursor(Qt::OpenHandCursor); else viewport->setCursor(originalCursor); } #endif /*! \internal */ void QGraphicsViewPrivate::storeDragDropEvent(const QGraphicsSceneDragDropEvent *event) { delete lastDragDropEvent; lastDragDropEvent = new QGraphicsSceneDragDropEvent(event->type()); lastDragDropEvent->setScenePos(event->scenePos()); lastDragDropEvent->setScreenPos(event->screenPos()); lastDragDropEvent->setButtons(event->buttons()); lastDragDropEvent->setModifiers(event->modifiers()); lastDragDropEvent->setPossibleActions(event->possibleActions()); lastDragDropEvent->setProposedAction(event->proposedAction()); lastDragDropEvent->setDropAction(event->dropAction()); lastDragDropEvent->setMimeData(event->mimeData()); lastDragDropEvent->setWidget(event->widget()); lastDragDropEvent->setSource(event->source()); } /*! \internal */ void QGraphicsViewPrivate::populateSceneDragDropEvent(QGraphicsSceneDragDropEvent *dest, QDropEvent *source) { #ifndef QT_NO_DRAGANDDROP Q_Q(QGraphicsView); dest->setScenePos(q->mapToScene(source->pos())); dest->setScreenPos(q->mapToGlobal(source->pos())); dest->setButtons(source->mouseButtons()); dest->setModifiers(source->keyboardModifiers()); dest->setPossibleActions(source->possibleActions()); dest->setProposedAction(source->proposedAction()); dest->setDropAction(source->dropAction()); dest->setMimeData(source->mimeData()); dest->setWidget(viewport); dest->setSource(source->source()); #else Q_UNUSED(dest) Q_UNUSED(source) #endif } /*! \internal */ QRect QGraphicsViewPrivate::mapToViewRect(const QGraphicsItem *item, const QRectF &rect) const { Q_Q(const QGraphicsView); if (dirtyScroll) const_cast(this)->updateScroll(); if (item->d_ptr->itemIsUntransformable()) { QTransform itv = item->deviceTransform(q->viewportTransform()); return itv.mapRect(rect).toAlignedRect(); } // Translate-only // COMBINE QPointF offset; const QGraphicsItem *parentItem = item; const QGraphicsItemPrivate *itemd; do { itemd = parentItem->d_ptr; if (itemd->transformData) break; offset += itemd->pos; } while ((parentItem = itemd->parent)); QRectF baseRect = rect.translated(offset.x(), offset.y()); if (!parentItem) { if (identityMatrix) { baseRect.translate(-scrollX, -scrollY); return baseRect.toAlignedRect(); } return matrix.mapRect(baseRect).translated(-scrollX, -scrollY).toAlignedRect(); } QTransform tr = parentItem->sceneTransform(); if (!identityMatrix) tr *= matrix; QRectF r = tr.mapRect(baseRect); r.translate(-scrollX, -scrollY); return r.toAlignedRect(); } /*! \internal */ QRegion QGraphicsViewPrivate::mapToViewRegion(const QGraphicsItem *item, const QRectF &rect) const { Q_Q(const QGraphicsView); if (dirtyScroll) const_cast(this)->updateScroll(); // Accurate bounding region QTransform itv = item->deviceTransform(q->viewportTransform()); return item->boundingRegion(itv) & itv.mapRect(rect).toAlignedRect(); } /*! \internal */ void QGraphicsViewPrivate::processPendingUpdates() { if (!scene) return; if (fullUpdatePending) { // We have already called viewport->update() dirtyBoundingRect = QRect(); dirtyRegion = QRegion(); return; } if (viewportUpdateMode == QGraphicsView::BoundingRectViewportUpdate) { if (optimizationFlags & QGraphicsView::DontAdjustForAntialiasing) viewport->update(dirtyBoundingRect); else viewport->update(dirtyBoundingRect.adjusted(-2, -2, 2, 2)); } else { viewport->update(dirtyRegion); // Already adjusted in updateRect/Region. } dirtyBoundingRect = QRect(); dirtyRegion = QRegion(); } void QGraphicsViewPrivate::updateAll() { viewport->update(); fullUpdatePending = true; dirtyBoundingRect = QRect(); dirtyRegion = QRegion(); } void QGraphicsViewPrivate::updateRegion(const QRegion &r) { if (r.isEmpty() || fullUpdatePending) return; // Rect intersects viewport - update everything? switch (viewportUpdateMode) { case QGraphicsView::FullViewportUpdate: fullUpdatePending = true; viewport->update(); break; case QGraphicsView::BoundingRectViewportUpdate: dirtyBoundingRect |= r.boundingRect(); if (dirtyBoundingRect.contains(viewport->rect())) { fullUpdatePending = true; viewport->update(); } break; case QGraphicsView::SmartViewportUpdate: // ### DEPRECATE case QGraphicsView::MinimalViewportUpdate: if (optimizationFlags & QGraphicsView::DontAdjustForAntialiasing) { dirtyRegion += r; } else { const QVector &rects = r.rects(); for (int i = 0; i < rects.size(); ++i) dirtyRegion += rects.at(i).adjusted(-2, -2, 2, 2); } break; case QGraphicsView::NoViewportUpdate: // Unreachable break; } } void QGraphicsViewPrivate::updateRect(const QRect &r) { if (r.isEmpty() || fullUpdatePending) return; // Rect intersects viewport - update everything? switch (viewportUpdateMode) { case QGraphicsView::FullViewportUpdate: fullUpdatePending = true; viewport->update(); break; case QGraphicsView::BoundingRectViewportUpdate: dirtyBoundingRect |= r; if (dirtyBoundingRect.contains(viewport->rect())) { fullUpdatePending = true; viewport->update(); } break; case QGraphicsView::SmartViewportUpdate: // ### DEPRECATE case QGraphicsView::MinimalViewportUpdate: if (optimizationFlags & QGraphicsView::DontAdjustForAntialiasing) dirtyRegion += r; else dirtyRegion += r.adjusted(-2, -2, 2, 2); break; case QGraphicsView::NoViewportUpdate: // Unreachable break; } } QStyleOptionGraphicsItem *QGraphicsViewPrivate::allocStyleOptionsArray(int numItems) { if (mustAllocateStyleOptions || (numItems > styleOptions.capacity())) // too many items, let's allocate on-the-fly return new QStyleOptionGraphicsItem[numItems]; // expand only whenever necessary if (numItems > styleOptions.size()) styleOptions.resize(numItems); mustAllocateStyleOptions = true; return styleOptions.data(); } void QGraphicsViewPrivate::freeStyleOptionsArray(QStyleOptionGraphicsItem *array) { mustAllocateStyleOptions = false; if (array != styleOptions.data()) delete [] array; } extern QPainterPath qt_regionToPath(const QRegion ®ion); /*! ### Adjustments in findItems: mapToScene(QRect) forces us to adjust the input rectangle by (0, 0, 1, 1), because it uses QRect::bottomRight() (etc) when mapping the rectangle to a polygon (which is _wrong_). In addition, as QGraphicsItem::boundingRect() is defined in logical space, but the default pen for QPainter is cosmetic with a width of 0, QPainter is at risk of painting 1 pixel outside the bounding rect. Therefore we must search for items with an adjustment of (-1, -1, 1, 1). */ QList QGraphicsViewPrivate::findItems(const QRegion &exposedRegion, bool *allItems) const { Q_Q(const QGraphicsView); // Step 1) If all items are contained within the expose region, then // return a list of all visible items. const QRectF exposedRegionSceneBounds = q->mapToScene(exposedRegion.boundingRect().adjusted(-1, -1, 1, 1)) .boundingRect(); if (exposedRegionSceneBounds.contains(scene->d_func()->growingItemsBoundingRect)) { Q_ASSERT(allItems); *allItems = true; // All items are guaranteed within the exposed region, don't bother using the index. QList itemList(scene->d_func()->index->items(Qt::DescendingOrder)); int i = 0; while (i < itemList.size()) { const QGraphicsItem *item = itemList.at(i); // But we only want to include items that are visible // The following check is basically the same as item->d_ptr->isInvisible(), except // that we don't check whether the item clips children to shape or propagates its // opacity (we loop through all items, so those checks are wrong in this context). if (!item->isVisible() || item->d_ptr->isClippedAway() || item->d_ptr->isFullyTransparent()) itemList.removeAt(i); else ++i; } return itemList; } // Step 2) If the expose region is a simple rect and the view is only // translated or scaled, search for items using // QGraphicsScene::items(QRectF). bool simpleRectLookup = (scene->d_func()->largestUntransformableItem.isNull() && exposedRegion.numRects() == 1 && matrix.type() <= QTransform::TxScale); if (simpleRectLookup) { return scene->d_func()->index->items(exposedRegionSceneBounds, Qt::IntersectsItemBoundingRect, Qt::DescendingOrder); } // If the region is complex or the view has a complex transform, adjust // the expose region, convert it to a path, and then search for items // using QGraphicsScene::items(QPainterPath); QRegion adjustedRegion; foreach (const QRect &r, exposedRegion.rects()) adjustedRegion += r.adjusted(-1, -1, 1, 1); const QPainterPath exposedPath(qt_regionToPath(adjustedRegion)); if (scene->d_func()->largestUntransformableItem.isNull()) { const QPainterPath exposedScenePath(q->mapToScene(exposedPath)); return scene->d_func()->index->items(exposedScenePath, Qt::IntersectsItemBoundingRect, Qt::DescendingOrder); } // NB! Path must be in viewport coordinates. return itemsInArea(exposedPath, Qt::IntersectsItemBoundingRect, Qt::DescendingOrder); } /*! Constructs a QGraphicsView. \a parent is passed to QWidget's constructor. */ QGraphicsView::QGraphicsView(QWidget *parent) : QAbstractScrollArea(*new QGraphicsViewPrivate, parent) { setViewport(0); setAcceptDrops(true); setBackgroundRole(QPalette::Base); // ### Ideally this would be enabled/disabled depending on whether any // widgets in the current scene enabled input methods. We could do that // using a simple reference count. The same goes for acceptDrops and mouse // tracking. setAttribute(Qt::WA_InputMethodEnabled); } /*! Constructs a QGraphicsView and sets the visualized scene to \a scene. \a parent is passed to QWidget's constructor. */ QGraphicsView::QGraphicsView(QGraphicsScene *scene, QWidget *parent) : QAbstractScrollArea(*new QGraphicsViewPrivate, parent) { setScene(scene); setViewport(0); setAcceptDrops(true); setBackgroundRole(QPalette::Base); setAttribute(Qt::WA_InputMethodEnabled); } /*! \internal */ QGraphicsView::QGraphicsView(QGraphicsViewPrivate &dd, QWidget *parent) : QAbstractScrollArea(dd, parent) { setViewport(0); setAcceptDrops(true); setBackgroundRole(QPalette::Base); setAttribute(Qt::WA_InputMethodEnabled); } /*! Destructs the QGraphicsView object. */ QGraphicsView::~QGraphicsView() { Q_D(QGraphicsView); if (d->scene) d->scene->d_func()->views.removeAll(this); delete d->lastDragDropEvent; } /*! \reimp */ QSize QGraphicsView::sizeHint() const { Q_D(const QGraphicsView); if (d->scene) { QSizeF baseSize = d->matrix.mapRect(sceneRect()).size(); baseSize += QSizeF(d->frameWidth * 2, d->frameWidth * 2); return baseSize.boundedTo((3 * QApplication::desktop()->size()) / 4).toSize(); } return QAbstractScrollArea::sizeHint(); } /*! \property QGraphicsView::renderHints \brief the default render hints for the view These hints are used to initialize QPainter before each visible item is drawn. QPainter uses render hints to toggle rendering features such as antialiasing and smooth pixmap transformation. QPainter::TextAntialiasing is enabled by default. Example: \snippet doc/src/snippets/code/src_gui_graphicsview_qgraphicsview.cpp 1 */ QPainter::RenderHints QGraphicsView::renderHints() const { Q_D(const QGraphicsView); return d->renderHints; } void QGraphicsView::setRenderHints(QPainter::RenderHints hints) { Q_D(QGraphicsView); if (hints == d->renderHints) return; d->renderHints = hints; viewport()->update(); } /*! If \a enabled is true, the render hint \a hint is enabled; otherwise it is disabled. \sa renderHints */ void QGraphicsView::setRenderHint(QPainter::RenderHint hint, bool enabled) { Q_D(QGraphicsView); QPainter::RenderHints oldHints = d->renderHints; if (enabled) d->renderHints |= hint; else d->renderHints &= ~hint; if (oldHints != d->renderHints) viewport()->update(); } /*! \property QGraphicsView::alignment \brief the alignment of the scene in the view when the whole scene is visible. If the whole scene is visible in the view, (i.e., there are no visible scroll bars,) the view's alignment will decide where the scene will be rendered in the view. For example, if the alignment is Qt::AlignCenter, which is default, the scene will be centered in the view, and if the alignment is (Qt::AlignLeft | Qt::AlignTop), the scene will be rendered in the top-left corner of the view. */ Qt::Alignment QGraphicsView::alignment() const { Q_D(const QGraphicsView); return d->alignment; } void QGraphicsView::setAlignment(Qt::Alignment alignment) { Q_D(QGraphicsView); if (d->alignment != alignment) { d->alignment = alignment; d->recalculateContentSize(); } } /*! \property QGraphicsView::transformationAnchor \brief how the view should position the scene during transformations. QGraphicsView uses this property to decide how to position the scene in the viewport when the transformation matrix changes, and the coordinate system of the view is transformed. The default behavior, AnchorViewCenter, ensures that the scene point at the center of the view remains unchanged during transformations (e.g., when rotating, the scene will appear to rotate around the center of the view). Note that the effect of this property is noticeable when only a part of the scene is visible (i.e., when there are scroll bars). Otherwise, if the whole scene fits in the view, QGraphicsScene uses the view \l alignment to position the scene in the view. \sa alignment, resizeAnchor */ QGraphicsView::ViewportAnchor QGraphicsView::transformationAnchor() const { Q_D(const QGraphicsView); return d->transformationAnchor; } void QGraphicsView::setTransformationAnchor(ViewportAnchor anchor) { Q_D(QGraphicsView); d->transformationAnchor = anchor; } /*! \property QGraphicsView::resizeAnchor \brief how the view should position the scene when the view is resized. QGraphicsView uses this property to decide how to position the scene in the viewport when the viewport widget's size changes. The default behavior, NoAnchor, leaves the scene's position unchanged during a resize; the top-left corner of the view will appear to be anchored while resizing. Note that the effect of this property is noticeable when only a part of the scene is visible (i.e., when there are scroll bars). Otherwise, if the whole scene fits in the view, QGraphicsScene uses the view \l alignment to position the scene in the view. \sa alignment, transformationAnchor, Qt::WNorthWestGravity */ QGraphicsView::ViewportAnchor QGraphicsView::resizeAnchor() const { Q_D(const QGraphicsView); return d->resizeAnchor; } void QGraphicsView::setResizeAnchor(ViewportAnchor anchor) { Q_D(QGraphicsView); d->resizeAnchor = anchor; } /*! \property QGraphicsView::viewportUpdateMode \brief how the viewport should update its contents. \since 4.3 QGraphicsView uses this property to decide how to update areas of the scene that have been reexposed or changed. Usually you do not need to modify this property, but there are some cases where doing so can improve rendering performance. See the ViewportUpdateMode documentation for specific details. The default value is MinimalViewportUpdate, where QGraphicsView will update as small an area of the viewport as possible when the contents change. \sa ViewportUpdateMode, cacheMode */ QGraphicsView::ViewportUpdateMode QGraphicsView::viewportUpdateMode() const { Q_D(const QGraphicsView); return d->viewportUpdateMode; } void QGraphicsView::setViewportUpdateMode(ViewportUpdateMode mode) { Q_D(QGraphicsView); d->viewportUpdateMode = mode; } /*! \property QGraphicsView::optimizationFlags \brief flags that can be used to tune QGraphicsView's performance. \since 4.3 QGraphicsView uses clipping, extra bounding rect adjustments, and certain other aids to improve rendering quality and performance for the common case graphics scene. However, depending on the target platform, the scene, and the viewport in use, some of these operations can degrade performance. The effect varies from flag to flag; see the OptimizationFlags documentation for details. By default, no optimization flags are enabled. \sa setOptimizationFlag() */ QGraphicsView::OptimizationFlags QGraphicsView::optimizationFlags() const { Q_D(const QGraphicsView); return d->optimizationFlags; } void QGraphicsView::setOptimizationFlags(OptimizationFlags flags) { Q_D(QGraphicsView); d->optimizationFlags = flags; } /*! Enables \a flag if \a enabled is true; otherwise disables \a flag. \sa optimizationFlags */ void QGraphicsView::setOptimizationFlag(OptimizationFlag flag, bool enabled) { Q_D(QGraphicsView); if (enabled) d->optimizationFlags |= flag; else d->optimizationFlags &= ~flag; } /*! \property QGraphicsView::dragMode \brief the behavior for dragging the mouse over the scene while the left mouse button is pressed. This property defines what should happen when the user clicks on the scene background and drags the mouse (e.g., scrolling the viewport contents using a pointing hand cursor, or selecting multiple items with a rubber band). The default value, NoDrag, does nothing. This behavior only affects mouse clicks that are not handled by any item. You can define a custom behavior by creating a subclass of QGraphicsView and reimplementing mouseMoveEvent(). */ QGraphicsView::DragMode QGraphicsView::dragMode() const { Q_D(const QGraphicsView); return d->dragMode; } void QGraphicsView::setDragMode(DragMode mode) { Q_D(QGraphicsView); if (d->dragMode == mode) return; #ifndef QT_NO_CURSOR if (d->dragMode == ScrollHandDrag) viewport()->unsetCursor(); #endif // If dragMode is unset while dragging, e.g. via a keyEvent, we // don't unset the handScrolling state. When enabling scrolling // again the mouseMoveEvent will automatically start scrolling, // without a mousePress if (d->dragMode == ScrollHandDrag && mode == NoDrag && d->handScrolling) d->handScrolling = false; d->dragMode = mode; #ifndef QT_NO_CURSOR if (d->dragMode == ScrollHandDrag) { // Forget the stored viewport cursor when we enter scroll hand drag mode. d->hasStoredOriginalCursor = false; viewport()->setCursor(Qt::OpenHandCursor); } #endif } #ifndef QT_NO_RUBBERBAND /*! \property QGraphicsView::rubberBandSelectionMode \brief the behavior for selecting items with a rubber band selection rectangle. \since 4.3 This property defines how items are selected when using the RubberBandDrag drag mode. The default value is Qt::IntersectsItemShape; all items whose shape intersects with or is contained by the rubber band are selected. \sa dragMode, items() */ Qt::ItemSelectionMode QGraphicsView::rubberBandSelectionMode() const { Q_D(const QGraphicsView); return d->rubberBandSelectionMode; } void QGraphicsView::setRubberBandSelectionMode(Qt::ItemSelectionMode mode) { Q_D(QGraphicsView); d->rubberBandSelectionMode = mode; } #endif /*! \property QGraphicsView::cacheMode \brief which parts of the view are cached QGraphicsView can cache pre-rendered content in a QPixmap, which is then drawn onto the viewport. The purpose of such caching is to speed up the total rendering time for areas that are slow to render. Texture, gradient and alpha blended backgrounds, for example, can be notibly slow to render; especially with a transformed view. The CacheBackground flag enables caching of the view's background. For example: \snippet doc/src/snippets/code/src_gui_graphicsview_qgraphicsview.cpp 2 The cache is invalidated every time the view is transformed. However, when scrolling, only partial invalidation is required. By default, nothing is cached. \sa resetCachedContent(), QPixmapCache */ QGraphicsView::CacheMode QGraphicsView::cacheMode() const { Q_D(const QGraphicsView); return d->cacheMode; } void QGraphicsView::setCacheMode(CacheMode mode) { Q_D(QGraphicsView); if (mode == d->cacheMode) return; d->cacheMode = mode; resetCachedContent(); } /*! Resets any cached content. Calling this function will clear QGraphicsView's cache. If the current cache mode is \l CacheNone, this function does nothing. This function is called automatically for you when the backgroundBrush or QGraphicsScene::backgroundBrush properties change; you only need to call this function if you have reimplemented QGraphicsScene::drawBackground() or QGraphicsView::drawBackground() to draw a custom background, and need to trigger a full redraw. \sa cacheMode() */ void QGraphicsView::resetCachedContent() { Q_D(QGraphicsView); if (d->cacheMode == CacheNone) return; if (d->cacheMode & CacheBackground) { // Background caching is enabled. d->mustResizeBackgroundPixmap = true; viewport()->update(); } else if (d->mustResizeBackgroundPixmap) { // Background caching is disabled. // Cleanup, free some resources. d->mustResizeBackgroundPixmap = false; d->backgroundPixmap = QPixmap(); d->backgroundPixmapExposed = QRegion(); } } /*! Invalidates and schedules a redraw of \a layers inside \a rect. \a rect is in scene coordinates. Any cached content for \a layers inside \a rect is unconditionally invalidated and redrawn. You can call this function to notify QGraphicsView of changes to the background or the foreground of the scene. It is commonly used for scenes with tile-based backgrounds to notify changes when QGraphicsView has enabled background caching. Note that QGraphicsView currently supports background caching only (see QGraphicsView::CacheBackground). This function is equivalent to calling update() if any layer but QGraphicsScene::BackgroundLayer is passed. \sa QGraphicsScene::invalidate(), update() */ void QGraphicsView::invalidateScene(const QRectF &rect, QGraphicsScene::SceneLayers layers) { Q_D(QGraphicsView); if ((layers & QGraphicsScene::BackgroundLayer) && !d->mustResizeBackgroundPixmap) { QRect viewRect = mapFromScene(rect).boundingRect(); if (viewport()->rect().intersects(viewRect)) { // The updated background area is exposed; schedule this area for // redrawing. d->backgroundPixmapExposed += viewRect; if (d->scene) d->scene->update(rect); } } } /*! \property QGraphicsView::interactive \brief whether the view allowed scene interaction. If enabled, this view is set to allow scene interaction. Otherwise, this view will not allow interaction, and any mouse or key events are ignored (i.e., it will act as a read-only view). By default, this property is true. */ bool QGraphicsView::isInteractive() const { Q_D(const QGraphicsView); return d->sceneInteractionAllowed; } void QGraphicsView::setInteractive(bool allowed) { Q_D(QGraphicsView); d->sceneInteractionAllowed = allowed; } /*! Returns a pointer to the scene that is currently visualized in the view. If no scene is currently visualized, 0 is returned. \sa setScene() */ QGraphicsScene *QGraphicsView::scene() const { Q_D(const QGraphicsView); return d->scene; } /*! Sets the current scene to \a scene. If \a scene is already being viewed, this function does nothing. When a scene is set on a view, the QGraphicsScene::changed() signal is automatically connected to this view's updateScene() slot, and the view's scroll bars are adjusted to fit the size of the scene. */ void QGraphicsView::setScene(QGraphicsScene *scene) { Q_D(QGraphicsView); if (d->scene == scene) return; // Always update the viewport when the scene changes. viewport()->update(); // Remove the previously assigned scene. if (d->scene) { disconnect(d->scene, SIGNAL(changed(QList)), this, SLOT(updateScene(QList))); disconnect(d->scene, SIGNAL(sceneRectChanged(QRectF)), this, SLOT(updateSceneRect(QRectF))); d->scene->d_func()->views.removeAll(this); d->connectedToScene = false; } // Assign the new scene and update the contents (scrollbars, etc.)). if ((d->scene = scene)) { connect(d->scene, SIGNAL(sceneRectChanged(QRectF)), this, SLOT(updateSceneRect(QRectF))); d->updateSceneSlotReimplementedChecked = false; d->scene->d_func()->views << this; d->recalculateContentSize(); d->lastCenterPoint = sceneRect().center(); d->keepLastCenterPoint = true; // We are only interested in mouse tracking if items accept // hover events or use non-default cursors. if (!d->scene->d_func()->allItemsIgnoreHoverEvents || !d->scene->d_func()->allItemsUseDefaultCursor) { d->viewport->setMouseTracking(true); } } else { d->recalculateContentSize(); } } /*! \property QGraphicsView::sceneRect \brief the area of the scene visualized by this view. The scene rectangle defines the extent of the scene, and in the view's case, this means the area of the scene that you can navigate using the scroll bars. If unset, or if a null QRectF is set, this property has the same value as QGraphicsScene::sceneRect, and it changes with QGraphicsScene::sceneRect. Otherwise, the view's scene rect is unaffected by the scene. Note that, although the scene supports a virtually unlimited size, the range of the scroll bars will never exceed the range of an integer (INT_MIN, INT_MAX). When the scene is larger than the scroll bars' values, you can choose to use translate() to navigate the scene instead. By default, this property contains a rectangle at the origin with zero width and height. \sa QGraphicsScene::sceneRect */ QRectF QGraphicsView::sceneRect() const { Q_D(const QGraphicsView); if (d->hasSceneRect) return d->sceneRect; if (d->scene) return d->scene->sceneRect(); return QRectF(); } void QGraphicsView::setSceneRect(const QRectF &rect) { Q_D(QGraphicsView); d->hasSceneRect = !rect.isNull(); d->sceneRect = rect; d->recalculateContentSize(); } /*! Returns the current transformation matrix for the view. If no current transformation is set, the identity matrix is returned. \sa setMatrix(), rotate(), scale(), shear(), translate() */ QMatrix QGraphicsView::matrix() const { Q_D(const QGraphicsView); return d->matrix.toAffine(); } /*! Sets the view's current transformation matrix to \a matrix. If \a combine is true, then \a matrix is combined with the current matrix; otherwise, \a matrix \e replaces the current matrix. \a combine is false by default. The transformation matrix tranforms the scene into view coordinates. Using the default transformation, provided by the identity matrix, one pixel in the view represents one unit in the scene (e.g., a 10x10 rectangular item is drawn using 10x10 pixels in the view). If a 2x2 scaling matrix is applied, the scene will be drawn in 1:2 (e.g., a 10x10 rectangular item is then drawn using 20x20 pixels in the view). Example: \snippet doc/src/snippets/code/src_gui_graphicsview_qgraphicsview.cpp 3 To simplify interation with items using a transformed view, QGraphicsView provides mapTo... and mapFrom... functions that can translate between scene and view coordinates. For example, you can call mapToScene() to map a view coordinate to a floating point scene coordinate, or mapFromScene() to map from floating point scene coordinates to view coordinates. \sa matrix(), rotate(), scale(), shear(), translate() */ void QGraphicsView::setMatrix(const QMatrix &matrix, bool combine) { setTransform(QTransform(matrix), combine); } /*! Resets the view transformation matrix to the identity matrix. */ void QGraphicsView::resetMatrix() { resetTransform(); } /*! Rotates the current view transformation \a angle degrees clockwise. \sa setMatrix(), matrix(), scale(), shear(), translate() */ void QGraphicsView::rotate(qreal angle) { Q_D(QGraphicsView); QTransform matrix = d->matrix; matrix.rotate(angle); setTransform(matrix); } /*! Scales the current view transformation by (\a sx, \a sy). \sa setMatrix(), matrix(), rotate(), shear(), translate() */ void QGraphicsView::scale(qreal sx, qreal sy) { Q_D(QGraphicsView); QTransform matrix = d->matrix; matrix.scale(sx, sy); setTransform(matrix); } /*! Shears the current view transformation by (\a sh, \a sv). \sa setMatrix(), matrix(), rotate(), scale(), translate() */ void QGraphicsView::shear(qreal sh, qreal sv) { Q_D(QGraphicsView); QTransform matrix = d->matrix; matrix.shear(sh, sv); setTransform(matrix); } /*! Translates the current view transformation by (\a dx, \a dy). \sa setMatrix(), matrix(), rotate(), shear() */ void QGraphicsView::translate(qreal dx, qreal dy) { Q_D(QGraphicsView); QTransform matrix = d->matrix; matrix.translate(dx, dy); setTransform(matrix); } /*! Scrolls the contents of the viewport to ensure that the scene coordinate \a pos, is centered in the view. Because \a pos is a floating point coordinate, and the scroll bars operate on integer coordinates, the centering is only an approximation. \note If the item is close to or outside the border, it will be visible in the view, but not centered. \sa ensureVisible() */ void QGraphicsView::centerOn(const QPointF &pos) { Q_D(QGraphicsView); qreal width = viewport()->width(); qreal height = viewport()->height(); QPointF viewPoint = d->matrix.map(pos); QPointF oldCenterPoint = pos; if (!d->leftIndent) { if (isRightToLeft()) { qint64 horizontal = 0; horizontal += horizontalScrollBar()->minimum(); horizontal += horizontalScrollBar()->maximum(); horizontal -= int(viewPoint.x() - width / 2.0); horizontalScrollBar()->setValue(horizontal); } else { horizontalScrollBar()->setValue(int(viewPoint.x() - width / 2.0)); } } if (!d->topIndent) verticalScrollBar()->setValue(int(viewPoint.y() - height / 2.0)); d->lastCenterPoint = oldCenterPoint; } /*! \fn QGraphicsView::centerOn(qreal x, qreal y) \overload This function is provided for convenience. It's equivalent to calling centerOn(QPointF(\a x, \a y)). */ /*! \overload Scrolls the contents of the viewport to ensure that \a item is centered in the view. \sa ensureVisible() */ void QGraphicsView::centerOn(const QGraphicsItem *item) { centerOn(item->sceneBoundingRect().center()); } /*! Scrolls the contents of the viewport so that the scene rectangle \a rect is visible, with margins specified in pixels by \a xmargin and \a ymargin. If the specified rect cannot be reached, the contents are scrolled to the nearest valid position. The default value for both margins is 50 pixels. \sa centerOn() */ void QGraphicsView::ensureVisible(const QRectF &rect, int xmargin, int ymargin) { Q_D(QGraphicsView); Q_UNUSED(xmargin); Q_UNUSED(ymargin); qreal width = viewport()->width(); qreal height = viewport()->height(); QRectF viewRect = d->matrix.mapRect(rect); qreal left = d->horizontalScroll(); qreal right = left + width; qreal top = d->verticalScroll(); qreal bottom = top + height; if (viewRect.left() <= left + xmargin) { // need to scroll from the left if (!d->leftIndent) horizontalScrollBar()->setValue(int(viewRect.left() - xmargin - 0.5)); } if (viewRect.right() >= right - xmargin) { // need to scroll from the right if (!d->leftIndent) horizontalScrollBar()->setValue(int(viewRect.right() - width + xmargin + 0.5)); } if (viewRect.top() <= top + ymargin) { // need to scroll from the top if (!d->topIndent) verticalScrollBar()->setValue(int(viewRect.top() - ymargin - 0.5)); } if (viewRect.bottom() >= bottom - ymargin) { // need to scroll from the bottom if (!d->topIndent) verticalScrollBar()->setValue(int(viewRect.bottom() - height + ymargin + 0.5)); } } /*! \fn QGraphicsView::ensureVisible(qreal x, qreal y, qreal w, qreal h, int xmargin, int ymargin) \overload This function is provided for convenience. It's equivalent to calling ensureVisible(QRectF(\a x, \a y, \a w, \a h), \a xmargin, \a ymargin). */ /*! \overload Scrolls the contents of the viewport so that the center of item \a item is visible, with margins specified in pixels by \a xmargin and \a ymargin. If the specified point cannot be reached, the contents are scrolled to the nearest valid position. The default value for both margins is 50 pixels. \sa centerOn() */ void QGraphicsView::ensureVisible(const QGraphicsItem *item, int xmargin, int ymargin) { ensureVisible(item->sceneBoundingRect(), xmargin, ymargin); } /*! Scales the view matrix and scrolls the scroll bars to ensure that the scene rectangle \a rect fits inside the viewport. \a rect must be inside the scene rect; otherwise, fitInView() cannot guarantee that the whole rect is visible. This function keeps the view's rotation, translation, or shear. The view is scaled according to \a aspectRatioMode. \a rect will be centered in the view if it does not fit tightly. It's common to call fitInView() from inside a reimplementation of resizeEvent(), to ensure that the whole scene, or parts of the scene, scales automatically to fit the new size of the viewport as the view is resized. Note though, that calling fitInView() from inside resizeEvent() can lead to unwanted resize recursion, if the new transformation toggles the automatic state of the scrollbars. You can toggle the scrollbar policies to always on or always off to prevent this (see horizontalScrollBarPolicy() and verticalScrollBarPolicy()). If \a rect is empty, or if the viewport is too small, this function will do nothing. \sa setMatrix(), ensureVisible(), centerOn() */ void QGraphicsView::fitInView(const QRectF &rect, Qt::AspectRatioMode aspectRatioMode) { Q_D(QGraphicsView); if (!d->scene || rect.isNull()) return; // Reset the view scale to 1:1. QRectF unity = d->matrix.mapRect(QRectF(0, 0, 1, 1)); if (unity.isEmpty()) return; scale(1 / unity.width(), 1 / unity.height()); // Find the ideal x / y scaling ratio to fit \a rect in the view. int margin = 2; QRectF viewRect = viewport()->rect().adjusted(margin, margin, -margin, -margin); if (viewRect.isEmpty()) return; QRectF sceneRect = d->matrix.mapRect(rect); if (sceneRect.isEmpty()) return; qreal xratio = viewRect.width() / sceneRect.width(); qreal yratio = viewRect.height() / sceneRect.height(); // Respect the aspect ratio mode. switch (aspectRatioMode) { case Qt::KeepAspectRatio: xratio = yratio = qMin(xratio, yratio); break; case Qt::KeepAspectRatioByExpanding: xratio = yratio = qMax(xratio, yratio); break; case Qt::IgnoreAspectRatio: break; } // Scale and center on the center of \a rect. scale(xratio, yratio); centerOn(rect.center()); } /*! \fn void QGraphicsView::fitInView(qreal x, qreal y, qreal w, qreal h, Qt::AspectRatioMode aspectRatioMode = Qt::IgnoreAspectRatio) \overload This convenience function is equivalent to calling fitInView(QRectF(\a x, \a y, \a w, \a h), \a aspectRatioMode). \sa ensureVisible(), centerOn() */ /*! \overload Ensures that \a item fits tightly inside the view, scaling the view according to \a aspectRatioMode. \sa ensureVisible(), centerOn() */ void QGraphicsView::fitInView(const QGraphicsItem *item, Qt::AspectRatioMode aspectRatioMode) { QPainterPath path = item->isClipped() ? item->clipPath() : item->shape(); fitInView(item->sceneTransform().map(path).boundingRect(), aspectRatioMode); } /*! Renders the \a source rect, which is in view coordinates, from the scene into \a target, which is in paint device coordinates, using \a painter. This function is useful for capturing the contents of the view onto a paint device, such as a QImage (e.g., to take a screenshot), or for printing to QPrinter. For example: \snippet doc/src/snippets/code/src_gui_graphicsview_qgraphicsview.cpp 4 If \a source is a null rect, this function will use viewport()->rect() to determine what to draw. If \a target is a null rect, the full dimensions of \a painter's paint device (e.g., for a QPrinter, the page size) will be used. The source rect contents will be transformed according to \a aspectRatioMode to fit into the target rect. By default, the aspect ratio is kept, and \a source is scaled to fit in \a target. \sa QGraphicsScene::render() */ void QGraphicsView::render(QPainter *painter, const QRectF &target, const QRect &source, Qt::AspectRatioMode aspectRatioMode) { Q_D(QGraphicsView); if (!d->scene || !(painter && painter->isActive())) return; // Default source rect = viewport rect QRect sourceRect = source; if (source.isNull()) sourceRect = viewport()->rect(); // Default target rect = device rect QRectF targetRect = target; if (target.isNull()) { if (painter->device()->devType() == QInternal::Picture) targetRect = sourceRect; else targetRect.setRect(0, 0, painter->device()->width(), painter->device()->height()); } // Find the ideal x / y scaling ratio to fit \a source into \a target. qreal xratio = targetRect.width() / sourceRect.width(); qreal yratio = targetRect.height() / sourceRect.height(); // Scale according to the aspect ratio mode. switch (aspectRatioMode) { case Qt::KeepAspectRatio: xratio = yratio = qMin(xratio, yratio); break; case Qt::KeepAspectRatioByExpanding: xratio = yratio = qMax(xratio, yratio); break; case Qt::IgnoreAspectRatio: break; } // Find all items to draw, and reverse the list (we want to draw // in reverse order). QPolygonF sourceScenePoly = mapToScene(sourceRect.adjusted(-1, -1, 1, 1)); QList itemList = d->scene->items(sourceScenePoly, Qt::IntersectsItemBoundingRect); QGraphicsItem **itemArray = new QGraphicsItem *[itemList.size()]; int numItems = itemList.size(); for (int i = 0; i < numItems; ++i) itemArray[numItems - i - 1] = itemList.at(i); itemList.clear(); // Setup painter matrix. QTransform moveMatrix; moveMatrix.translate(-d->horizontalScroll(), -d->verticalScroll()); QTransform painterMatrix = d->matrix * moveMatrix; painterMatrix *= QTransform() .translate(targetRect.left(), targetRect.top()) .scale(xratio, yratio) .translate(-sourceRect.left(), -sourceRect.top()); // Generate the style options QStyleOptionGraphicsItem *styleOptionArray = d->allocStyleOptionsArray(numItems); for (int i = 0; i < numItems; ++i) itemArray[i]->d_ptr->initStyleOption(&styleOptionArray[i], painterMatrix, targetRect.toRect()); painter->save(); // Clip in device coordinates to avoid QRegion transformations. painter->setClipRect(targetRect); QPainterPath path; path.addPolygon(sourceScenePoly); path.closeSubpath(); painter->setClipPath(painterMatrix.map(path), Qt::IntersectClip); // Transform the painter. painter->setTransform(painterMatrix, true); // Render the scene. QRectF sourceSceneRect = sourceScenePoly.boundingRect(); drawBackground(painter, sourceSceneRect); drawItems(painter, numItems, itemArray, styleOptionArray); drawForeground(painter, sourceSceneRect); delete [] itemArray; d->freeStyleOptionsArray(styleOptionArray); painter->restore(); } /*! Returns a list of all the items in the associated scene. \sa QGraphicsScene::items() */ QList QGraphicsView::items() const { Q_D(const QGraphicsView); if (!d->scene) return QList(); return d->scene->items(); } /*! Returns all items in the area \a path, which is in viewport coordinates, also taking untransformable items into consideration. This function is considerably slower than just checking the scene directly. There is certainly room for improvement. */ QList QGraphicsViewPrivate::itemsInArea(const QPainterPath &path, Qt::ItemSelectionMode mode, Qt::SortOrder order) const { Q_Q(const QGraphicsView); // Determine the size of the largest untransformable subtree of children // mapped to scene coordinates. QRectF untr = scene->d_func()->largestUntransformableItem; QRectF ltri = matrix.inverted().mapRect(untr); ltri.adjust(-untr.width(), -untr.height(), untr.width(), untr.height()); QRectF rect = path.controlPointRect(); // Find all possible items in the relevant area. // ### Improve this algorithm; it might be searching a too large area. QRectF adjustedRect = q->mapToScene(rect.adjusted(-1, -1, 1, 1).toRect()).boundingRect(); adjustedRect.adjust(-ltri.width(), -ltri.height(), ltri.width(), ltri.height()); // First build a (potentially large) list of all items in the vicinity // that might be untransformable. QList allCandidates = scene->d_func()->index->estimateItems(adjustedRect, order, q->transform()); // Then find the minimal list of items that are inside \a path, and // convert it to a set. QList regularCandidates = scene->items(q->mapToScene(path), mode, order, q->transform()); QSet candSet = QSet::fromList(regularCandidates); QTransform viewMatrix = q->viewportTransform(); QList result; //### this will disapear // Run through all candidates and keep all items that are in candSet, or // are untransformable and collide with \a path. ### We can improve this // algorithm. QList::Iterator it = allCandidates.begin(); while (it != allCandidates.end()) { QGraphicsItem *item = *it; if (item->d_ptr->itemIsUntransformable()) { // Check if this untransformable item collides with the // original selection rect. QTransform itemTransform = item->deviceTransform(viewMatrix); if (QGraphicsScenePrivate::itemCollidesWithPath(item, itemTransform.inverted().map(path), mode)) result << item; } else { if (candSet.contains(item)) result << item; } ++it; } return result; } /*! Returns a list of all the items at the position \a pos in the view. The items are listed in descending Z order (i.e., the first item in the list is the top-most item, and the last item is the bottom-most item). \a pos is in viewport coordinates. This function is most commonly called from within mouse event handlers in a subclass in QGraphicsView. \a pos is in untransformed viewport coordinates, just like QMouseEvent::pos(). \snippet doc/src/snippets/code/src_gui_graphicsview_qgraphicsview.cpp 5 \sa QGraphicsScene::items(), QGraphicsItem::zValue() */ QList QGraphicsView::items(const QPoint &pos) const { Q_D(const QGraphicsView); if (!d->scene) return QList(); if (d->scene->d_func()->largestUntransformableItem.isNull()) { if ((d->identityMatrix || d->matrix.type() <= QTransform::TxScale)) { QTransform xinv = viewportTransform().inverted(); return d->scene->items(xinv.mapRect(QRectF(pos.x(), pos.y(), 1, 1))); } return d->scene->items(mapToScene(pos.x(), pos.y(), 1, 1)); } QPainterPath path; path.addRect(QRectF(pos.x(), pos.y(), 1, 1)); return d->itemsInArea(path); } /*! \fn QGraphicsView::items(int x, int y) const This function is provided for convenience. It's equivalent to calling items(QPoint(\a x, \a y)). */ /*! \overload Returns a list of all the items that, depending on \a mode, are either contained by or intersect with \a rect. \a rect is in viewport coordinates. The default value for \a mode is Qt::IntersectsItemShape; all items whose exact shape intersects with or is contained by \a rect are returned. \sa itemAt(), items(), mapToScene() */ QList QGraphicsView::items(const QRect &rect, Qt::ItemSelectionMode mode) const { Q_D(const QGraphicsView); if (!d->scene) return QList(); if (d->scene->d_func()->largestUntransformableItem.isNull()) return d->scene->items(mapToScene(rect), mode); QPainterPath path; path.addRect(rect); return d->itemsInArea(path); } /*! \fn QList QGraphicsView::items(int x, int y, int w, int h, Qt::ItemSelectionMode mode) const \since 4.3 This convenience function is equivalent to calling items(QRectF(\a x, \a y, \a w, \a h), \a mode). */ /*! \overload Returns a list of all the items that, depending on \a mode, are either contained by or intersect with \a polygon. \a polygon is in viewport coordinates. The default value for \a mode is Qt::IntersectsItemShape; all items whose exact shape intersects with or is contained by \a polygon are returned. \sa itemAt(), items(), mapToScene() */ QList QGraphicsView::items(const QPolygon &polygon, Qt::ItemSelectionMode mode) const { Q_D(const QGraphicsView); if (!d->scene) return QList(); if (d->scene->d_func()->largestUntransformableItem.isNull()) return d->scene->items(mapToScene(polygon), mode); QPainterPath path; path.addPolygon(polygon); path.closeSubpath(); return d->itemsInArea(path); } /*! \overload Returns a list of all the items that, depending on \a mode, are either contained by or intersect with \a path. \a path is in viewport coordinates. The default value for \a mode is Qt::IntersectsItemShape; all items whose exact shape intersects with or is contained by \a path are returned. \sa itemAt(), items(), mapToScene() */ QList QGraphicsView::items(const QPainterPath &path, Qt::ItemSelectionMode mode) const { Q_D(const QGraphicsView); if (!d->scene) return QList(); if (d->scene->d_func()->largestUntransformableItem.isNull()) return d->scene->items(mapToScene(path), mode); return d->itemsInArea(path); } /*! Returns the item at position \a pos, which is in viewport coordinates. If there are several items at this position, this function returns the topmost item. Example: \snippet doc/src/snippets/code/src_gui_graphicsview_qgraphicsview.cpp 6 \sa items() */ QGraphicsItem *QGraphicsView::itemAt(const QPoint &pos) const { Q_D(const QGraphicsView); if (!d->scene) return 0; QList itemsAtPos = items(pos); return itemsAtPos.isEmpty() ? 0 : itemsAtPos.first(); } /*! \overload \fn QGraphicsItem *QGraphicsView::itemAt(int x, int y) const This function is provided for convenience. It's equivalent to calling itemAt(QPoint(\a x, \a y)). */ /*! Returns the viewport coordinate \a point mapped to scene coordinates. Note: It can be useful to map the whole rectangle covered by the pixel at \a point instead of the point itself. To do this, you can call mapToScene(QRect(\a point, QSize(2, 2))). \sa mapFromScene() */ QPointF QGraphicsView::mapToScene(const QPoint &point) const { Q_D(const QGraphicsView); QPointF p = point; p.rx() += d->horizontalScroll(); p.ry() += d->verticalScroll(); return d->identityMatrix ? p : d->matrix.inverted().map(p); } /*! \fn QGraphicsView::mapToScene(int x, int y) const This function is provided for convenience. It's equivalent to calling mapToScene(QPoint(\a x, \a y)). */ /*! Returns the viewport rectangle \a rect mapped to a scene coordinate polygon. \sa mapFromScene() */ QPolygonF QGraphicsView::mapToScene(const QRect &rect) const { Q_D(const QGraphicsView); if (!rect.isValid()) return QPolygonF(); QPointF scrollOffset(d->horizontalScroll(), d->verticalScroll()); QRect r = rect.adjusted(0, 0, 1, 1); QPointF tl = scrollOffset + r.topLeft(); QPointF tr = scrollOffset + r.topRight(); QPointF br = scrollOffset + r.bottomRight(); QPointF bl = scrollOffset + r.bottomLeft(); QPolygonF poly; poly.resize(4); if (!d->identityMatrix) { QTransform x = d->matrix.inverted(); poly[0] = x.map(tl); poly[1] = x.map(tr); poly[2] = x.map(br); poly[3] = x.map(bl); } else { poly[0] = tl; poly[1] = tr; poly[2] = br; poly[3] = bl; } return poly; } /*! \fn QGraphicsView::mapToScene(int x, int y, int w, int h) const This function is provided for convenience. It's equivalent to calling mapToScene(QRect(\a x, \a y, \a w, \a h)). */ /*! Returns the viewport polygon \a polygon mapped to a scene coordinate polygon. \sa mapFromScene() */ QPolygonF QGraphicsView::mapToScene(const QPolygon &polygon) const { QPolygonF poly; foreach (const QPoint &point, polygon) poly << mapToScene(point); return poly; } /*! Returns the viewport painter path \a path mapped to a scene coordinate painter path. \sa mapFromScene() */ QPainterPath QGraphicsView::mapToScene(const QPainterPath &path) const { Q_D(const QGraphicsView); QTransform moveMatrix; moveMatrix.translate(d->horizontalScroll(), d->verticalScroll()); return (moveMatrix * d->matrix.inverted()).map(path); } /*! Returns the scene coordinate \a point to viewport coordinates. \sa mapToScene() */ QPoint QGraphicsView::mapFromScene(const QPointF &point) const { Q_D(const QGraphicsView); QPointF p = d->identityMatrix ? point : d->matrix.map(point); p.rx() -= d->horizontalScroll(); p.ry() -= d->verticalScroll(); return p.toPoint(); } /*! \fn QGraphicsView::mapFromScene(qreal x, qreal y) const This function is provided for convenience. It's equivalent to calling mapFromScene(QPointF(\a x, \a y)). */ /*! Returns the scene rectangle \a rect to a viewport coordinate polygon. \sa mapToScene() */ QPolygon QGraphicsView::mapFromScene(const QRectF &rect) const { Q_D(const QGraphicsView); QPointF tl; QPointF tr; QPointF br; QPointF bl; if (!d->identityMatrix) { const QTransform &x = d->matrix; tl = x.map(rect.topLeft()); tr = x.map(rect.topRight()); br = x.map(rect.bottomRight()); bl = x.map(rect.bottomLeft()); } else { tl = rect.topLeft(); tr = rect.topRight(); br = rect.bottomRight(); bl = rect.bottomLeft(); } QPointF scrollOffset(d->horizontalScroll(), d->verticalScroll()); tl -= scrollOffset; tr -= scrollOffset; br -= scrollOffset; bl -= scrollOffset; QPolygon poly; poly.resize(4); poly[0] = tl.toPoint(); poly[1] = tr.toPoint(); poly[2] = br.toPoint(); poly[3] = bl.toPoint(); return poly; } /*! \fn QGraphicsView::mapFromScene(qreal x, qreal y, qreal w, qreal h) const This function is provided for convenience. It's equivalent to calling mapFromScene(QRectF(\a x, \a y, \a w, \a h)). */ /*! Returns the scene coordinate polygon \a polygon to a viewport coordinate polygon. \sa mapToScene() */ QPolygon QGraphicsView::mapFromScene(const QPolygonF &polygon) const { QPolygon poly; foreach (const QPointF &point, polygon) poly << mapFromScene(point); return poly; } /*! Returns the scene coordinate painter path \a path to a viewport coordinate painter path. \sa mapToScene() */ QPainterPath QGraphicsView::mapFromScene(const QPainterPath &path) const { Q_D(const QGraphicsView); QTransform moveMatrix; moveMatrix.translate(-d->horizontalScroll(), -d->verticalScroll()); return (d->matrix * moveMatrix).map(path); } /*! \reimp */ QVariant QGraphicsView::inputMethodQuery(Qt::InputMethodQuery query) const { Q_D(const QGraphicsView); if (!d->scene) return QVariant(); QVariant value = d->scene->inputMethodQuery(query); if (value.type() == QVariant::RectF) value = mapFromScene(value.toRectF()).boundingRect(); else if (value.type() == QVariant::PointF) value = mapFromScene(value.toPointF()); else if (value.type() == QVariant::Rect) value = mapFromScene(value.toRect()).boundingRect(); else if (value.type() == QVariant::Point) value = mapFromScene(value.toPoint()); return value; } /*! \property QGraphicsView::backgroundBrush \brief the background brush of the scene. This property sets the background brush for the scene in this view. It is used to override the scene's own background, and defines the behavior of drawBackground(). To provide custom background drawing for this view, you can reimplement drawBackground() instead. By default, this property contains a brush with the Qt::NoBrush pattern. \sa QGraphicsScene::backgroundBrush, foregroundBrush */ QBrush QGraphicsView::backgroundBrush() const { Q_D(const QGraphicsView); return d->backgroundBrush; } void QGraphicsView::setBackgroundBrush(const QBrush &brush) { Q_D(QGraphicsView); d->backgroundBrush = brush; viewport()->update(); if (d->cacheMode & CacheBackground) { // Invalidate the background pixmap d->mustResizeBackgroundPixmap = true; } } /*! \property QGraphicsView::foregroundBrush \brief the foreground brush of the scene. This property sets the foreground brush for the scene in this view. It is used to override the scene's own foreground, and defines the behavior of drawForeground(). To provide custom foreground drawing for this view, you can reimplement drawForeground() instead. By default, this property contains a brush with the Qt::NoBrush pattern. \sa QGraphicsScene::foregroundBrush, backgroundBrush */ QBrush QGraphicsView::foregroundBrush() const { Q_D(const QGraphicsView); return d->foregroundBrush; } void QGraphicsView::setForegroundBrush(const QBrush &brush) { Q_D(QGraphicsView); d->foregroundBrush = brush; viewport()->update(); } /*! Schedules an update of the scene rectangles \a rects. \sa QGraphicsScene::changed() */ void QGraphicsView::updateScene(const QList &rects) { // ### Note: Since 4.5, this slot is only called if the user explicitly // establishes a connection between the scene and the view, as the scene // and view are no longer connected. We need to keep it working (basically // leave it as it is), but the new delivery path is through // QGraphicsScenePrivate::itemUpdate(). Q_D(QGraphicsView); if (d->fullUpdatePending || d->viewportUpdateMode == QGraphicsView::NoViewportUpdate) return; // Extract and reset dirty scene rect info. QVector dirtyViewportRects; const QVector &dirtyRects = d->dirtyRegion.rects(); for (int i = 0; i < dirtyRects.size(); ++i) dirtyViewportRects += dirtyRects.at(i); d->dirtyRegion = QRegion(); d->dirtyBoundingRect = QRect(); bool fullUpdate = !d->accelerateScrolling || d->viewportUpdateMode == QGraphicsView::FullViewportUpdate; bool boundingRectUpdate = (d->viewportUpdateMode == QGraphicsView::BoundingRectViewportUpdate) || (d->viewportUpdateMode == QGraphicsView::SmartViewportUpdate && ((dirtyViewportRects.size() + rects.size()) >= QGRAPHICSVIEW_REGION_RECT_THRESHOLD)); QRegion updateRegion; QRect boundingRect; QRect viewportRect = viewport()->rect(); bool redraw = false; QTransform transform = viewportTransform(); // Convert scene rects to viewport rects. foreach (const QRectF &rect, rects) { QRect xrect = transform.mapRect(rect).toRect(); if (!(d->optimizationFlags & DontAdjustForAntialiasing)) xrect.adjust(-2, -2, 2, 2); if (!viewportRect.intersects(xrect)) continue; dirtyViewportRects << xrect; } foreach (const QRect &rect, dirtyViewportRects) { // Add the exposed rect to the update region. In rect update // mode, we only count the bounding rect of items. if (!boundingRectUpdate) { updateRegion += rect; } else { boundingRect |= rect; } redraw = true; if (fullUpdate) { // If fullUpdate is true and we found a visible dirty rect, // we're done. break; } } if (!redraw) return; if (fullUpdate) viewport()->update(); else if (boundingRectUpdate) viewport()->update(boundingRect); else viewport()->update(updateRegion); } /*! Notifies QGraphicsView that the scene's scene rect has changed. \a rect is the new scene rect. If the view already has an explicitly set scene rect, this function does nothing. \sa sceneRect, QGraphicsScene::sceneRectChanged() */ void QGraphicsView::updateSceneRect(const QRectF &rect) { Q_D(QGraphicsView); if (!d->hasSceneRect) { d->sceneRect = rect; d->recalculateContentSize(); } } /*! This slot is called by QAbstractScrollArea after setViewport() has been called. Reimplement this function in a subclass of QGraphicsView to initialize the new viewport \a widget before it is used. \sa setViewport() */ void QGraphicsView::setupViewport(QWidget *widget) { Q_D(QGraphicsView); if (!widget) { qWarning("QGraphicsView::setupViewport: cannot initialize null widget"); return; } const bool isGLWidget = widget->inherits("QGLWidget"); d->accelerateScrolling = !(isGLWidget); widget->setFocusPolicy(Qt::StrongFocus); if (!isGLWidget) { // autoFillBackground enables scroll acceleration. widget->setAutoFillBackground(true); } // We are only interested in mouse tracking if items // accept hover events or use non-default cursors. if (d->scene && (!d->scene->d_func()->allItemsIgnoreHoverEvents || !d->scene->d_func()->allItemsUseDefaultCursor)) { widget->setMouseTracking(true); } widget->setAcceptDrops(acceptDrops()); } /*! \reimp */ bool QGraphicsView::event(QEvent *event) { Q_D(QGraphicsView); if (d->sceneInteractionAllowed) { switch (event->type()) { case QEvent::ShortcutOverride: if (d->scene) return QApplication::sendEvent(d->scene, event); break; case QEvent::KeyPress: if (d->scene) { QKeyEvent *k = static_cast(event); if (k->key() == Qt::Key_Tab || k->key() == Qt::Key_Backtab) { // Send the key events to the scene. This will invoke the // scene's tab focus handling, and if the event is // accepted, we return (prevent further event delivery), // and the base implementation will call QGraphicsView's // focusNextPrevChild() function. If the event is ignored, // we fall back to standard tab focus handling. QApplication::sendEvent(d->scene, event); if (event->isAccepted()) return true; // Ensure the event doesn't propagate just because the // scene ignored it. If the event propagates, then tab // handling will be called twice (this and parent). event->accept(); } } break; default: break; } } return QAbstractScrollArea::event(event); } /*! \reimp */ bool QGraphicsView::viewportEvent(QEvent *event) { Q_D(QGraphicsView); if (!d->scene) return QAbstractScrollArea::viewportEvent(event); switch (event->type()) { case QEvent::Enter: QApplication::sendEvent(d->scene, event); break; case QEvent::WindowActivate: QApplication::sendEvent(d->scene, event); break; case QEvent::WindowDeactivate: // ### This is a temporary fix for until we get proper mouse // grab events. mouseGrabberItem should be set to 0 if we lose // the mouse grab. // Remove all popups when the scene loses focus. if (!d->scene->d_func()->popupWidgets.isEmpty()) d->scene->d_func()->removePopup(d->scene->d_func()->popupWidgets.first()); QApplication::sendEvent(d->scene, event); break; case QEvent::Leave: // ### This is a temporary fix for until we get proper mouse grab // events. activeMouseGrabberItem should be set to 0 if we lose the // mouse grab. if ((QApplication::activePopupWidget() && QApplication::activePopupWidget() != window()) || (QApplication::activeModalWidget() && QApplication::activeModalWidget() != window()) || (QApplication::activeWindow() != window())) { if (!d->scene->d_func()->popupWidgets.isEmpty()) d->scene->d_func()->removePopup(d->scene->d_func()->popupWidgets.first()); } d->useLastMouseEvent = false; QApplication::sendEvent(d->scene, event); break; #ifndef QT_NO_TOOLTIP case QEvent::ToolTip: { QHelpEvent *toolTip = static_cast(event); QGraphicsSceneHelpEvent helpEvent(QEvent::GraphicsSceneHelp); helpEvent.setWidget(viewport()); helpEvent.setScreenPos(toolTip->globalPos()); helpEvent.setScenePos(mapToScene(toolTip->pos())); QApplication::sendEvent(d->scene, &helpEvent); toolTip->setAccepted(helpEvent.isAccepted()); return true; } #endif case QEvent::Paint: // Reset full update d->fullUpdatePending = false; if (d->scene) { // Check if this view reimplements the updateScene slot; if it // does, we can't do direct update delivery and have to fall back // to connecting the changed signal. if (!d->updateSceneSlotReimplementedChecked) { d->updateSceneSlotReimplementedChecked = true; const QMetaObject *mo = metaObject(); if (mo != &QGraphicsView::staticMetaObject) { if (mo->indexOfSlot("updateScene(QList)") != QGraphicsView::staticMetaObject.indexOfSlot("updateScene(QList)")) { connect(d->scene, SIGNAL(changed(QList)), this, SLOT(updateScene(QList))); } } } d->scene->d_func()->updateAll = false; } break; default: break; } return QAbstractScrollArea::viewportEvent(event); } #ifndef QT_NO_CONTEXTMENU /*! \reimp */ void QGraphicsView::contextMenuEvent(QContextMenuEvent *event) { Q_D(QGraphicsView); if (!d->scene || !d->sceneInteractionAllowed) return; d->mousePressViewPoint = event->pos(); d->mousePressScenePoint = mapToScene(d->mousePressViewPoint); d->mousePressScreenPoint = event->globalPos(); d->lastMouseMoveScenePoint = d->mousePressScenePoint; d->lastMouseMoveScreenPoint = d->mousePressScreenPoint; QGraphicsSceneContextMenuEvent contextEvent(QEvent::GraphicsSceneContextMenu); contextEvent.setWidget(viewport()); contextEvent.setScenePos(d->mousePressScenePoint); contextEvent.setScreenPos(d->mousePressScreenPoint); contextEvent.setModifiers(event->modifiers()); contextEvent.setReason((QGraphicsSceneContextMenuEvent::Reason)(event->reason())); contextEvent.setAccepted(event->isAccepted()); QApplication::sendEvent(d->scene, &contextEvent); event->setAccepted(contextEvent.isAccepted()); } #endif // QT_NO_CONTEXTMENU /*! \reimp */ void QGraphicsView::dropEvent(QDropEvent *event) { #ifndef QT_NO_DRAGANDDROP Q_D(QGraphicsView); if (!d->scene || !d->sceneInteractionAllowed) return; // Generate a scene event. QGraphicsSceneDragDropEvent sceneEvent(QEvent::GraphicsSceneDrop); d->populateSceneDragDropEvent(&sceneEvent, event); // Send it to the scene. QApplication::sendEvent(d->scene, &sceneEvent); // Accept the originating event if the scene accepted the scene event. event->setAccepted(sceneEvent.isAccepted()); if (sceneEvent.isAccepted()) event->setDropAction(sceneEvent.dropAction()); delete d->lastDragDropEvent; d->lastDragDropEvent = 0; #else Q_UNUSED(event) #endif } /*! \reimp */ void QGraphicsView::dragEnterEvent(QDragEnterEvent *event) { #ifndef QT_NO_DRAGANDDROP Q_D(QGraphicsView); if (!d->scene || !d->sceneInteractionAllowed) return; // Disable replaying of mouse move events. d->useLastMouseEvent = false; // Generate a scene event. QGraphicsSceneDragDropEvent sceneEvent(QEvent::GraphicsSceneDragEnter); d->populateSceneDragDropEvent(&sceneEvent, event); // Store it for later use. d->storeDragDropEvent(&sceneEvent); // Send it to the scene. QApplication::sendEvent(d->scene, &sceneEvent); // Accept the originating event if the scene accepted the scene event. if (sceneEvent.isAccepted()) { event->setAccepted(true); event->setDropAction(sceneEvent.dropAction()); } #else Q_UNUSED(event) #endif } /*! \reimp */ void QGraphicsView::dragLeaveEvent(QDragLeaveEvent *event) { #ifndef QT_NO_DRAGANDDROP Q_D(QGraphicsView); if (!d->scene || !d->sceneInteractionAllowed) return; if (!d->lastDragDropEvent) { qWarning("QGraphicsView::dragLeaveEvent: drag leave received before drag enter"); return; } // Generate a scene event. QGraphicsSceneDragDropEvent sceneEvent(QEvent::GraphicsSceneDragLeave); sceneEvent.setScenePos(d->lastDragDropEvent->scenePos()); sceneEvent.setScreenPos(d->lastDragDropEvent->screenPos()); sceneEvent.setButtons(d->lastDragDropEvent->buttons()); sceneEvent.setModifiers(d->lastDragDropEvent->modifiers()); sceneEvent.setPossibleActions(d->lastDragDropEvent->possibleActions()); sceneEvent.setProposedAction(d->lastDragDropEvent->proposedAction()); sceneEvent.setDropAction(d->lastDragDropEvent->dropAction()); sceneEvent.setMimeData(d->lastDragDropEvent->mimeData()); sceneEvent.setWidget(d->lastDragDropEvent->widget()); sceneEvent.setSource(d->lastDragDropEvent->source()); delete d->lastDragDropEvent; d->lastDragDropEvent = 0; // Send it to the scene. QApplication::sendEvent(d->scene, &sceneEvent); // Accept the originating event if the scene accepted the scene event. if (sceneEvent.isAccepted()) event->setAccepted(true); #else Q_UNUSED(event) #endif } /*! \reimp */ void QGraphicsView::dragMoveEvent(QDragMoveEvent *event) { #ifndef QT_NO_DRAGANDDROP Q_D(QGraphicsView); if (!d->scene || !d->sceneInteractionAllowed) return; // Generate a scene event. QGraphicsSceneDragDropEvent sceneEvent(QEvent::GraphicsSceneDragMove); d->populateSceneDragDropEvent(&sceneEvent, event); // Store it for later use. d->storeDragDropEvent(&sceneEvent); // Send it to the scene. QApplication::sendEvent(d->scene, &sceneEvent); // Ignore the originating event if the scene ignored the scene event. event->setAccepted(sceneEvent.isAccepted()); if (sceneEvent.isAccepted()) event->setDropAction(sceneEvent.dropAction()); #else Q_UNUSED(event) #endif } /*! \reimp */ void QGraphicsView::focusInEvent(QFocusEvent *event) { Q_D(QGraphicsView); QAbstractScrollArea::focusInEvent(event); if (d->scene) QApplication::sendEvent(d->scene, event); // Pass focus on if the scene cannot accept focus. if (!d->scene || !event->isAccepted()) QAbstractScrollArea::focusInEvent(event); } /*! \reimp */ bool QGraphicsView::focusNextPrevChild(bool next) { return QAbstractScrollArea::focusNextPrevChild(next); } /*! \reimp */ void QGraphicsView::focusOutEvent(QFocusEvent *event) { Q_D(QGraphicsView); QAbstractScrollArea::focusOutEvent(event); if (d->scene) QApplication::sendEvent(d->scene, event); } /*! \reimp */ void QGraphicsView::keyPressEvent(QKeyEvent *event) { Q_D(QGraphicsView); if (!d->scene || !d->sceneInteractionAllowed) { QAbstractScrollArea::keyPressEvent(event); return; } QApplication::sendEvent(d->scene, event); if (!event->isAccepted()) QAbstractScrollArea::keyPressEvent(event); } /*! \reimp */ void QGraphicsView::keyReleaseEvent(QKeyEvent *event) { Q_D(QGraphicsView); if (!d->scene || !d->sceneInteractionAllowed) return; QApplication::sendEvent(d->scene, event); if (!event->isAccepted()) QAbstractScrollArea::keyReleaseEvent(event); } /*! \reimp */ void QGraphicsView::mouseDoubleClickEvent(QMouseEvent *event) { Q_D(QGraphicsView); if (!d->scene || !d->sceneInteractionAllowed) return; d->storeMouseEvent(event); d->mousePressViewPoint = event->pos(); d->mousePressScenePoint = mapToScene(d->mousePressViewPoint); d->mousePressScreenPoint = event->globalPos(); d->lastMouseMoveScenePoint = d->mousePressScenePoint; d->lastMouseMoveScreenPoint = d->mousePressScreenPoint; d->mousePressButton = event->button(); QGraphicsSceneMouseEvent mouseEvent(QEvent::GraphicsSceneMouseDoubleClick); mouseEvent.setWidget(viewport()); mouseEvent.setButtonDownScenePos(d->mousePressButton, d->mousePressScenePoint); mouseEvent.setButtonDownScreenPos(d->mousePressButton, d->mousePressScreenPoint); mouseEvent.setScenePos(mapToScene(d->mousePressViewPoint)); mouseEvent.setScreenPos(d->mousePressScreenPoint); mouseEvent.setLastScenePos(d->lastMouseMoveScenePoint); mouseEvent.setLastScreenPos(d->lastMouseMoveScreenPoint); mouseEvent.setButtons(event->buttons()); mouseEvent.setButtons(event->buttons()); mouseEvent.setAccepted(false); mouseEvent.setButton(event->button()); mouseEvent.setModifiers(event->modifiers()); QApplication::sendEvent(d->scene, &mouseEvent); } /*! \reimp */ void QGraphicsView::mousePressEvent(QMouseEvent *event) { Q_D(QGraphicsView); // Store this event for replaying, finding deltas, and for // scroll-dragging; even in non-interactive mode, scroll hand dragging is // allowed, so we store the event at the very top of this function. d->storeMouseEvent(event); d->lastMouseEvent.setAccepted(false); if (d->sceneInteractionAllowed) { // Store some of the event's button-down data. d->mousePressViewPoint = event->pos(); d->mousePressScenePoint = mapToScene(d->mousePressViewPoint); d->mousePressScreenPoint = event->globalPos(); d->lastMouseMoveScenePoint = d->mousePressScenePoint; d->lastMouseMoveScreenPoint = d->mousePressScreenPoint; d->mousePressButton = event->button(); if (d->scene) { // Convert and deliver the mouse event to the scene. QGraphicsSceneMouseEvent mouseEvent(QEvent::GraphicsSceneMousePress); mouseEvent.setWidget(viewport()); mouseEvent.setButtonDownScenePos(d->mousePressButton, d->mousePressScenePoint); mouseEvent.setButtonDownScreenPos(d->mousePressButton, d->mousePressScreenPoint); mouseEvent.setScenePos(d->mousePressScenePoint); mouseEvent.setScreenPos(d->mousePressScreenPoint); mouseEvent.setLastScenePos(d->lastMouseMoveScenePoint); mouseEvent.setLastScreenPos(d->lastMouseMoveScreenPoint); mouseEvent.setButtons(event->buttons()); mouseEvent.setButton(event->button()); mouseEvent.setModifiers(event->modifiers()); mouseEvent.setAccepted(false); QApplication::sendEvent(d->scene, &mouseEvent); // Update the original mouse event accepted state. bool isAccepted = mouseEvent.isAccepted(); event->setAccepted(isAccepted); // Update the last mouse event accepted state. d->lastMouseEvent.setAccepted(isAccepted); if (isAccepted) return; } } #ifndef QT_NO_RUBBERBAND if (d->dragMode == QGraphicsView::RubberBandDrag && !d->rubberBanding) { if (d->sceneInteractionAllowed) { // Rubberbanding is only allowed in interactive mode. event->accept(); d->rubberBanding = true; d->rubberBandRect = QRect(); if (d->scene) { // Initiating a rubber band always clears the selection. d->scene->clearSelection(); } } } else #endif if (d->dragMode == QGraphicsView::ScrollHandDrag && event->button() == Qt::LeftButton) { // Left-button press in scroll hand mode initiates hand scrolling. event->accept(); d->handScrolling = true; d->handScrollMotions = 0; #ifndef QT_NO_CURSOR viewport()->setCursor(Qt::ClosedHandCursor); #endif } } /*! \reimp */ void QGraphicsView::mouseMoveEvent(QMouseEvent *event) { Q_D(QGraphicsView); #ifndef QT_NO_RUBBERBAND if (d->dragMode == QGraphicsView::RubberBandDrag && d->sceneInteractionAllowed) { d->storeMouseEvent(event); if (d->rubberBanding) { // Check for enough drag distance if ((d->mousePressViewPoint - event->pos()).manhattanLength() < QApplication::startDragDistance()) { return; } // Update old rubberband if (d->viewportUpdateMode != QGraphicsView::NoViewportUpdate && !d->rubberBandRect.isEmpty()) { if (d->viewportUpdateMode != FullViewportUpdate) viewport()->update(d->rubberBandRegion(viewport(), d->rubberBandRect)); else viewport()->update(); } // Stop rubber banding if the user has let go of all buttons (even // if we didn't get the release events). if (!event->buttons()) { d->rubberBanding = false; d->rubberBandRect = QRect(); return; } // Update rubberband position const QPoint &mp = d->mousePressViewPoint; QPoint ep = event->pos(); d->rubberBandRect = QRect(qMin(mp.x(), ep.x()), qMin(mp.y(), ep.y()), qAbs(mp.x() - ep.x()) + 1, qAbs(mp.y() - ep.y()) + 1); // Update new rubberband if (d->viewportUpdateMode != QGraphicsView::NoViewportUpdate){ if (d->viewportUpdateMode != FullViewportUpdate) viewport()->update(d->rubberBandRegion(viewport(), d->rubberBandRect)); else viewport()->update(); } // Set the new selection area QPainterPath selectionArea; selectionArea.addPolygon(mapToScene(d->rubberBandRect)); selectionArea.closeSubpath(); if (d->scene) d->scene->setSelectionArea(selectionArea, d->rubberBandSelectionMode); return; } } else #endif // QT_NO_RUBBERBAND if (d->dragMode == QGraphicsView::ScrollHandDrag) { if (d->handScrolling) { QScrollBar *hBar = horizontalScrollBar(); QScrollBar *vBar = verticalScrollBar(); QPoint delta = event->pos() - d->lastMouseEvent.pos(); hBar->setValue(hBar->value() + (isRightToLeft() ? delta.x() : -delta.x())); vBar->setValue(vBar->value() - delta.y()); // Detect how much we've scrolled to disambiguate scrolling from // clicking. ++d->handScrollMotions; } } d->mouseMoveEventHandler(event); } /*! \reimp */ void QGraphicsView::mouseReleaseEvent(QMouseEvent *event) { Q_D(QGraphicsView); #ifndef QT_NO_RUBBERBAND if (d->dragMode == QGraphicsView::RubberBandDrag && d->sceneInteractionAllowed && !event->buttons()) { if (d->rubberBanding) { if (d->viewportUpdateMode != QGraphicsView::NoViewportUpdate){ if (d->viewportUpdateMode != FullViewportUpdate) viewport()->update(d->rubberBandRegion(viewport(), d->rubberBandRect)); else viewport()->update(); } d->rubberBanding = false; d->rubberBandRect = QRect(); } } else #endif if (d->dragMode == QGraphicsView::ScrollHandDrag) { #ifndef QT_NO_CURSOR // Restore the open hand cursor. ### There might be items // under the mouse that have a valid cursor at this time, so // we could repeat the steps from mouseMoveEvent(). viewport()->setCursor(Qt::OpenHandCursor); #endif d->handScrolling = false; if (d->scene && d->sceneInteractionAllowed && !d->lastMouseEvent.isAccepted() && d->handScrollMotions <= 6) { // If we've detected very little motion during the hand drag, and // no item accepted the last event, we'll interpret that as a // click to the scene, and reset the selection. d->scene->clearSelection(); } } d->storeMouseEvent(event); if (!d->sceneInteractionAllowed) return; if (!d->scene) return; QGraphicsSceneMouseEvent mouseEvent(QEvent::GraphicsSceneMouseRelease); mouseEvent.setWidget(viewport()); mouseEvent.setButtonDownScenePos(d->mousePressButton, d->mousePressScenePoint); mouseEvent.setButtonDownScreenPos(d->mousePressButton, d->mousePressScreenPoint); mouseEvent.setScenePos(mapToScene(event->pos())); mouseEvent.setScreenPos(event->globalPos()); mouseEvent.setLastScenePos(d->lastMouseMoveScenePoint); mouseEvent.setLastScreenPos(d->lastMouseMoveScreenPoint); mouseEvent.setButtons(event->buttons()); mouseEvent.setButton(event->button()); mouseEvent.setModifiers(event->modifiers()); mouseEvent.setAccepted(false); QApplication::sendEvent(d->scene, &mouseEvent); // Update the last mouse event selected state. d->lastMouseEvent.setAccepted(mouseEvent.isAccepted()); #ifndef QT_NO_CURSOR if (mouseEvent.isAccepted() && mouseEvent.buttons() == 0 && viewport()->testAttribute(Qt::WA_SetCursor)) { // The last mouse release on the viewport will trigger clearing the cursor. d->_q_unsetViewportCursor(); } #endif } #ifndef QT_NO_WHEELEVENT /*! \reimp */ void QGraphicsView::wheelEvent(QWheelEvent *event) { Q_D(QGraphicsView); if (!d->scene || !d->sceneInteractionAllowed) { QAbstractScrollArea::wheelEvent(event); return; } event->ignore(); QGraphicsSceneWheelEvent wheelEvent(QEvent::GraphicsSceneWheel); wheelEvent.setWidget(viewport()); wheelEvent.setScenePos(mapToScene(event->pos())); wheelEvent.setScreenPos(event->globalPos()); wheelEvent.setButtons(event->buttons()); wheelEvent.setModifiers(event->modifiers()); wheelEvent.setDelta(event->delta()); wheelEvent.setOrientation(event->orientation()); wheelEvent.setAccepted(false); QApplication::sendEvent(d->scene, &wheelEvent); event->setAccepted(wheelEvent.isAccepted()); if (!event->isAccepted()) QAbstractScrollArea::wheelEvent(event); } #endif // QT_NO_WHEELEVENT /*! \reimp */ void QGraphicsView::paintEvent(QPaintEvent *event) { Q_D(QGraphicsView); if (!d->scene) { QAbstractScrollArea::paintEvent(event); return; } // Set up painter state protection. d->scene->d_func()->painterStateProtection = !(d->optimizationFlags & DontSavePainterState); // Determine the exposed region d->exposedRegion = event->region(); if (!d->accelerateScrolling) d->exposedRegion = viewport()->rect(); else if (d->viewportUpdateMode == BoundingRectViewportUpdate) d->exposedRegion = event->rect(); QRectF exposedSceneRect = mapToScene(d->exposedRegion.boundingRect()).boundingRect(); // Set up the painter QPainter painter(viewport()); #ifndef QT_NO_RUBBERBAND if (d->rubberBanding && !d->rubberBandRect.isEmpty()) painter.save(); #endif // Set up render hints painter.setRenderHints(painter.renderHints(), false); painter.setRenderHints(d->renderHints, true); // Set up viewport transform const QTransform viewTransform = viewportTransform(); painter.setWorldTransform(viewTransform); // Draw background if ((d->cacheMode & CacheBackground) #ifdef Q_WS_X11 && X11->use_xrender #endif ) { // Recreate the background pixmap, and flag the whole background as // exposed. if (d->mustResizeBackgroundPixmap) { d->backgroundPixmap = QPixmap(viewport()->size()); QBrush bgBrush = viewport()->palette().brush(viewport()->backgroundRole()); if (!bgBrush.isOpaque()) d->backgroundPixmap.fill(Qt::transparent); QPainter p(&d->backgroundPixmap); p.fillRect(0, 0, d->backgroundPixmap.width(), d->backgroundPixmap.height(), bgBrush); d->backgroundPixmapExposed = QRegion(viewport()->rect()); d->mustResizeBackgroundPixmap = false; } // Redraw exposed areas if (!d->backgroundPixmapExposed.isEmpty()) { QPainter backgroundPainter(&d->backgroundPixmap); backgroundPainter.setClipRegion(d->backgroundPixmapExposed, Qt::ReplaceClip); backgroundPainter.setTransform(viewportTransform()); backgroundPainter.setCompositionMode(QPainter::CompositionMode_Source); drawBackground(&backgroundPainter, exposedSceneRect); d->backgroundPixmapExposed = QRegion(); } // Blit the background from the background pixmap painter.setWorldTransform(QTransform()); painter.drawPixmap(QPoint(), d->backgroundPixmap); painter.setWorldTransform(viewTransform); } else { if (!(d->optimizationFlags & DontSavePainterState)) painter.save(); drawBackground(&painter, exposedSceneRect); if (!(d->optimizationFlags & DontSavePainterState)) painter.restore(); } // Items if (!(d->optimizationFlags & IndirectPainting)) { d->scene->d_func()->drawSubtreeRecursive(0, &painter, viewTransform, &d->exposedRegion, viewport(), 0); } else { // Find all exposed items bool allItems = false; QList itemList = d->findItems(d->exposedRegion, &allItems); if (!itemList.isEmpty()) { // Generate the style options. const int numItems = itemList.size(); QGraphicsItem **itemArray = &itemList[0]; // Relies on QList internals, but is perfectly valid. QStyleOptionGraphicsItem *styleOptionArray = d->allocStyleOptionsArray(numItems); for (int i = 0; i < numItems; ++i) itemArray[i]->d_ptr->initStyleOption(&styleOptionArray[i], viewTransform, d->exposedRegion, allItems); // Draw the items. drawItems(&painter, numItems, itemArray, styleOptionArray); d->freeStyleOptionsArray(styleOptionArray); } } // Foreground drawForeground(&painter, exposedSceneRect); #ifndef QT_NO_RUBBERBAND // Rubberband if (d->rubberBanding && !d->rubberBandRect.isEmpty()) { painter.restore(); QStyleOptionRubberBand option; option.initFrom(viewport()); option.rect = d->rubberBandRect; option.shape = QRubberBand::Rectangle; QStyleHintReturnMask mask; if (viewport()->style()->styleHint(QStyle::SH_RubberBand_Mask, &option, viewport(), &mask)) { // painter clipping for masked rubberbands painter.setClipRegion(mask.region, Qt::IntersectClip); } viewport()->style()->drawControl(QStyle::CE_RubberBand, &option, &painter, viewport()); } #endif painter.end(); // Restore painter state protection. d->scene->d_func()->painterStateProtection = true; } /*! \reimp */ void QGraphicsView::resizeEvent(QResizeEvent *event) { Q_D(QGraphicsView); // Save the last center point - the resize may scroll the view, which // changes the center point. QPointF oldLastCenterPoint = d->lastCenterPoint; QAbstractScrollArea::resizeEvent(event); d->recalculateContentSize(); // Restore the center point again. if (d->resizeAnchor == NoAnchor && !d->keepLastCenterPoint) { d->updateLastCenterPoint(); } else { d->lastCenterPoint = oldLastCenterPoint; } d->centerView(d->resizeAnchor); d->keepLastCenterPoint = false; if (d->cacheMode & CacheBackground) { // Invalidate the background pixmap d->mustResizeBackgroundPixmap = true; } } /*! \reimp */ void QGraphicsView::scrollContentsBy(int dx, int dy) { Q_D(QGraphicsView); d->dirtyScroll = true; if (d->transforming) return; if (isRightToLeft()) dx = -dx; if (d->viewportUpdateMode != QGraphicsView::NoViewportUpdate) { if (d->viewportUpdateMode != QGraphicsView::FullViewportUpdate) { d->dirtyRegion.translate(dx, dy); if (d->accelerateScrolling) { #ifndef QT_NO_RUBBERBAND // Update new and old rubberband regions if (!d->rubberBandRect.isEmpty()) { QRegion rubberBandRegion(d->rubberBandRegion(viewport(), d->rubberBandRect)); rubberBandRegion += rubberBandRegion.translated(-dx, -dy); viewport()->update(rubberBandRegion); } #endif viewport()->scroll(dx, dy); } else { viewport()->update(); } } else { viewport()->update(); } } d->updateLastCenterPoint(); if ((d->cacheMode & CacheBackground) #ifdef Q_WS_X11 && X11->use_xrender #endif ) { // Scroll the background pixmap QRegion exposed; if (!d->backgroundPixmap.isNull()) d->backgroundPixmap.scroll(dx, dy, d->backgroundPixmap.rect(), &exposed); // Invalidate the background pixmap d->backgroundPixmapExposed.translate(dx, dy); d->backgroundPixmapExposed += exposed; } // Always replay on scroll. if (d->sceneInteractionAllowed) d->replayLastMouseEvent(); } /*! \reimp */ void QGraphicsView::showEvent(QShowEvent *event) { Q_D(QGraphicsView); d->recalculateContentSize(); d->centerView(d->transformationAnchor); QAbstractScrollArea::showEvent(event); } /*! \reimp */ void QGraphicsView::inputMethodEvent(QInputMethodEvent *event) { Q_D(QGraphicsView); if (d->scene) QApplication::sendEvent(d->scene, event); } /*! Draws the background of the scene using \a painter, before any items and the foreground are drawn. Reimplement this function to provide a custom background for this view. If all you want is to define a color, texture or gradient for the background, you can call setBackgroundBrush() instead. All painting is done in \e scene coordinates. \a rect is the exposed rectangle. The default implementation fills \a rect using the view's backgroundBrush. If no such brush is defined (the default), the scene's drawBackground() function is called instead. \sa drawForeground(), QGraphicsScene::drawBackground() */ void QGraphicsView::drawBackground(QPainter *painter, const QRectF &rect) { Q_D(QGraphicsView); if (d->scene && d->backgroundBrush.style() == Qt::NoBrush) { d->scene->drawBackground(painter, rect); return; } painter->fillRect(rect, d->backgroundBrush); } /*! Draws the foreground of the scene using \a painter, after the background and all items are drawn. Reimplement this function to provide a custom foreground for this view. If all you want is to define a color, texture or gradient for the foreground, you can call setForegroundBrush() instead. All painting is done in \e scene coordinates. \a rect is the exposed rectangle. The default implementation fills \a rect using the view's foregroundBrush. If no such brush is defined (the default), the scene's drawForeground() function is called instead. \sa drawBackground(), QGraphicsScene::drawForeground() */ void QGraphicsView::drawForeground(QPainter *painter, const QRectF &rect) { Q_D(QGraphicsView); if (d->scene && d->foregroundBrush.style() == Qt::NoBrush) { d->scene->drawForeground(painter, rect); return; } painter->fillRect(rect, d->foregroundBrush); } /*! Draws the items \a items in the scene using \a painter, after the background and before the foreground are drawn. \a numItems is the number of items in \a items and options in \a options. \a options is a list of styleoptions; one for each item. Reimplement this function to provide custom item drawing for this view. The default implementation calls the scene's drawItems() function. \sa drawForeground(), drawBackground(), QGraphicsScene::drawItems() */ void QGraphicsView::drawItems(QPainter *painter, int numItems, QGraphicsItem *items[], const QStyleOptionGraphicsItem options[]) { Q_D(QGraphicsView); if (d->scene) { QWidget *widget = painter->device() == viewport() ? viewport() : 0; d->scene->drawItems(painter, numItems, items, options, widget); } } /*! Returns the current transformation matrix for the view. If no current transformation is set, the identity matrix is returned. \sa setTransform(), rotate(), scale(), shear(), translate() */ QTransform QGraphicsView::transform() const { Q_D(const QGraphicsView); return d->matrix; } /*! Returns a matrix that maps viewport coordinates to scene coordinates. \sa mapToScene(), mapFromScene() */ QTransform QGraphicsView::viewportTransform() const { Q_D(const QGraphicsView); QTransform moveMatrix; moveMatrix.translate(-d->horizontalScroll(), -d->verticalScroll()); return d->identityMatrix ? moveMatrix : d->matrix * moveMatrix; } /*! Returns true if the view is transformed (i.e., a non-identity transform has been assigned, or the scrollbars are adjusted). \sa setTransform(), horizontalScrollBar(), verticalScrollBar() */ bool QGraphicsView::isTransformed() const { Q_D(const QGraphicsView); return !d->identityMatrix || d->horizontalScroll() || d->verticalScroll(); } /*! Sets the view's current transformation matrix to \a matrix. If \a combine is true, then \a matrix is combined with the current matrix; otherwise, \a matrix \e replaces the current matrix. \a combine is false by default. The transformation matrix tranforms the scene into view coordinates. Using the default transformation, provided by the identity matrix, one pixel in the view represents one unit in the scene (e.g., a 10x10 rectangular item is drawn using 10x10 pixels in the view). If a 2x2 scaling matrix is applied, the scene will be drawn in 1:2 (e.g., a 10x10 rectangular item is then drawn using 20x20 pixels in the view). Example: \snippet doc/src/snippets/code/src_gui_graphicsview_qgraphicsview.cpp 7 To simplify interation with items using a transformed view, QGraphicsView provides mapTo... and mapFrom... functions that can translate between scene and view coordinates. For example, you can call mapToScene() to map a view coordiate to a floating point scene coordinate, or mapFromScene() to map from floating point scene coordinates to view coordinates. \sa transform(), rotate(), scale(), shear(), translate() */ void QGraphicsView::setTransform(const QTransform &matrix, bool combine ) { Q_D(QGraphicsView); QTransform oldMatrix = d->matrix; if (!combine) d->matrix = matrix; else d->matrix = matrix * d->matrix; if (oldMatrix == d->matrix) return; d->identityMatrix = d->matrix.isIdentity(); d->transforming = true; if (d->scene) { d->recalculateContentSize(); d->centerView(d->transformationAnchor); } else { d->updateLastCenterPoint(); } if (d->sceneInteractionAllowed) d->replayLastMouseEvent(); d->transforming = false; // Any matrix operation requires a full update. viewport()->update(); } /*! Resets the view transformation to the identity matrix. \sa transform(), setTransform() */ void QGraphicsView::resetTransform() { setTransform(QTransform()); } QT_END_NAMESPACE #include "moc_qgraphicsview.cpp" #endif // QT_NO_GRAPHICSVIEW