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/****************************************************************************
**
** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies).
** All rights reserved.
** Contact: Nokia Corporation (qt-info@nokia.com)
**
** This file is part of the documentation of the Qt Toolkit.
**
** $QT_BEGIN_LICENSE:FDL$
** Commercial Usage
** Licensees holding valid Qt Commercial licenses may use this file in
** accordance with the Qt Commercial License Agreement provided with the
** Software or, alternatively, in accordance with the terms contained in a
** written agreement between you and Nokia.
**
** GNU Free Documentation License
** Alternatively, this file may be used under the terms of the GNU Free
** Documentation License version 1.3 as published by the Free Software
** Foundation and appearing in the file included in the packaging of this
** file.
**
** If you have questions regarding the use of this file, please contact
** Nokia at qt-info@nokia.com.
** $QT_END_LICENSE$
**
****************************************************************************/
/*!
\example graphicsview/elasticnodes
\title Elastic Nodes Example
This GraphicsView example shows how to implement edges between nodes in a
graph, with basic interaction. You can click to drag a node around, and
zoom in and out using the mouse wheel or the keyboard. Hitting the space
bar will randomize the nodes. The example is also resolution independent;
as you zoom in, the graphics remain crisp.
\image elasticnodes-example.png
Graphics View provides the QGraphicsScene class for managing and
interacting with a large number of custom-made 2D graphical items derived
from the QGraphicsItem class, and a QGraphicsView widget for visualizing
the items, with support for zooming and rotation.
This example consists of a \c Node class, an \c Edge class, a \c
GraphWidget test, and a \c main function: the \c Node class represents
draggable yellow nodes in a grid, the \c Edge class represents the lines
between the nodes, the \c GraphWidget class represents the application
window, and the \c main() function creates and shows this window, and runs
the event loop.
\section1 Node Class Definition
The \c Node class serves three purposes:
\list
\o Painting a yellow gradient "ball" in two states: sunken and raised.
\o Managing connections to other nodes.
\o Calculating forces pulling and pushing the nodes in the grid.
\endlist
Let's start by looking at the \c Node class declaration.
\snippet examples/graphicsview/elasticnodes/node.h 0
The \c Node class inherits QGraphicsItem, and reimplements the two
mandatory functions \l{QGraphicsItem::boundingRect()}{boundingRect()} and
\l{QGraphicsItem::paint()}{paint()} to provide its visual appearance. It
also reimplements \l{QGraphicsItem::shape()}{shape()} to ensure its hit
area has an elliptic shape (as opposed to the default bounding rectangle).
For edge management purposes, the node provides a simple API for adding
edges to a node, and for listing all connected edges.
The \l{QGraphicsItem::advance()}{advance()} reimplementation is called
whenever the scene's state advances by one step. The calculateForces()
function is called to calculate the forces that push and pull on this node
and its neighbors.
The \c Node class also reimplements
\l{QGraphicsItem::itemChange()}{itemChange()} to react to state changes (in
this case, position changes), and
\l{QGraphicsItem::mousePressEvent()}{mousePressEvent()} and
\l{QGraphicsItem::mouseReleaseEvent()}{mouseReleaseEvent()} to update the
item's visual appearance.
We will start reviewing the \c Node implementation by looking at its
constructor:
\snippet examples/graphicsview/elasticnodes/node.cpp 0
In the constructor, we set the
\l{QGraphicsItem::ItemIsMovable}{ItemIsMovable} flag to allow the item to
move in response to mouse dragging, and
\l{QGraphicsItem::ItemSendsGeometryChanges}{ItemSendsGeometryChanges} to
enable \l{QGraphicsItem::itemChange()}{itemChange()} notifications for
position and transformation changes. We also enable
\l{QGraphicsItem::DeviceCoordinateCache}{DeviceCoordinateCache} to speed up
rendering performance. To ensure that the nodes are always stacked on top
of edges, we finally set the item's Z value to -1.
\c Node's constructor takes a \c GraphWidget pointer and stores this as a
member variable. We will revisit this pointer later on.
\snippet examples/graphicsview/elasticnodes/node.cpp 1
The addEdge() function adds the input edge to a list of attached edges. The
edge is then adjusted so that the end points for the edge match the
positions of the source and destination nodes.
The edges() function simply returns the list of attached edges.
\snippet examples/graphicsview/elasticnodes/node.cpp 2
There are two ways to move a node. The \c calculateForces() function
implements the elastic effect that pulls and pushes on nodes in the grid.
In addition, the user can directly move one node around with the mouse.
Because we do not want the two approaches to operate at the same time on
the same node, we start \c calculateForces() by checking if this \c Node is
the current mouse grabber item (i.e., QGraphicsScene::mouseGrabberItem()).
Because we need to find all neighboring (but not necessarily connected)
nodes, we also make sure the item is part of a scene in the first place.
\snippet examples/graphicsview/elasticnodes/node.cpp 3
The "elastic" effect comes from an algorithm that applies pushing and
pulling forces. The effect is impressive, and surprisingly simple to
implement.
The algorithm has two steps: the first is to calculate the forces that push
the nodes apart, and the second is to subtract the forces that pull the
nodes together. First we need to find all the nodes in the graph. We call
QGraphicsScene::items() to find all items in the scene, and then use
qgraphicsitem_cast() to look for \c Node instances.
We make use of \l{QGraphicsItem::mapFromItem()}{mapFromItem()} to create a
temporary vector pointing from this node to each other node, in \l{The
Graphics View Coordinate System}{local coordinates}. We use the decomposed
components of this vector to determine the direction and strength of force
that should apply to the node. The forces accumulate for each node, and are
then adjusted so that the closest nodes are given the strongest force, with
rapid degradation when distance increases. The sum of all forces is stored
in \c xvel (X-velocity) and \c yvel (Y-velocity).
\snippet examples/graphicsview/elasticnodes/node.cpp 4
The edges between the nodes represent forces that pull the nodes together.
By visiting each edge that is connected to this node, we can use a similar
approach as above to find the direction and strength of all pulling forces.
These forces are subtracted from \c xvel and \c yvel.
\snippet examples/graphicsview/elasticnodes/node.cpp 5
In theory, the sum of pushing and pulling forces should stabilize to
precisely 0. In practise, however, they never do. To circumvent errors in
numerical precision, we simply force the sum of forces to be 0 when they
are less than 0.1.
\snippet examples/graphicsview/elasticnodes/node.cpp 6
The final step of \c calculateForces() determines the node's new position.
We add the force to the node's current position. We also make sure the new
position stays inside of our defined boundaries. We don't actually move the
item in this function; that's done in a separate step, from \c advance().
\snippet examples/graphicsview/elasticnodes/node.cpp 7
The \c advance() function updates the item's current position. It is called
from \c GraphWidget::timerEvent(). If the node's position changed, the
function returns true; otherwise false is returned.
\snippet examples/graphicsview/elasticnodes/node.cpp 8
The \c Node's bounding rectangle is a 20x20 sized rectangle centered around
its origin (0, 0), adjusted by 2 units in all directions to compensate for
the node's outline stroke, and by 3 units down and to the right to make
room for a simple drop shadow.
\snippet examples/graphicsview/elasticnodes/node.cpp 9
The shape is a simple ellipse. This ensures that you must click inside the
node's elliptic shape in order to drag it around. You can test this effect
by running the example, and zooming far in so that the nodes are very
large. Without reimplementing \l{QGraphicsItem::shape()}{shape()}, the
item's hit area would be identical to its bounding rectangle (i.e.,
rectangular).
\snippet examples/graphicsview/elasticnodes/node.cpp 10
This function implements the node's painting. We start by drawing a simple
dark gray elliptic drop shadow at (-7, -7), that is, (3, 3) units down and
to the right from the top-left corner (-10, -10) of the ellipse.
We then draw an ellipse with a radial gradient fill. This fill is either
Qt::yellow to Qt::darkYellow when raised, or the opposite when sunken. In
sunken state we also shift the center and focal point by (3, 3) to
emphasize the impression that something has been pushed down.
Drawing filled ellipses with gradients can be quite slow, especially when
using complex gradients such as QRadialGradient. This is why this example
uses \l{QGraphicsItem::DeviceCoordinateCache}{DeviceCoordinateCache}, a
simple yet effective measure that prevents unnecessary redrawing.
\snippet examples/graphicsview/elasticnodes/node.cpp 11
We reimplement \l{QGraphicsItem::itemChange()}{itemChange()} to adjust the
position of all connected edges, and to notify the scene that an item has
moved (i.e., "something has happened"). This will trigger new force
calculations.
This notification is the only reason why the nodes need to keep a pointer
back to the \c GraphWidget. Another approach could be to provide such
notification using a signal; in such case, \c Node would need to inherit
from QGraphicsObject.
\snippet examples/graphicsview/elasticnodes/node.cpp 12
Because we have set the \l{QGraphicsItem::ItemIsMovable}{ItemIsMovable}
flag, we don't need to implement the logic that moves the node according to
mouse input; this is already provided for us. We still need to reimplement
the mouse press and release handlers, though, to update the nodes' visual
appearance (i.e., sunken or raised).
\section1 Edge Class Definition
The \c Edge class represents the arrow-lines between the nodes in this
example. The class is very simple: it maintains a source- and destination
node pointer, and provides an \c adjust() function that makes sure the line
starts at the position of the source, and ends at the position of the
destination. The edges are the only items that change continuously as
forces pull and push on the nodes.
Let's take a look at the class declaration:
\snippet examples/graphicsview/elasticnodes/edge.h 0
\c Edge inherits from QGraphicsItem, as it's a simple class that has no use
for signals, slots, and properties (compare to QGraphicsObject).
The constructor takes two node pointers as input. Both pointers are
mandatory in this example. We also provide get-functions for each node.
The \c adjust() function repositions the edge, and the item also implements
\l{QGraphicsItem::boundingRect()}{boundingRect()} and
\{QGraphicsItem::paint()}{paint()}.
We will now review its implementation.
\snippet examples/graphicsview/elasticnodes/edge.cpp 0
The \c Edge constructor initializes its \c arrowSize data member to 10 units;
this determines the size of the arrow which is drawn in
\l{QGraphicsItem::paint()}{paint()}.
In the constructor body, we call
\l{QGraphicsItem::setAcceptedMouseButtons()}{setAcceptedMouseButtons(0)}.
This ensures that the edge items are not considered for mouse input at all
(i.e., you cannot click the edges). Then, the source and destination
pointers are updated, this edge is registered with each node, and we call
\c adjust() to update this edge's start end end position.
\snippet examples/graphicsview/elasticnodes/edge.cpp 1
The source and destination get-functions simply return the respective
pointers.
\snippet examples/graphicsview/elasticnodes/edge.cpp 2
In \c adjust(), we define two points: \c sourcePoint, and \c destPoint,
pointing at the source and destination nodes' origins respectively. Each
point is calculated using \l{The Graphics View Coordinate System}{local
coordinates}.
We want the tip of the edge's arrows to point to the exact outline of the
nodes, as opposed to the center of the nodes. To find this point, we first
decompose the vector pointing from the center of the source to the center
of the destination node into X and Y, and then normalize the components by
dividing by the length of the vector. This gives us an X and Y unit delta
that, when multiplied by the radius of the node (which is 10), gives us the
offset that must be added to one point of the edge, and subtracted from the
other.
If the length of the vector is less than 20 (i.e., if two nodes overlap),
then we fix the source and destination pointer at the center of the source
node. In practise this case is very hard to reproduce manually, as the
forces between the two nodes is then at its maximum.
It's important to notice that we call
\l{QGraphicsItem::prepareGeometryChange()}{prepareGeometryChange()} in this
function. The reason is that the variables \c sourcePoint and \c destPoint
are used directly when painting, and they are returned from the
\l{QGraphicsItem::boundingRect()}{boundingRect()} reimplementation. We must
always call
\l{QGraphicsItem::prepareGeometryChange()}{prepareGeometryChange()} before
changing what \l{QGraphicsItem::boundingRect()}{boundingRect()} returns,
and before these variables can be used by
\l{QGraphicsItem::paint()}{paint()}, to keep Graphics View's internal
bookkeeping clean. It's safest to call this function once, immediately
before any such variable is modified.
\snippet examples/graphicsview/elasticnodes/edge.cpp 3
The edge's bounding rectangle is defined as the smallest rectangle that
includes both the start and the end point of the edge. Because we draw an
arrow on each edge, we also need to compensate by adjusting with half the
arrow size and half the pen width in all directions. The pen is used to
draw the outline of the arrow, and we can assume that half of the outline
can be drawn outside of the arrow's area, and half will be drawn inside.
\snippet examples/graphicsview/elasticnodes/edge.cpp 4
We start the reimplementation of \l{QGraphicsItem::paint()}{paint()} by
checking a few preconditions. Firstly, if either the source or destination
node is not set, then we return immediately; there is nothing to draw.
At the same time, we check if the length of the edge is approximately 0,
and if it is, then we also return.
\snippet examples/graphicsview/elasticnodes/edge.cpp 5
We draw the line using a pen that has round joins and caps. If you run the
example, zoom in and study the edge in detail, you will see that there are
no sharp/square edges.
\snippet examples/graphicsview/elasticnodes/edge.cpp 6
We proceed to drawing one arrow at each end of the edge. Each arrow is
drawn as a polygon with a black fill. The coordinates for the arrow are
determined using simple trigonometry.
\section1 GraphWidget Class Definition
\c GraphWidget is a subclass of QGraphicsView, which provides the main
window with scrollbars.
\snippet examples/graphicsview/elasticnodes/graphwidget.h 0
The class provides a basic constructor that initializes the scene, an \c
itemMoved() function to notify changes in the scene's node graph, a few
event handlers, a reimplementation of
\l{QGraphicsView::drawBackground()}{drawBackground()}, and a helper
function for scaling the view by using the mouse wheel or keyboard.
\snippet examples/graphicsview/elasticnodes/graphwidget.cpp 0
\c GraphicsWidget's constructor creates the scene, and because most items
move around most of the time, it sets QGraphicsScene::NoIndex. The scene
then gets a fixed \l{QGraphicsScene::sceneRect}{scene rectangle}, and is
assigned to the \c GraphWidget view.
The view enables QGraphicsView::CacheBackground to cache rendering of its
static, and somewhat complex, background. Because the graph renders a close
collection of small items that all move around, it's unnecessary for
Graphics View to waste time finding accurate update regions, so we set the
QGraphicsView::BoundingRectViewportUpdate viewport update mode. The default
would work fine, but this mode is noticably faster for this example.
To improve rendering quality, we set QPainter::Antialiasing.
The transformation anchor decides how the view should scroll when you
transform the view, or in our case, when we zoom in or out. We have chosen
QGraphicsView::AnchorUnderMouse, which centers the view on the point under
the mouse cursor. This makes it easy to zoom towards a point in the scene
by moving the mouse over it, and then rolling the mouse wheel.
Finally we give the window a minimum size that matches the scene's default
size, and set a suitable window title.
\snippet examples/graphicsview/elasticnodes/graphwidget.cpp 1
The last part of the constructor creates the grid of nodes and edges, and
gives each node an initial position.
\snippet examples/graphicsview/elasticnodes/graphwidget.cpp 2
\c GraphWidget is notified of node movement through this \c itemMoved()
function. Its job is simply to restart the main timer in case it's not
running already. The timer is designed to stop when the graph stabilizes,
and start once it's unstable again.
\snippet examples/graphicsview/elasticnodes/graphwidget.cpp 3
This is \c GraphWidget's key event handler. The arrow keys move the center
node around, the '+' and '-' keys zoom in and out by calling \c
scaleView(), and the enter and space keys randomize the positions of the
nodes. All other key events (e.g., page up and page down) are handled by
QGraphicsView's default implementation.
\snippet examples/graphicsview/elasticnodes/graphwidget.cpp 4
The timer event handler's job is to run the whole force calculation
machinery as a smooth animation. Each time the timer is triggered, the
handler will find all nodes in the scene, and call \c
Node::calculateForces() on each node, one at a time. Then, in a final step
it will call \c Node::advance() to move all nodes to their new positions.
By checking the return value of \c advance(), we can decide if the grid
stabilized (i.e., no nodes moved). If so, we can stop the timer.
\snippet examples/graphicsview/elasticnodes/graphwidget.cpp 5
In the wheel event handler, we convert the mouse wheel delta to a scale
factor, and pass this factor to \c scaleView(). This approach takes into
account the speed that the wheel is rolled. The faster you roll the mouse
wheel, the faster the view will zoom.
\snippet examples/graphicsview/elasticnodes/graphwidget.cpp 6
The view's background is rendered in a reimplementation of
QGraphicsView::drawBackground(). We draw a large rectangle filled with a
linear gradient, add a drop shadow, and then render text on top. The text
is rendered twice for a simple drop-shadow effect.
This background rendering is quite expensive; this is why the view enables
QGraphicsView::CacheBackground.
\snippet examples/graphicsview/elasticnodes/graphwidget.cpp 7
The \c scaleView() helper function checks that the scale factor stays
within certain limits (i.e., you cannot zoom too far in nor too far out),
and then applies this scale to the view.
\section1 The main() Function
In contrast to the complexity of the rest of this example, the \c main()
function is very simple: We create a QApplication instance, seed the
randomizer using qsrand(), and then create and show an instance of \c
GraphWidget. Because all nodes in the grid are moved initially, the \c
GraphWidget timer will start immediately after control has returned to the
event loop.
*/
|