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/****************************************************************************
**
** Copyright (C) 2009 Nokia Corporation and/or its subsidiary(-ies).
** Contact: Nokia Corporation (qt-info@nokia.com)
**
** This file is part of the documentation 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
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** 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
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** 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
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** packaging of this file. Please review the following information to
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****************************************************************************/
/*!
\example opengl/overpainting
\title Overpainting Example
The Overpainting example shows how QPainter can be used
to overpaint a scene rendered using OpenGL in a QGLWidget.
\image overpainting-example.png
QGLWidget provides a widget with integrated OpenGL graphics support
that enables 3D graphics to be displayed using normal OpenGL calls,
yet also behaves like any other standard Qt widget with support for
signals and slots, properties, and Qt's action system.
Usually, QGLWidget is subclassed to display a pure 3D scene; the
developer reimplements \l{QGLWidget::initializeGL()}{initializeGL()}
to initialize any required resources, \l{QGLWidget::resizeGL()}{resizeGL()}
to set up the projection and viewport, and
\l{QGLWidget::paintGL()}{paintGL()} to perform the OpenGL calls needed
to render the scene. However, it is possible to subclass QGLWidget
differently to allow 2D graphics, drawn using QPainter, to be
painted over a scene rendered using OpenGL.
In this example, we demonstrate how this is done by reusing the code
from the \l{Hello GL Example}{Hello GL} example to provide a 3D scene,
and painting over it with some translucent 2D graphics. Instead of
examining each class in detail, we only cover the parts of the
\c GLWidget class that enable overpainting, and provide more detailed
discussion in the final section of this document.
\section1 GLWidget Class Definition
The \c GLWidget class is a subclass of QGLWidget, based on the one used
in the \l{Hello GL Example}{Hello GL} example. Rather than describe the
class as a whole, we show the first few lines of the class and only
discuss the changes we have made to the rest of it:
\snippet examples/opengl/overpainting/glwidget.h 0
\dots
\snippet examples/opengl/overpainting/glwidget.h 1
\dots
\snippet examples/opengl/overpainting/glwidget.h 4
As usual, the widget uses \l{QGLWidget::initializeGL()}{initializeGL()}
to set up objects for our scene and perform other OpenGL initialization tasks.
The \l{QGLWidget::resizeGL()}{resizeGL()} function is used to ensure that
the 3D graphics in the scene are transformed correctly to the 2D viewport
displayed in the widget.
Instead of implementing \l{QGLWidget::paintGL()}{paintGL()} to handle updates
to the widget, we implement a normal QWidget::paintEvent(). This
allows us to mix OpenGL calls and QPainter operations in a controlled way.
In this example, we also implement QWidget::showEvent() to help with the
initialization of the 2D graphics used.
The new private member functions and variables relate exclusively to the
2D graphics and animation. The \c animate() slot is called periodically by the
\c animationTimer to update the widget; the \c createBubbles() function
initializes the \c bubbles list with instances of a helper class used to
draw the animation; the \c drawInstructions() function is responsible for
a semi-transparent messages that is also overpainted onto the OpenGL scene.
\section1 GLWidget Class Implementation
Again, we only show the parts of the \c GLWidget implementation that are
relevant to this example. In the constructor, we initialize a QTimer to
control the animation:
\snippet examples/opengl/overpainting/glwidget.cpp 0
We turn off the widget's \l{QWidget::autoFillBackground}{autoFillBackground} property to
instruct OpenGL not to paint a background for the widget when
\l{QPainter::begin()}{QPainter::begin()} is called.
As in the \l{Hello GL Example}{Hello GL} example, the destructor is responsible
for freeing any OpenGL-related resources:
\snippet examples/opengl/overpainting/glwidget.cpp 1
The \c initializeGL() function is fairly minimal, only setting up the display
list used in the scene.
\snippet examples/opengl/overpainting/glwidget.cpp 2
To cooperate fully with QPainter, we defer matrix stack operations and attribute
initialization until the widget needs to be updated.
In this example, we implement \l{QWidget::paintEvent()}{paintEvent()} rather
than \l{QGLWidget::paintGL()}{paintGL()} to render
our scene. When drawing on a QGLWidget, the paint engine used by QPainter
performs certain operations that change the states of the OpenGL
implementation's matrix and property stacks. Therefore, it is necessary to
make all the OpenGL calls to display the 3D graphics before we construct
a QPainter to draw the 2D overlay.
We render a 3D scene by setting up model and projection transformations
and other attributes. We use an OpenGL stack operation to preserve the
original matrix state, allowing us to recover it later:
\snippet examples/opengl/overpainting/glwidget.cpp 4
We define a color to use for the widget's background, and set up various
attributes that define how the scene will be rendered.
\snippet examples/opengl/overpainting/glwidget.cpp 6
We call the \c setupViewport() private function to set up the
projection used for the scene. This is unnecessary in OpenGL
examples that implement the \l{QGLWidget::paintGL()}{paintGL()}
function because the matrix stacks are usually unmodified between
calls to \l{QGLWidget::resizeGL()}{resizeGL()} and
\l{QGLWidget::paintGL()}{paintGL()}.
Since the widget's background is not drawn by the system or by Qt, we use
an OpenGL call to paint it before positioning the object defined earlier
in the scene:
\snippet examples/opengl/overpainting/glwidget.cpp 7
Once the list containing the object has been executed, the matrix stack
needs to be restored to its original state at the start of this function
before we can begin overpainting:
\snippet examples/opengl/overpainting/glwidget.cpp 8
With the 3D graphics done, we construct a QPainter for use on the widget
and simply overpaint the widget with 2D graphics; in this case, using a
helper class to draw a number of translucent bubbles onto the widget,
and calling \c drawInstructions() to overlay some instructions:
\snippet examples/opengl/overpainting/glwidget.cpp 10
When QPainter::end() is called, suitable OpenGL-specific calls are made to
write the scene, and its additional contents, onto the widget.
The implementation of the \l{QGLWidget::resizeGL()}{resizeGL()} function
sets up the dimensions of the viewport and defines a projection
transformation:
\snippet examples/opengl/overpainting/glwidget.cpp 11
Ideally, we want to arrange the 2D graphics to suit the widget's dimensions.
To achieve this, we implement the \l{QWidget::showEvent()}{showEvent()} handler,
creating new graphic elements (bubbles) if necessary at appropriate positions
in the widget.
\snippet examples/opengl/overpainting/glwidget.cpp 12
This function only has an effect if less than 20 bubbles have already been
created.
The \c animate() slot is called every time the widget's \c animationTimer emits
the \l{QTimer::timeout()}{timeout()} signal. This keeps the bubbles moving
around.
\snippet examples/opengl/overpainting/glwidget.cpp 13
We simply iterate over the bubbles in the \c bubbles list, updating the
widget before and after each of them is moved.
The \c setupViewport() function is called from \c paintEvent()
and \c resizeGL().
\snippet examples/opengl/overpainting/glwidget.cpp 14
The \c drawInstructions() function is used to prepare some basic
instructions that will be painted with the other 2D graphics over
the 3D scene.
\snippet examples/opengl/overpainting/glwidget.cpp 15
\section1 Summary
When overpainting 2D content onto 3D content, we need to use a QPainter
\e and make OpenGL calls to achieve the desired effect. Since QPainter
itself uses OpenGL calls when used on a QGLWidget subclass, we need to
preserve the state of various OpenGL stacks when we perform our own
calls, using the following approach:
\list
\o Reimplement QGLWidget::initializeGL(), but only perform minimal
initialization. QPainter will perform its own initialization
routines, modifying the matrix and property stacks, so it is better
to defer certain initialization tasks until just before you render
the 3D scene.
\o Reimplement QGLWidget::resizeGL() as in the pure 3D case.
\o Reimplement QWidget::paintEvent() to draw both 2D and 3D graphics.
\endlist
The \l{QWidget::paintEvent()}{paintEvent()} implementation performs the
following tasks:
\list
\o Push the current OpenGL modelview matrix onto a stack.
\o Perform initialization tasks usually done in the
\l{QGLWidget::initializeGL()}{initializeGL()} function.
\o Perform code that would normally be located in the widget's
\l{QGLWidget::resizeGL()}{resizeGL()} function to set the correct
perspective transformation and set up the viewport.
\o Render the scene using OpenGL calls.
\o Pop the OpenGL modelview matrix off the stack.
\o Construct a QPainter object.
\o Initialize it for use on the widget with the QPainter::begin() function.
\o Draw primitives using QPainter's member functions.
\o Call QPainter::end() to finish painting.
\endlist
*/
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