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/****************************************************************************
**
** Copyright (C) 2012 Digia Plc and/or its subsidiary(-ies).
** Contact: http://www.qt-project.org/legal
**
** This file is part of the documentation of the Qt Toolkit.
**
** $QT_BEGIN_LICENSE:FDL$
** Commercial License Usage
** Licensees holding valid commercial Qt licenses may use this file in
** accordance with the commercial license agreement provided with the
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** use the contact form at http://qt.digia.com/contact-us.
**
** GNU Free Documentation License Usage
** 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. Please review the following information to ensure
** the GNU Free Documentation License version 1.3 requirements
** will be met: http://www.gnu.org/copyleft/fdl.html.
** $QT_END_LICENSE$
**
****************************************************************************/
/*!
\example qws/svgalib
\title Accelerated Graphics Driver Example
\brief The Accelerated Graphics Driver example shows how you can write
your own accelerated graphics driver and \l {add your graphics
driver to Qt for Embedded Linux}.
In \l{Qt for Embedded Linux},
painting is a pure software implementation and is normally performed
in two steps:
The clients render each window onto a corresponding surface
(stored in memory) using a paint engine, and then the server uses
the graphics driver to compose the surface images and copy them to
the screen. (See the \l{Qt for Embedded Linux Architecture} documentation
for details.)
The rendering can be accelerated in two ways: Either by
accelerating the copying of pixels to the screen, or by
accelerating the explicit painting operations. The first is done
in the graphics driver implementation, the latter is performed by
the paint engine implementation. Typically, both the pixel copying
and the painting operations are accelerated using the following
approach:
\list 1
\o \l {Step 1: Creating a Custom Graphics Driver}
{Creating a Custom Graphics Driver}
\o \l {Step 2: Implementing a Custom Raster Paint Engine}
{Implementing a Custom Paint Engine}
\o \l {Step 3: Making the Widgets Aware of the Custom Paint
Engine}{Making the Widgets Aware of the Custom Paint Engine}
\endlist
After compiling the example code, install the graphics driver
plugin with the command \c {make install}. To start an application
using the graphics driver, you can either set the environment
variable \l QWS_DISPLAY and then run the application, or you can
just run the application using the \c -display switch:
\snippet doc/src/snippets/code/doc_src_examples_svgalib.qdoc 0
\table
\header \o SVGAlib
\row \o
Instead of interfacing the graphics hardware directly, this
example relies on \l {http://www.svgalib.org}{SVGAlib} being
installed on your system. \l {http://www.svgalib.org}{SVGAlib} is
a small graphics library which provides acceleration for many
common graphics cards used on desktop computers. It should work on
most workstations and has a small and simple API.
\endtable
\section1 Step 1: Creating a Custom Graphics Driver
The custom graphics driver is created by deriving from the QScreen
class. QScreen is the base class for implementing screen/graphics
drivers in Qt for Embedded Linux.
\snippet examples/qws/svgalib/svgalibscreen.h 0
\codeline
\snippet examples/qws/svgalib/svgalibscreen.h 1
The \l {QScreen::}{connect()}, \l {QScreen::}{disconnect()}, \l
{QScreen::}{initDevice()} and \l {QScreen::}{shutdownDevice()}
functions are declared as pure virtual functions in QScreen and
must be implemented. They are used to configure the hardware, or
query its configuration: \l {QScreen::}{connect()} and \l
{QScreen::}{disconnect()} are called by both the server and client
processes, while the \l {QScreen::}{initDevice()} and \l
{QScreen::}{shutdownDevice()} functions are only called by the
server process.
QScreen's \l {QScreen::}{setMode()} and \l {QScreen::}{blank()}
functions are also pure virtual, but our driver's implementations
are trivial. The last two functions (\l {QScreen::}{blit()} and \l
{QScreen::}{solidFill()}) are the ones involved in putting pixels
on the screen, i.e., we reimplement these functions to perform the
pixel copying acceleration.
Finally, the \c context variable is a pointer to a \l
{http://www.svgalib.org}{SVGAlib} specific type. Note that the
details of using the \l {http://www.svgalib.org}{SVGAlib} library
is beyond the scope of this example.
\section2 SvgalibScreen Class Implementation
The \l {QScreen::}{connect()} function is the first function that
is called after the constructor returns. It queries \l
{http://www.svgalib.org}{SVGAlib} about the graphics mode and
initializes the variables.
\snippet examples/qws/svgalib/svgalibscreen.cpp 0
It is important that the \l {QScreen::}{connect()} function
initializes the \c data, \c lstep, \c w, \c h, \c dw, \c dh, \c d,
\c physWidth and \c physHeight variables (inherited from QScreen)
to ensure that the driver is in a state consistent with the driver
configuration.
In this particular example we do not have any information of the
real physical size of the screen, so we set these values with the
assumption of a screen with 72 DPI.
\snippet examples/qws/svgalib/svgalibscreen.cpp 1
When the \l {QScreen::}{connect()} function returns, the server
process calls the \l {QScreen::}{initDevice()} function which is
expected to do the necessary hardware initialization, leaving the
hardware in a state consistent with the driver configuration.
Note that we have chosen to use the software cursor. If you want
to use a hardware cursor, you should create a subclass of
QScreenCursor, create an instance of it, and make the global
variable \c qt_screencursor point to this instance.
\snippet examples/qws/svgalib/svgalibscreen.cpp 2
\codeline
\snippet examples/qws/svgalib/svgalibscreen.cpp 3
Before exiting, the server process will call the \l
{QScreen::}{shutdownDevice()} function to do the necessary
hardware cleanup. Again, it is important that the function leaves
the hardware in a state consistent with the driver
configuration. When \l {QScreen::}{shutdownDevice()} returns, the
\l {QScreen::}{disconnect()} function is called. Our
implementation of the latter function is trivial.
Note that, provided that the \c QScreen::data variable points to a
valid linear framebuffer, the graphics driver is fully functional
as a simple screen driver at this point. The rest of this example
will show where to take advantage of the accelerated capabilities
available on the hardware.
Whenever an area on the screen needs to be updated, the server will
call the \l {QScreen::}{exposeRegion()} function that paints the
given region on screen. The default implementation will do the
necessary composing of the top-level windows and call \l
{QScreen::}{solidFill()} and \l {QScreen::}{blit()} whenever it is
required. We do not want to change this behavior in the driver so
we do not reimplement \l {QScreen::}{exposeRegion()}.
To control how the pixels are put onto the screen we need to
reimplement the \l {QScreen::}{solidFill()} and \l
{QScreen::}{blit()} functions.
\snippet examples/qws/svgalib/svgalibscreen.cpp 4
\codeline
\snippet examples/qws/svgalib/svgalibscreen.cpp 5
\section1 Step 2: Implementing a Custom Raster Paint Engine
\l{Qt for Embedded Linux} uses QRasterPaintEngine (a raster-based
implementation of QPaintEngine) to implement the painting
operations.
Acceleration of the painting operations is done by deriving from
QRasterPaintEngine class. This is a powerful mechanism for
accelerating graphic primitives while getting software fallbacks
for all the primitives you do not accelerate.
\snippet examples/qws/svgalib/svgalibpaintengine.h 0
In this example, we will only accelerate one of the \l
{QRasterPaintEngine::}{drawRects()} functions, i.e., only
non-rotated, aliased and opaque rectangles will be rendered using
accelerated painting. All other primitives are rendered using the
base class's unaccelerated implementation.
The paint engine's state is stored in the private member
variables, and we reimplement the \l
{QPaintEngine::}{updateState()} function to ensure that our
custom paint engine's state is updated properly whenever it is
required. The private \c setClip() and \c updateClip() functions
are only helper function used to simplify the \l
{QPaintEngine::}{updateState()} implementation.
We also reimplement QRasterPaintEngine's \l
{QRasterPaintEngine::}{begin()} and \l
{QRasterPaintEngine::}{end()} functions to initialize the paint
engine and to do the cleanup when we are done rendering,
respectively.
\table
\header \o Private Header Files
\row
\o
Note the \c include statement used by this class. The files
prefixed with \c private/ are private headers file within
\l{Qt for Embedded Linux}. Private header files are not part of
the standard installation and are only present while
compiling Qt. To be able to compile using
private header files you need to use a \c qmake binary within a
compiled \l{Qt for Embedded Linux} package.
\warning Private header files may change without notice between
releases.
\endtable
The \l {QRasterPaintEngine::}{begin()} function initializes the
internal state of the paint engine. Note that it also calls the
base class implementation to initialize the parts inherited from
QRasterPaintEngine:
\snippet examples/qws/svgalib/svgalibpaintengine.cpp 0
\codeline
\snippet examples/qws/svgalib/svgalibpaintengine.cpp 1
The implementation of the \l {QRasterPaintEngine::}{end()}
function removes the clipping constraints that might have been set
in \l {http://www.svgalib.org}{SVGAlib}, before calling the
corresponding base class implementation.
\snippet examples/qws/svgalib/svgalibpaintengine.cpp 2
The \l {QPaintEngine::}{updateState()} function updates our
custom paint engine's state. The QPaintEngineState class provides
information about the active paint engine's current state.
Note that we only accept and save the current matrix if it doesn't
do any shearing. The pen is accepted if it is opaque and only one
pixel wide. The rest of the engine's properties are updated
following the same pattern. Again it is important that the
QPaintEngine::updateState() function is called to update the
parts inherited from the base class.
\snippet examples/qws/svgalib/svgalibpaintengine.cpp 3
\codeline
\snippet examples/qws/svgalib/svgalibpaintengine.cpp 4
The \c setClip() helper function is called from our custom
implementation of \l {QPaintEngine::}{updateState()}, and
enables clipping to the given region. An empty region means that
clipping is disabled.
Our custom update function also makes use of the \c updateClip()
helper function that checks if the clip is "simple", i.e., that it
can be represented by only one rectangle, and updates the clip
region in \l {http://www.svgalib.org}{SVGAlib}.
\snippet examples/qws/svgalib/svgalibpaintengine.cpp 5
Finally, we accelerated that drawing of non-rotated, aliased and
opaque rectangles in our reimplementation of the \l
{QRasterPaintEngine::}{drawRects()} function. The
QRasterPaintEngine fallback is used whenever the rectangle is not
simple enough.
\section1 Step 3: Making the Widgets Aware of the Custom Paint Engine
To activate the custom paint engine, we also need to implement a
corresponding paint device and window surface and make some minor
adjustments of the graphics driver.
\list
\o \l {Implementing a Custom Paint Device}
\o \l {Implementing a Custom Window Surface}
\o \l {Adjusting the Graphics Driver}
\endlist
\section2 Implementing a Custom Paint Device
The custom paint device can be derived from the
QCustomRasterPaintDevice class. Reimplement its \l
{QCustomRasterPaintDevice::}{paintEngine()} and \l
{QCustomRasterPaintDevice::}{memory()} functions to activate the
accelerated paint engine:
\snippet examples/qws/svgalib/svgalibpaintdevice.h 0
The \l {QCustomRasterPaintDevice::}{paintEngine()} function should
return an instance of the \c SvgalibPaintEngine class. The \l
{QCustomRasterPaintDevice::}{memory()} function should return a
pointer to the buffer which should be used when drawing the
widget.
Our example driver is rendering directly to the screen without any
buffering, i.e., our custom pain device's \l
{QCustomRasterPaintDevice::}{memory()} function returns a pointer
to the framebuffer. For this reason, we must also reimplement the
\l {QPaintDevice::}{metric()} function to reflect the metrics of
framebuffer.
\section2 Implementing a Custom Window Surface
The custom window surface can be derived from the QWSWindowSurface
class. QWSWindowSurface manages the memory used when drawing a
window.
\snippet examples/qws/svgalib/svgalibsurface.h 0
We can implement most of the pure virtual functions inherited from
QWSWindowSurface as trivial inline functions, except the scroll()
function that actually makes use of some hardware acceleration:
\snippet examples/qws/svgalib/svgalibsurface.cpp 0
\section2 Adjusting the Graphics Driver
Finally, we enable the graphics driver to recognize an instance of
our custom window surface:
\snippet examples/qws/svgalib/svgalibscreen.cpp 7
\codeline
\snippet examples/qws/svgalib/svgalibscreen.cpp 8
The \l {QScreen::}{createSurface()} functions are factory
functions that determines what kind of surface a top-level window
is using. In our example we only use the custom surface if the
given window has the Qt::WA_PaintOnScreen attribute or the
QT_ONSCREEN_PAINT environment variable is set.
*/
|