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The QPaintEngine class is used internally by QPainter and QPaintDevice, and is hidden from application programmers unless they create their own device type. \image paintsystem-core.png The main benefit of this approach is that all painting follows the same painting pipeline making it easy to add support for new features and providing default implementations for unsupported ones. Alternatively, Qt provides the QtOpenGL module, offering classes that makes it easy to use OpenGL in Qt applications. Among others, the module provides an OpenGL widget class that can be used just like any other Qt widget, except that it opens an OpenGL display buffer where the OpenGL API can be used to render the contents. \tableofcontents section1 \section1 Drawing QPainter provides highly optimized functions to do most of the drawing GUI programs require. It can draw everything from simple graphical primitives (represented by the QPoint, QLine, QRect, QRegion and QPolygon classes) to complex shapes like vector paths. In Qt vector paths are represented by the QPainterPath class. QPainterPath provides a container for painting operations, enabling graphical shapes to be constructed and reused. \table 100% \row \o \image paintsystem-painterpath.png \o \bold QPainterPath A painter path is an object composed of lines and curves. For example, a rectangle is composed by lines and an ellipse is composed by curves. The main advantage of painter paths over normal drawing operations is that complex shapes only need to be created once; then they can be drawn many times using only calls to the QPainter::drawPath() function. A QPainterPath object can be used for filling, outlining, and clipping. To generate fillable outlines for a given painter path, use the QPainterPathStroker class. \endtable Lines and outlines are drawn using the QPen class. A pen is defined by its style (i.e. its line-type), width, brush, how the endpoints are drawn (cap-style) and how joins between two connected lines are drawn (join-style). The pen's brush is a QBrush object used to fill strokes generated with the pen, i.e. the QBrush class defines the fill pattern. QPainter can also draw aligned text and pixmaps. When drawing text, the font is specified using the QFont class. Qt will use the font with the specified attributes, or if no matching font exists, Qt will use the closest matching installed font. The attributes of the font that is actually used can be retrieved using the QFontInfo class. In addition, the QFontMetrics class provides the font measurements, and the QFontDatabase class provides information about the fonts available in the underlying window system. Normally, QPainter draws in a "natural" coordinate system, but it is able to perform view and world transformations using the QMatrix class. For more information, see \l {The Coordinate System} documentation which also describes the rendering process, i.e. the relation between the logical representation and the rendered pixels, and the benefits of anti-aliased painting. \table 100% \row \o \bold {Anti-Aliased Painting} When drawing, the pixel rendering is controlled by the QPainter::Antialiasing render hint. The QPainter::RenderHint enum is used to specify flags to QPainter that may or may not be respected by any given engine. The QPainter::Antialiasing value indicates that the engine should antialias edges of primitives if possible, i.e. smoothing the edges by using different color intensities. \o \image paintsystem-antialiasing.png \endtable \section1 Filling Shapes are filled using the QBrush class. A brush is defined by its color and its style (i.e. its fill pattern). Any color in Qt is represented by the QColor class which supports the RGB, HSV and CMYK color models. QColor also support alpha-blended outlining and filling (specifying the transparency effect), and the class is platform and device independent (the colors are mapped to hardware using the QColormap class). For more information, see the QColor class documentation. When creating a new widget, it is recommend to use the colors in the widget's palette rather than hard-coding specific colors. All widgets in Qt contain a palette and use their palette to draw themselves. A widget's palette is represented by the QPalette class which contains color groups for each widget state. The available fill patterns are described by the Qt::BrushStyle enum. These include basic patterns spanning from uniform color to very sparse pattern, various line combinations, gradient fills and textures. Qt provides the QGradient class to define custom gradient fills, while texture patterns are specified using the QPixmap class. \table 100% \row \o \image paintsystem-fancygradient.png \o \bold QGradient The QGradient class is used in combination with QBrush to specify gradient fills. \image paintsystem-gradients.png Qt currently supports three types of gradient fills: Linear gradients interpolate colors between start and end points, radial gradients interpolate colors between a focal point and end points on a circle surrounding it, and conical gradients interpolate colors around a center point. \endtable \section1 Creating a Paint Device The QPaintDevice class is the base class of objects that can be painted, i.e. QPainter can draw on any QPaintDevice subclass. QPaintDevice's drawing capabilities are currently implemented by the QWidget, QImage, QPixmap, QGLWidget, QGLPixelBuffer, QPicture and QPrinter subclasses. \image paintsystem-devices.png \table 100% \row \o \bold {Custom Backends} Support for a new backend can be implemented by deriving from the QPaintDevice class and reimplementing the virtual QPaintDevice::paintEngine() function to tell QPainter which paint engine should be used to draw on this particular device. To actually be able to draw on the device, this paint engine must be a custom paint engine created by deriving from the QPaintEngine class. \endtable \section2 Widget The QWidget class is the base class of all user interface objects. The widget is the atom of the user interface: it receives mouse, keyboard and other events from the window system, and paints a representation of itself on the screen. \section2 Image The QImage class provides a hardware-independent image representation which is designed and optimized for I/O, and for direct pixel access and manipulation. QImage supports several image formats including monochrome, 8-bit, 32-bit and alpha-blended images. One advantage of using QImage as a paint device is that it is possible to guarantee the pixel exactness of any drawing operation in a platform-independent way. Another benefit is that the painting can be performed in another thread than the current GUI thread. \section2 Pixmap The QPixmap class is an off-screen image representation which is designed and optimized for showing images on screen. Unlike QImage, the pixel data in a pixmap is internal and is managed by the underlying window system, i.e. pixels can only be accessed through QPainter functions or by converting the QPixmap to a QImage. To optimize drawing with QPixmap, Qt provides the QPixmapCache class which can be used to store temporary pixmaps that are expensive to generate without using more storage space than the cache limit. Qt also provides the QBitmap convenience class, inheriting QPixmap. QBitmap guarantees monochrome (1-bit depth) pixmaps, and is mainly used for creating custom QCursor and QBrush objects, constructing QRegion objects, and for setting masks for pixmaps and widgets. \section2 OpenGL Widget As mentioned above, Qt provides the QtOpenGL module offering classes that makes it easy to use OpenGL in Qt applications. For example, the QGLWidget enables the OpenGL API for rendering. But QGLWidget is also a QWidget subclass, and can be used by QPainter as any other paint device. One huge benefit from this is that it enables Qt to utilize the high performance of OpenGL for most drawing operations, such as transformations and pixmap drawing. \section2 Pixel Buffer The QtOpenGL module also provides the QGLPixelBuffer class which inherits QPaintDevice directly. QGLPixelBuffer encapsulates an OpenGL pbuffer. Rendering into a pbuffer is normally done using full hardware acceleration which can be significantly faster than rendering into a QPixmap. \section2 Framebuffer Object The QtOpenGL module also provides the QGLFramebufferObject class which inherits QPaintDevice directly. QGLFramebufferObject encapsulates an OpenGL framebuffer object. Framebuffer objects can also be used for off-screen rendering, and offer several advantages over pixel buffers for this purpose. These are described in the QGLFramebufferObject class documentation. \section2 Picture The QPicture class is a paint device that records and replays QPainter commands. A picture serializes painter commands to an IO device in a platform-independent format. QPicture is also resolution independent, i.e. a QPicture can be displayed on different devices (for example svg, pdf, ps, printer and screen) looking the same. Qt provides the QPicture::load() and QPicture::save() functions for loading and saving pictures. But in addition the QPictureIO class is provided to enable the programmer to install new picture file formats in addition to those that Qt provides. \section2 Printer The QPrinter class is a paint device that paints on a printer. On Windows or Mac OS X, QPrinter uses the built-in printer drivers. On X11, QPrinter generates postscript and sends that to lpr, lp, or another print program. QPrinter can also print to any other QPrintEngine object. The QPrintEngine class defines an interface for how QPrinter interacts with a given printing subsystem. The common case when creating your own print engine, is to derive from both QPaintEngine and QPrintEngine. The output format is by default determined by the platform the printer is running on, but by explicitly setting the output format to QPrinter::PdfFormat, QPrinter will generate its output as a PDF file. \section1 Reading and Writing Image Files The most common way to read images is through QImage and QPixmap's constructors, or by calling the QImage::load() and QPixmap::load() functions. In addition, Qt provides the QImageReader class which gives more control over the process. Depending on the underlying support in the image format, the functions provided by the class can save memory and speed up loading of images. Likewise, Qt provides the QImageWriter class which supports setting format specific options, such as the gamma level, compression level and quality, prior to storing the image. If you do not need such options, you can use QImage::save() or QPixmap::save() instead. \table 100% \row \o \bold QMovie QMovie is a convenience class for displaying animations, using the QImageReader class internally. Once created, the QMovie class provides various functions for both running and controlling the given animation. \o \image paintsystem-movie.png \endtable The QImageReader and QImageWriter classes rely on the QImageIOHandler class which is the common image I/O interface for all image formats in Qt. QImageIOHandler objects are used internally by QImageReader and QImageWriter to add support for different image formats to Qt. A list of the supported file formats are available through the QImageReader::supportedImageFormats() and QImageWriter::supportedImageFormats() functions. Qt supports several file formats by default, and in addition new formats can be added as plugins. The currently supported formats are listed in the QImageReader and QImageWriter class documentation. Qt's plugin mechanism can also be used to write a custom image format handler. This is done by deriving from the QImageIOHandler class, and creating a QImageIOPlugin object which is a factory for creating QImageIOHandler objects. When the plugin is installed, QImageReader and QImageWriter will automatically load the plugin and start using it. \table 100% \row \o \image paintsystem-svg.png \o \bold {SVG Rendering} Scalable Vector Graphics (SVG) is an language for describing both static and animated two-dimensional vector graphics. Qt includes support for the static features of SVG 1.2 Tiny. SVG drawings can be rendered onto any QPaintDevice subclass. This approach gives developers the flexibility to experiment, in order to find the best solution for each application. The easiest way to render SVG files is to construct a QSvgWidget and load an SVG file using one of the QSvgWidget::load() functions. The rendering is performed by the QSvgRenderer class which also can be used directly to provide SVG support for custom widgets. For more information, see the QtSvg module documentation. \endtable \section1 Styling Qt's built-in widgets use the QStyle class to perform nearly all of their drawing. QStyle is an abstract base class that encapsulates the look and feel of a GUI, and can be used to make the widgets look exactly like the equivalent native widgets or to give the widgets a custom look. Qt provides a set of QStyle subclasses that emulate the native look of the different platforms supported by Qt (QWindowsStyle, QMacStyle, QMotifStyle, etc.). These styles are built into the QtGui library, other styles can be made available using Qt's plugin mechansim. Most functions for drawing style elements take four arguments: \list \o an enum value specifying which graphical element to draw \o a QStyleOption object specifying how and where to render that element \o a QPainter object that should be used to draw the element \o a QWidget object on which the drawing is performed (optional) \endlist The style gets all the information it needs to render the graphical element from the QStyleOption class. The widget is passed as the last argument in case the style needs it to perform special effects (such as animated default buttons on Mac OS X), but it isn't mandatory. In fact, QStyle can be used to draw on any paint device (not just widgets), in which case the widget argument is a zero pointer. \image paintsystem-stylepainter.png The paint system also provides the QStylePainter class inheriting from QPainter. QStylePainter is a convenience class for drawing QStyle elements inside a widget, and extends QPainter with a set of high-level drawing functions implemented on top of QStyle's API. The advantage of using QStylePainter is that the parameter lists get considerably shorter. \table 100% \row \o \inlineimage paintsystem-icon.png \o \bold QIcon The QIcon class provides scalable icons in different modes and states. QIcon can generate pixmaps reflecting an icon's state, mode and size. These pixmaps are generated from the set of pixmaps made available to the icon, and are used by Qt widgets to show an icon representing a particular action. The rendering of a QIcon object is handled by the QIconEngine class. Each icon has a corresponding icon engine that is responsible for drawing the icon with a requested size, mode and state. \endtable \section1 Selecting the Painting Backend Since Qt 4.5, it is possible to replace the paint engines and paint devices used for widgets, pixmaps and the offscreen double buffer. By default the backends are: \table \row \o Windows \o Software Rasterizer \row \o X11 \o X11 \row \o Mac OS X \o CoreGraphics \row \o Embedded \o Software Rasterizer \endtable Passing a command line parameter to the application, such as, \c{-graphicssystem raster}, specifies that Qt should use the software rasterizer for this application. The Software rasterizer is fully supported on all platforms. \code > analogclock -graphicssystem raster \endcode There is also a \c{-graphicssystem opengl} mode that uses OpenGL for all drawing. Currently, this engine is experimental as it does not draw everything correctly. Qt also supports being configured using \c {-graphicssystem raster|opengl} in which case all applications will use the specified graphics system for its graphics. */