Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
Raster Window Example#
This example shows how to create a minimal QWindow
based application using QPainter
for rendering.
Application Entry Point#
if __name__ == "__main__": app = QGuiApplication(argc, argv) window = RasterWindow() window.show() sys.exit(app.exec())
The entry point for a QWindow
based application is the QGuiApplication
class. It manages the GUI application’s control flow and main settings. We pass the command line arguments which can be used to pick up certain system wide options.
From there, we go on to create our window instance and then call the show()
function to tell the windowing system that this window should now be made visible on screen.
Once this is done, we enter the application’s event loop so the application can run.
RasterWindow Declaration#
from PySide6 import QtGui class RasterWindow(QWindow): Q_OBJECT # public RasterWindow = explicit(QWindow parent = None) virtual void render(QPainter painter) # public slots def renderLater(): def renderNow(): # protected bool event(QEvent event) override def resizeEvent(event): def exposeEvent(event): # private m_backingStore = QScopedPointer()
We first start by including the <QtGui>
header. This means we can use all classes in the Qt GUI module. Classes can also be included individually if that is preferred.
The RasterWindow class subclasses QWindow
directly and provides a constructor which allows the window to be a sub-window of another QWindow
. Parent-less QWindows show up in the windowing system as top-level windows.
The class declares a QBackingStore
which is what we use to manage the window’s back buffer for QPainter
based graphics.
The raster window is also reused in a few other examples and adds a few helper functions, like renderLater().
RasterWindow Implementation#
def __init__(self, parent): super().__init__(parent) , m_backingStore(QBackingStore(self)) setGeometry(100, 100, 300, 200)
In the constructor we create the backingstore and pass it the window instance it is supposed to manage. We also set the initial window geometry.
def exposeEvent(self, arg__0): if isExposed(): renderNow()
Shortly after calling show()
on a created window, the virtual function exposeEvent()
will be called to notify us that the window’s exposure in the windowing system has changed. The event contains the exposed sub-region, but since we will anyway draw the entire window every time, we do not make use of that.
The function isExposed()
will tell us if the window is showing or not. We need this as the exposeEvent is called also when the window becomes obscured in the windowing system. If the window is showing, we call renderNow() to draw the window immediately. We want to draw right away so we can present the system with some visual content.
def resizeEvent(self, resizeEvent): m_backingStore.resize(resizeEvent.size())
The resize event is guaranteed to be called prior to the window being shown on screen and will also be called whenever the window is resized while on screen. We use this to resize the back buffer, and defer rendering to the corresponding/following expose event.
def renderNow(self): if not isExposed(): return rect = QRect(0, 0, width(), height()) m_backingStore.beginPaint(rect) device = m_backingStore.paintDevice() painter = QPainter(device) painter.fillRect(0, 0, width(), height(), QGradient.NightFade) render(painter) painter.end() m_backingStore.endPaint() m_backingStore.flush(rect)
The renderNow function sets up what is needed for a QWindow
to render its content using QPainter
. As obscured windows have will not be visible, we abort if the window is not exposed in the windowing system. This can for instance happen when another window fully obscures this window.
We start the drawing by calling beginPaint()
on the region we want to draw. Then we get the QPaintDevice
of the back buffer and create a QPainter
to render to that paint device.
To void leaving traces from the previous rendering and start with a clean buffer, we fill the entire buffer with the color white. Then we call the virtual render() function which does the actual drawing of this window.
After drawing is complete, we call endPaint() to signal that we are done rendering and present the contents in the back buffer using flush()
.
def render(self, painter): painter.drawText(QRectF(0, 0, width(), height()), Qt.AlignCenter, "QWindow")
The render function contains the drawing code for the window. In this minial example, we only draw the string “ QWindow
“ in the center.
Rendering Asynchronously#
def renderLater(self): requestUpdate()
We went through a few places where the window needed to repainted immediately. There are some cases where this is not desirable, but rather let the application return to the event loop and schedule the repaint for later. We achieve this by requesting an update, using requestUpdate()
, which will then be delivered when the system is ready to repaint.
def event(self, QEvent event): if event.type() == QEvent.UpdateRequest: renderNow() return True return QWindow.event(event)
We reimplement the virtual QObject::event() function to handle the update event. When the event comes in we call renderNow() to render the window right away.