Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
Writing QML Extensions with C++#
Tutorial about extending QML with Qt C++.
The Qt QML module provides a set of APIs for extending QML through C++ extensions. You can write extensions to add your own QML types, extend existing Qt types, or call C/C++ functions that are not accessible from ordinary QML code.
This tutorial shows how to write a QML extension using C++ that includes core QML features, including properties, signals and bindings. It also shows how extensions can be deployed through plugins.
Many of the topics covered in this tutorial are documented in further detail in Overview - QML and C++ Integration and its documentation sub-topics. In particular, you may be interested in the sub-topics Exposing Attributes of C++ Classes to QML and Defining QML Types from C++ .
Running the Tutorial Examples#
The code in this tutorial is available as an example project with subprojects associated with each tutorial chapter. In Qt Creator , open the Welcome mode and select the tutorial from Examples. In Edit mode, expand the extending-qml project, right-click on the subproject (chapter) you want to run and select Run.
Creating Tutorial Project#
We create a new project using the Qt Quick Application template in Qt Creator, as instructed in Qt Creator: Creating Qt Quick Projects .
Chapter 1: Creating a New Type#
extending-qml/chapter1-basics
A common task when extending QML is to provide a new QML type that supports some custom functionality beyond what is provided by the built-in Qt Quick types . For example, this could be done to implement particular data models, or provide types with custom painting and drawing capabilities, or access system features like network programming that are not accessible through built-in QML features.
In this tutorial, we will show how to use the C++ classes in the Qt Quick module to extend QML. The end result will be a simple Pie Chart display implemented by several custom QML types connected together through QML features like bindings and signals, and made available to the QML runtime through a plugin.
To begin with, let’s create a new QML type called “PieChart” that has two properties: a name and a color. We will make it available in an importable type namespace called “Charts”, with a version of 1.0.
We want this PieChart
type to be usable from QML like this:
To do this, we need a C++ class that encapsulates this PieChart
type and its two properties. Since QML makes extensive use of Qt’s meta object system , this new class must:
Inherit from
QObject
Declare its properties using the
Q_PROPERTY
macro
Class Declaration#
Here is our PieChart
class, defined in piechart.h
:
from PySide6.QtQuick import QtQuick/QQuickPaintedItem from PySide6.QtGui import QColor class PieChart(QQuickPaintedItem): Q_OBJECT Q_PROPERTY(QString name READ name WRITE setName FINAL) Q_PROPERTY(QColor color READ color WRITE setColor FINAL) QML_ELEMENT # public PieChart(QQuickItem parent = None) name = QString() def setName(name): color = QColor() def setColor(color): def paint(painter): # private m_name = QString() m_color = QColor()
The class inherits from QQuickPaintedItem
because we want to override paint()
to perform drawing operations with the QPainter
API. If the class just represented some data type and was not an item that actually needed to be displayed, it could simply inherit from QObject
. Or, if we want to extend the functionality of an existing QObject
-based class, it could inherit from that class instead. Alternatively, if we want to create a visual item that doesn’t need to perform drawing operations with the QPainter
API, we can just subclass QQuickItem
.
The PieChart
class defines the two properties, name
and color
, with the Q_PROPERTY
macro, and overrides paint()
. The PieChart
class is registered using the QML_ELEMENT
macro, to allow it to be used from QML. If you don’t register the class, app.qml
won’t be able to create a PieChart
.
qmake Setup#
For the registration to take effect, the qmltypes
option is added to CONFIG
in the project file and a QML_IMPORT_NAME
and QML_IMPORT_MAJOR_VERSION
are given:
CONFIG += qmltypes QML_IMPORT_NAME = Charts QML_IMPORT_MAJOR_VERSION = 1
CMake Setup#
Similarly, for the registration to take effect when using CMake, use the qt_add_qml_module command:
qt_add_qml_module(chapter1-basics URI Charts QML_FILES app.qml NO_RESOURCE_TARGET_PATH DEPENDENCIES QtQuick )
Class Implementation#
The class implementation in piechart.cpp
simply sets and returns the m_name
and m_color
values as appropriate, and implements paint()
to draw a simple pie chart. It also turns off the ItemHasNoContents
flag to enable painting:
def __init__(self, parent): super().__init__(parent) ... def paint(self, painter): pen = QPen(m_color, 2) painter.setPen(pen) painter.setRenderHints(QPainter.Antialiasing, True) painter.drawPie(boundingRect().adjusted(1, 1, -1, -1), 90 * 16, 290 * 16)
QML Usage#
Now that we have defined the PieChart
type, we will use it from QML. The app.qml
file creates a PieChart
item and displays the pie chart’s details using a standard QML Text item:
import Charts import QtQuick Item { width: 300; height: 200 PieChart { id: aPieChart anchors.centerIn: parent width: 100; height: 100 name: "A simple pie chart" color: "red" } Text { anchors { bottom: parent.bottom; horizontalCenter: parent.horizontalCenter; bottomMargin: 20 } text: aPieChart.name } }
Notice that although the color is specified as a string in QML, it is automatically converted to a QColor
object for the PieChart color
property. Automatic conversions are provided for various other value types . For example, a string like “640x480” can be automatically converted to a QSize
value.
We’ll also create a C++ application that uses a QQuickView
to run and display app.qml
.
Here is the application main.cpp
:
from piechart import * from PySide6.QtQuick import QtQuick/QQuickView from PySide6.QtGui import QGuiApplication if __name__ == "__main__": app = QGuiApplication(argc, argv) view = QQuickView() view.setResizeMode(QQuickView.SizeRootObjectToView) view.setSource(QUrl("qrc:///app.qml")) view.show() return QGuiApplication.exec()
Project Build#
To build the project we include the files, link against the libraries, and define a type namespace called “Charts” with version 1.0 for any types exposed to QML.
Using qmake:
<Code snippet "/data/qt5-full-650/6.5.0/Src/qtbase/tutorials/extending-qml/chapter1-basics/chapter1-basics.pro" not found>
Using CMake:
<Code snippet "/data/qt5-full-650/6.5.0/Src/qtbase/tutorials/extending-qml/chapter1-basics/CMakeLists.txt" not found>
Now we can build and run the application:
Note
You may see a warning Expression … depends on non-NOTIFYable properties: PieChart::name. This happens because we add a binding to the writable name
property, but haven’t yet defined a notify signal for it. The QML engine therefore cannot update the binding if the name
value changes. This is addressed in the following chapters.
The source code from the following files are referred to in this chapter:
Chapter 2: Connecting to C++ Methods and Signals#
extending-qml/chapter2-methods
Suppose we want PieChart
to have a “clearChart()” method that erases the chart and then emits a “chartCleared” signal. Our app.qml
would be able to call clearChart()
and receive chartCleared()
signals like this:
import Charts import QtQuick Item { width: 300; height: 200 PieChart { id: aPieChart anchors.centerIn: parent width: 100; height: 100 color: "red" onChartCleared: console.log("The chart has been cleared") } MouseArea { anchors.fill: parent onClicked: aPieChart.clearChart() } Text { anchors { bottom: parent.bottom; horizontalCenter: parent.horizontalCenter; bottomMargin: 20 } text: "Click anywhere to clear the chart" } }
To do this, we add a clearChart()
method and a chartCleared()
signal to our C++ class:
class PieChart(QQuickPaintedItem): ... # public ... Q_INVOKABLE void clearChart() # signals def chartCleared(): ...
The use of Q_INVOKABLE
makes the clearChart()
method available to the Qt Meta-Object system, and in turn, to QML. Note that it could have been declared as a Qt slot instead of using Q_INVOKABLE
, as slots are also callable from QML. Both of these approaches are valid.
The clearChart()
method simply changes the color to transparent
, repaints the chart, then emits the chartCleared()
signal:
def clearChart(self): setColor(QColor(Qt.transparent)) update() chartCleared.emit()
Now when we run the application and click the window, the pie chart disappears, and the application outputs:
qml: The chart has been cleared
The source code from the following files are referred to in this chapter:
Chapter 3: Adding Property Bindings#
extending-qml/chapter3-bindings
Property binding is a powerful feature of QML that allows values of different types to be synchronized automatically. It uses signals to notify and update other types’ values when property values are changed.
Let’s enable property bindings for the color
property. That means if we have code like this:
import Charts import QtQuick Item { width: 300; height: 200 Row { anchors.centerIn: parent spacing: 20 PieChart { id: chartA width: 100; height: 100 color: "red" } PieChart { id: chartB width: 100; height: 100 color: chartA.color } } MouseArea { anchors.fill: parent onClicked: { chartA.color = "blue" } } Text { anchors { bottom: parent.bottom; horizontalCenter: parent.horizontalCenter; bottomMargin: 20 } text: "Click anywhere to change the chart color" } }
The “color: chartA.color” statement binds the color
value of chartB
to the color
of chartA
. Whenever chartA
's color
value changes, chartB
's color
value updates to the same value. When the window is clicked, the onClicked
handler in the MouseArea changes the color of chartA
, thereby changing both charts to the color blue.
It’s easy to enable property binding for the color
property. We add a NOTIFY feature to its Q_PROPERTY()
declaration to indicate that a “colorChanged” signal is emitted whenever the value changes.
class PieChart(QQuickPaintedItem): ... Q_PROPERTY(QColor color READ color WRITE setColor NOTIFY colorChanged FINAL) # public ... # signals def colorChanged(): ...
Then, we emit this signal in setColor()
:
def setColor(self, color): if color != m_color: m_color = color update() # repaint with the color() colorChanged.emit()
It’s important for setColor()
to check that the color value has actually changed before emitting colorChanged()
. This ensures the signal is not emitted unnecessarily and also prevents loops when other types respond to the value change.
The use of bindings is essential to QML. You should always add NOTIFY signals for properties if they are able to be implemented, so that your properties can be used in bindings. Properties that cannot be bound cannot be automatically updated and cannot be used as flexibly in QML. Also, since bindings are invoked so often and relied upon in QML usage, users of your custom QML types may see unexpected behavior if bindings are not implemented.
The source code from the following files are referred to in this chapter:
Chapter 4: Using Custom Property Types#
extending-qml/chapter4-customPropertyTypes
The PieChart
type currently has a string-type property and a color-type property. It could have many other types of properties. For example, it could have an int-type property to store an identifier for each chart:
// C++ class PieChart : public QQuickPaintedItem { Q_PROPERTY(int chartId READ chartId WRITE setChartId NOTIFY chartIdChanged) ... public: void setChartId(int chartId); int chartId() const; ... signals: void chartIdChanged(); }; // QML PieChart { ... chartId: 100 }
Aside from int
, we could use various other property types. Many of the Qt data types such as QColor
, QSize
and QRect
are automatically supported from QML. (See Data Type Conversion Between QML and C++ documentation for a full list.)
If we want to create a property whose type is not supported by QML by default, we need to register the type with the QML engine.
For example, let’s replace the use of the property
with a type called “ PieSlice “ that has a color
property. Instead of assigning a color, we assign an PieSlice
value which itself contains a color
:
import Charts import QtQuick Item { width: 300; height: 200 PieChart { id: chart anchors.centerIn: parent width: 100; height: 100 pieSlice: PieSlice { anchors.fill: parent color: "red" } } Component.onCompleted: console.log("The pie is colored " + chart.pieSlice.color) }
Like PieChart
, this new PieSlice
type inherits from QQuickPaintedItem
and declares its properties with Q_PROPERTY()
:
class PieSlice(QQuickPaintedItem): Q_OBJECT Q_PROPERTY(QColor color READ color WRITE setColor FINAL) QML_ELEMENT # public PieSlice(QQuickItem parent = None) color = QColor() def setColor(color): def paint(painter): # private m_color = QColor()
To use it in PieChart
, we modify the color
property declaration and associated method signatures:
class PieChart(QQuickItem): Q_OBJECT Q_PROPERTY(PieSlice* pieSlice READ pieSlice WRITE setPieSlice FINAL) ... # public ... pieSlice = PieSlice() def setPieSlice(pieSlice): ...
There is one thing to be aware of when implementing setPieSlice()
. The PieSlice
is a visual item, so it must be set as a child of the PieChart
using setParentItem()
so that the PieChart
knows to paint this child item when its contents are drawn:
def setPieSlice(self, pieSlice): m_pieSlice = pieSlice pieSlice.setParentItem(self)
Like the PieChart
type, the PieSlice
type has to be exposted to QML using QML_ELEMENT
.
class PieSlice(QQuickPaintedItem): Q_OBJECT Q_PROPERTY(QColor color READ color WRITE setColor FINAL) QML_ELEMENT # public PieSlice(QQuickItem parent = None) color = QColor() def setColor(color): def paint(painter): # private m_color = QColor() ...
As with PieChart
, we add the “Charts” type namespace, version 1.0, to our build file:
Using qmake:
<Code snippet "/data/qt5-full-650/6.5.0/Src/qtbase/tutorials/extending-qml/chapter4-customPropertyTypes/chapter4-customPropertyTypes.pro" not found>
Using CMake:
... qt_add_executable(chapter4-customPropertyTypes main.cpp piechart.cpp piechart.h pieslice.cpp pieslice.h ) qt_add_qml_module(chapter4-customPropertyTypes URI Charts QML_FILES app.qml NO_RESOURCE_TARGET_PATH DEPENDENCIES QtQuick ) ...
The source code from the following files are referred to in this chapter:
Chapter 5: Using List Property Types#
extending-qml/chapter5-listproperties
Right now, a PieChart
can only have one PieSlice
. Ideally a chart would have multiple slices, with different colors and sizes. To do this, we could have a slices
property that accepts a list of PieSlice
items:
import Charts import QtQuick Item { width: 300; height: 200 PieChart { anchors.centerIn: parent width: 100; height: 100 slices: [ PieSlice { anchors.fill: parent color: "red" fromAngle: 0; angleSpan: 110 }, PieSlice { anchors.fill: parent color: "black" fromAngle: 110; angleSpan: 50 }, PieSlice { anchors.fill: parent color: "blue" fromAngle: 160; angleSpan: 100 } ] } }
To do this, we replace the pieSlice
property in PieChart
with a slices
property, declared as a QQmlListProperty
type. The QQmlListProperty
class enables the creation of list properties in QML extensions. We replace the pieSlice()
function with a slices()
function that returns a list of slices, and add an internal append_slice()
function (discussed below). We also use a QList
to store the internal list of slices as m_slices
:
class PieChart(QQuickItem): Q_OBJECT Q_PROPERTY(QQmlListProperty<PieSlice> slices READ slices FINAL) ... # public ... slices = QQmlListProperty() # private def append_slice(list, slice): m_name = QString() *> = QList<PieSlice()
Although the slices
property does not have an associated WRITE
function, it is still modifiable because of the way QQmlListProperty
works. In the PieChart
implementation, we implement PieChart::slices()
to return a QQmlListProperty
value and indicate that the internal PieChart::append_slice()
function is to be called whenever a request is made from QML to add items to the list:
QQmlListProperty<PieSlice> PieChart.slices() return QQmlListProperty<PieSlice>(this, nullptr.append_slice, nullptr, None, None, None, None) def append_slice(self, list, slice): chart = PieChart(list.object) if chart: slice.setParentItem(chart) chart.m_slices.append(slice)
The append_slice()
function simply sets the parent item as before, and adds the new item to the m_slices
list. As you can see, the append function for a QQmlListProperty
is called with two arguments: the list property, and the item that is to be appended.
The PieSlice
class has also been modified to include fromAngle
and angleSpan
properties and to draw the slice according to these values. This is a straightforward modification if you have read the previous pages in this tutorial, so the code is not shown here.
The source code from the following files are referred to in this chapter:
Chapter 6: Writing an Extension Plugin#
extending-qml/chapter6-plugins
Currently the PieChart
and PieSlice
types are used by app.qml
, which is displayed using a QQuickView
in a C++ application. An alternative way to use our QML extension is to create a plugin library to make it available to the QML engine as a new QML import module. This allows the PieChart
and PieSlice
types to be registered into a type namespace which can be imported by any QML application, instead of restricting these types to be only used by the one application.
The steps for creating a plugin are described in Creating C++ Plugins for QML . To start with, we create a plugin class named ChartsPlugin
. It subclasses QQmlEngineExtensionPlugin
and uses the Q_PLUGIN_METADATA()
macro to register the plugin with the Qt meta object system.
Here is the ChartsPlugin
definition in chartsplugin.h
:
class ChartsPlugin(QQmlEngineExtensionPlugin): Q_OBJECT Q_PLUGIN_METADATA(IID QQmlEngineExtensionInterface_iid)
Then, we configure the build file to define the project as a plugin library.
Using qmake:
<Code snippet "/data/qt5-full-650/6.5.0/Src/qtbase/tutorials/extending-qml/chapter6-plugins/Charts/Charts.pro" not found>
Using CMake:
<Code snippet "/data/qt5-full-650/6.5.0/Src/qtbase/tutorials/extending-qml/chapter6-plugins/Charts/CMakeLists.txt" not found>
When building this example on Windows or Linux, the Charts
directory will be located at the same level as the application that uses our new import module. This way, the QML engine will find our module as the default search path for QML imports includes the directory of the application executable. On macOS, the plugin binary is copied to Contents/PlugIns
in the the application bundle. With qmake, this path is set in chapter6-plugins/app.pro
:
To account for this, we also need to add this location as a QML import path in main.cpp
:
view = QQuickView() #ifdef Q_OS_OSX view.engine().addImportPath(app.applicationDirPath() + "/../PlugIns") #endif ...
Defining custom import paths is useful also when there are multiple applications using the same QML imports.
The .pro
file also contains additional magic to ensure that the module definition qmldir file is always copied to the same location as the plugin binary.
The qmldir
file declares the module name and the plugin that is made available by the module:
<Code snippet "/data/qt5-full-650/6.5.0/Src/qtbase/tutorials/extending-qml/chapter6-plugins/Charts/qmldir" not found>
Now we have a QML module that can be imported to any application, provided that the QML engine knows where to find it. The example contains an executable that loads app.qml
, which uses the import Charts 1.0
statement. Alternatively, you can load the QML file using the qml tool , setting the import path to the current directory so that it finds the qmldir
file:
qml -I . app.qml
The module “Charts” will be loaded by the QML engine, and the types provided by that module will be available for use in any QML document which imports it.
The source code from the following files are referred to in this chapter:
Chapter 7: Summary#
In this tutorial, we’ve shown the basic steps for creating a QML extension:
Define new QML types by subclassing
QObject
and registering them withQML_ELEMENT
orQML_NAMED_ELEMENT()
Add callable methods using
Q_INVOKABLE
or Qt slots, and connect to Qt signals with anonSignal
syntaxAdd property bindings by defining NOTIFY signals
Define custom property types if the built-in types are not sufficient
Define list property types using
QQmlListProperty
Create a plugin library by defining a Qt plugin and writing a qmldir file
The QML and C++ Integration overview documentation shows other useful features that can be added to QML extensions. For example, we could use default properties to allow slices to be added without using the slices
property:
PieChart { PieSlice { ... } PieSlice { ... } PieSlice { ... } }
Or randomly add and remove slices from time to time using property value sources :
PieChart { PieSliceRandomizer on slices {} }