Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
Sliders Example#
The Sliders example shows how to use the different types of sliders available in Qt: QSlider
, QScrollBar
and QDial
.
Qt provides three types of slider-like widgets: QSlider
, QScrollBar
and QDial
. They all inherit most of their functionality from QAbstractSlider
, and can in theory replace each other in an application since the differences only concern their look and feel. This example shows what they look like, how they work and how their behavior and appearance can be manipulated through their properties.
The example also demonstrates how signals and slots can be used to synchronize the behavior of two or more widgets, and how to override resizeEvent()
to implement a responsive layout.
Screenshot of the Sliders example
The Sliders example consists of two classes:
SlidersGroup
is a custom widget. It combines aQSlider
, aQScrollBar
and aQDial
.
Window
is the main widget combining aQGroupBox
and a SlidersGroup. TheQGroupBox
contains several widgets that control the behavior of the slider-like widgets.
First we will review the Window
class, then we will take a look at the SlidersGroup
class.
Window Class Definition#
class Window(QWidget): Q_OBJECT # public Window(QWidget parent = None) # private def createControls(title): def resizeEvent(e): slidersGroup = SlidersGroup() controlsGroup = QGroupBox() minimumLabel = QLabel() maximumLabel = QLabel() valueLabel = QLabel() invertedAppearance = QCheckBox() invertedKeyBindings = QCheckBox() minimumSpinBox = QSpinBox() maximumSpinBox = QSpinBox() valueSpinBox = QSpinBox() layout = QBoxLayout()
The Window
class inherits from QWidget
. It displays the slider widgets and allows the user to set their minimum, maximum and current values and to customize their appearance, key bindings and orientation. We use a private createControls()
function to create the widgets that provide these controlling mechanisms and to connect them to the slider widgets.
Window Class Implementation#
def __init__(self, parent): super().__init__(parent) slidersGroup = SlidersGroup(tr("Sliders")) createControls(tr("Controls"))
In the constructor we first create the SlidersGroup
widget that displays the slider widgets. With createControls()
we create the controlling widgets, and connect those to to the sliders.
layout = QBoxLayout(QBoxLayout.LeftToRight) layout.addWidget(controlsGroup) layout.addWidget(slidersGroup) setLayout(layout) minimumSpinBox.setValue(0) maximumSpinBox.setValue(20) valueSpinBox.setValue(5) setWindowTitle(tr("Sliders"))
We put the groups of control widgets and the sliders in a horizontal layout before we initialize the minimum, maximum and current values. The initialization of the current value will propagate to the slider widgets through the connection we made between valueSpinBox
and the SlidersGroup
widgets. The minimum and maximum values propagate through the connections we created with createControls()
.
def createControls(self, title): controlsGroup = QGroupBox(title) minimumLabel = QLabel(tr("Minimum value:")) maximumLabel = QLabel(tr("Maximum value:")) valueLabel = QLabel(tr("Current value:")) invertedAppearance = QCheckBox(tr("Inverted appearance")) invertedKeyBindings = QCheckBox(tr("Inverted key bindings"))
In the private createControls()
function, we let a QGroupBox
(controlsGroup
) display the control widgets. A group box can provide a frame, a title and a keyboard shortcut, and displays various other widgets inside itself. The group of control widgets is composed by two checkboxes, and three spin boxes with labels.
After creating the labels, we create the two checkboxes. Checkboxes are typically used to represent features in an application that can be enabled or disabled. When invertedAppearance
is enabled, the slider values are inverted. The table below shows the appearance for the different slider-like widgets:
Normal
Inverted
Normal
Inverted
Normal
Inverted
Qt::Horizontal
Left to right
Right to left
Left to right
Right to left
Clockwise
Counterclockwise
Qt::Vertical
Bottom to top
Top to bottom
Top to bottom
Bottom to top
Clockwise
Counterclockwise
It is common to invert the appearance of a vertical QSlider
. A vertical slider that controls volume, for example, will typically go from bottom to top (the non-inverted appearance), whereas a vertical slider that controls the position of an object on screen might go from top to bottom, because screen coordinates go from top to bottom.
When the invertedKeyBindings
option is enabled (corresponding to the invertedControls
property), the slider’s wheel and key events are inverted. The normal key bindings mean that scrolling the mouse wheel “up” or using keys like page up will increase the slider’s current value towards its maximum. Inverted, the same wheel and key events will move the value toward the slider’s minimum. This can be useful if the appearance of a slider is inverted: Some users might expect the keys to still work the same way on the value, whereas others might expect PageUp to mean “up” on the screen.
Note that for horizontal and vertical scroll bars, the key bindings are inverted by default: PageDown increases the current value, and PageUp decreases it.
minimumSpinBox = QSpinBox() minimumSpinBox.setRange(-100, 100) minimumSpinBox.setSingleStep(1) maximumSpinBox = QSpinBox() maximumSpinBox.setRange(-100, 100) maximumSpinBox.setSingleStep(1) valueSpinBox = QSpinBox() valueSpinBox.setRange(-100, 100) valueSpinBox.setSingleStep(1)
Then we create the spin boxes. QSpinBox
allows the user to choose a value by clicking the up and down buttons or pressing the Up and Down keys on the keyboard to modify the value currently displayed. The user can also type in the value manually. The spin boxes control the minimum, maximum and current values for the QSlider
, QScrollBar
, and QDial
widgets.
slidersGroup.valueChanged.connect( valueSpinBox.setValue) valueSpinBox.valueChanged.connect( slidersGroup.setValue) minimumSpinBox.valueChanged.connect( slidersGroup.setMinimum) maximumSpinBox.valueChanged.connect( slidersGroup.setMaximum) invertedAppearance.toggled.connect( slidersGroup.invertAppearance) invertedKeyBindings.toggled.connect( slidersGroup.invertKeyBindings) controlsLayout = QGridLayout() controlsLayout.addWidget(minimumLabel, 0, 0) controlsLayout.addWidget(maximumLabel, 1, 0) controlsLayout.addWidget(valueLabel, 2, 0) controlsLayout.addWidget(minimumSpinBox, 0, 1) controlsLayout.addWidget(maximumSpinBox, 1, 1) controlsLayout.addWidget(valueSpinBox, 2, 1) controlsLayout.addWidget(invertedAppearance, 0, 2) controlsLayout.addWidget(invertedKeyBindings, 1, 2) controlsGroup.setLayout(controlsLayout)
Then we connect the slidersGroup
and the valueSpinBox
to each other, so that the slider widgets and the control widget will behave synchronized when the current value of one of them changes. The valueChanged()
signal is emitted with the new value as argument. The setValue()
slot sets the current value of the widget to the new value, and emits valueChanged()
if the new value is different from the old one.
We synchronize the behavior of the control widgets and the slider widgets through their signals and slots. We connect each control widget to both the horizontal and vertical group of slider widgets. We also connect orientationCombo
to the QStackedWidget
, so that the correct “page” is shown. Finally, we lay out the control widgets in a QGridLayout
within the controlsGroup
group box.
def resizeEvent(self, arg__0): if width() == 0 or height() == 0: return aspectRatio = double(width()) / double(height()) if aspectRatio < 1.0: layout.setDirection(QBoxLayout.TopToBottom) slidersGroup.setOrientation(Qt.Horizontal) elif aspectRatio > 1.0: layout.setDirection(QBoxLayout.LeftToRight) slidersGroup.setOrientation(Qt.Vertical)
Lastly, we override resizeEvent() from QWidget
. We guard against dividing by zero, and otherwise compute the aspect ratio of the widget. If the window has a portrait format, then we set the layout to organize the groups of control widgets and sliders vertically, and we give the sliders a horizontal orientation. If the window has a landscape format, then we change the layout to show the sliders and controlling widgets side by side, and give the sliders a vertical orientation.
SlidersGroup Class Definition#
class SlidersGroup(QGroupBox): Q_OBJECT # public SlidersGroup(QString title, QWidget parent = None) # signals def valueChanged(value): # public slots def setValue(value): def setMinimum(value): def setMaximum(value): def invertAppearance(invert): def invertKeyBindings(invert): def setOrientation(orientation): # private slider = QSlider() scrollBar = QScrollBar() dial = QDial() slidersLayout = QBoxLayout()
The SlidersGroup
class inherits from QGroupBox
. It provides a frame and a title, and contains a QSlider
, a QScrollBar
and a QDial
.
We provide a valueChanged()
signal and a public setValue()
slot with equivalent functionality to the ones in QAbstractSlider
and QSpinBox
. In addition, we implement several other public slots to set the minimum and maximum value, and invert the slider widgets’ appearance as well as key bindings, and set the orientation.
SlidersGroup Class Implementation#
def __init__(self, title, parent): super().__init__(title, parent) slider = QSlider() slider.setFocusPolicy(Qt.StrongFocus) slider.setTickPosition(QSlider.TicksBothSides) slider.setTickInterval(10) slider.setSingleStep(1) scrollBar = QScrollBar() scrollBar.setFocusPolicy(Qt.StrongFocus) dial = QDial() dial.setFocusPolicy(Qt.StrongFocus)
First we create the slider-like widgets with the appropriate properties. In particular we set the focus policy for each widget. Qt::FocusPolicy is an enum type that defines the various policies a widget can have with respect to acquiring keyboard focus. The Qt::StrongFocus policy means that the widget accepts focus by both tabbing and clicking.
slider.valueChanged.connect(scrollBar.setValue) scrollBar.valueChanged.connect(dial.setValue) dial.valueChanged.connect(slider.setValue) dial.valueChanged.connect(self.valueChanged)
Then we connect the widgets with each other, so that they will stay synchronized when the current value of one of them changes.
We connect dial
's valueChanged()
signal to the SlidersGroup
's valueChanged()
signal, to notify the other widgets in the application (i.e., the control widgets) of the changed value.
slidersLayout = QBoxLayout(QBoxLayout.LeftToRight) slidersLayout.addWidget(slider) slidersLayout.addWidget(scrollBar) slidersLayout.addWidget(dial) setLayout(slidersLayout)
Finally, we create the layout for the slider widgets within the group box. We start with a horizontal arrangement of the sliders.
def setValue(self, value): slider.setValue(value)
The setValue()
slot sets the value of the QSlider
. We don’t need to explicitly call setValue()
on the QScrollBar
and QDial
widgets, since QSlider
will emit the valueChanged()
signal when its value changes, triggering a domino effect.
def setMinimum(self, value): slider.setMinimum(value) scrollBar.setMinimum(value) dial.setMinimum(value) def setMaximum(self, value): slider.setMaximum(value) scrollBar.setMaximum(value) dial.setMaximum(value)
The setMinimum()
and setMaximum()
slots are used by the Window
class to set the range of the QSlider
, QScrollBar
, and QDial
widgets.
def invertAppearance(self, invert): slider.setInvertedAppearance(invert) scrollBar.setInvertedAppearance(invert) dial.setInvertedAppearance(invert) def invertKeyBindings(self, invert): slider.setInvertedControls(invert) scrollBar.setInvertedControls(invert) dial.setInvertedControls(invert)
The invertAppearance()
and invertKeyBindings()
slots control the child widgets’ invertedAppearance
and invertedControls
properties.
def setOrientation(self, orientation): slidersLayout.setDirection(orientation == Qt.Horizontal ? QBoxLayout.TopToBottom super().__init__() scrollBar.setOrientation(orientation) slider.setOrientation(orientation)
The setOrientation() slot controls the direction of the layout and the orientation of the sliders. In a horizontal group, the sliders have a horizontal orientation, and are laid out on top of each other. In a vertical group, the sliders have a vertical orientation, and are laid out next to each other.