4/15/2022
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  1. Qt Private Slots
  2. Qt Connect Slot
  3. Qt Virtual Slot

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This PyQt5 tutorial shows how to use Python 3 and Qt to create a GUI on Windows, Mac or Linux. It even covers creating an installer for your app.

What is PyQt5?

PyQt is a library that lets you use the Qt GUI framework from Python. Qt itself is written in C++. By using it from Python, you can build applications much more quickly while not sacrificing much of the speed of C++.

PyQt5 refers to the most recent version 5 of Qt. You may still find the occasional mention of (Py)Qt4 on the web, but it is old and no longer supported.

An interesting new competitor to PyQt is Qt for Python. Its API is virtually identical. Unlike PyQt, it is licensed under the LGPL and can thus be used for free in commercial projects. It's backed by the Qt company, and thus likely the future. We use PyQt here because it is more mature. Since the APIs are so similar, you can easily switch your apps to Qt for Python later.

Install PyQt

The best way to manage dependencies in Python is via a virtual environment. A virtual environment is simply a local directory that contains the libraries for a specific project. This is unlike a system-wide installation of those libraries, which would affect all of your other projects as well.

To create a virtual environment in the current directory, execute the following command:

This creates the venv/ folder. To activate the virtual environment on Windows, run:

On Mac and Linux, use:

You can see that the virtual environment is active by the (venv) prefix in your shell:

To now install PyQt, issue the following command:

The reason why we're using version 5.9.2 is that not all (Py)Qt releases are equally stable. This version is guaranteed to work. Besides this subtlety – Congratulations! You've successfully set up PyQt5.

Create a GUI

Time to write our very first GUI app! With the virtual environment still active, start Python. We will execute the following commands:

First, we tell Python to load PyQt via the import statement:

Next, we create a QApplication with the command:

This is a requirement of Qt: Every GUI app must have exactly one instance of QApplication. Many parts of Qt don't work until you have executed the above line. You will therefore need it in virtually every (Py)Qt app you write.

The brackets [] in the above line represent the command line arguments passed to the application. Because our app doesn't use any parameters, we leave the brackets empty.

Now, to actually see something, we create a simple label:

Then, we tell Qt to show the label on the screen:

Depending on your operating system, this already opens a tiny little window:

The last step is to hand control over to Qt and ask it to 'run the application until the user closes it'. This is done via the command:

If all this worked as expected then well done! You've just built your first GUI app with Python and Qt.

Widgets

Everything you see in a (Py)Qt app is a widget: Buttons, labels, windows, dialogs, progress bars etc. Like HTML elements, widgets are often nested. For example, a window can contain a button, which in turn contains a label.

The following screenshot shows the most common Qt widgets:

Top-to-bottom, left-to-right, they are:

You can download the code for the app shown in the screenshot here, if you are interested.

Layouts

Like the example above, your GUI will most likely consist of multiple widgets. In this case, you need to tell Qt how to position them. For instance, you can use QVBoxLayout to stack widgets vertically:

The code for this screenshot is:

As before, we instantiate a QApplication. Then, we create a window. We use the most basic type QWidget for it because it merely acts as a container and we don't want it to have any special behavior. Next, we create the layout and add two QPushButtons to it. Finally, we tell the window to use this layout (and thus its contents). As in our first application, we end with calls to .show() and app.exec_().

There are of course many other kinds of layouts (eg. QHBoxLayout to lay out items in a row). See Qt's documentation for an overview.

Custom styles

One of Qt's strengths is its support for custom styles. There are many mechanisms that let you customize the look and feel of your application. This section outlines a few.

Built-in styles

The coarsest way to change the appearance of your application is to set the global Style. Recall the widgets screenshot above:

This uses a style called Fusion. If you use the Windows style instead, then it looks as follows:

To apply a style, use app.setStyle(...):

The available styles depend on your platform but are usually 'Fusion', 'Windows', 'WindowsVista' (Windows only) and 'Macintosh' (Mac only).

Custom colors

If you like a style, but want to change its colors (eg. to a dark theme), then you can use QPalette and app.setPalette(...). For example:

This changes the text color in buttons to red:

For a dark theme of the Fusion style, see here.

Qt virtual slots

Style sheets

In addition to the above, you can change the appearance of your application via style sheets. This is Qt's analogue of CSS. We can use this for example to add some spacing:

For more information about style sheets, please see Qt's documentation.

Signals / slots

Qt virtual slot machine

Qt uses a mechanism called signals to let you react to events such as the user clicking a button. The following example illustrates this. It contains a button that, when clicked, shows a message box:

The interesting line is highlighted above: button.clicked is a signal, .connect(...) lets us install a so-called slot on it. This is simply a function that gets called when the signal occurs. In the above example, our slot shows a message box.

The term slot is important when using Qt from C++, because slots must be declared in a special way in C++. In Python however, any function can be a slot – we saw this above. For this reason, the distinction between slots and 'normal' functions has little relevance for us.

Signals are ubiquitous in Qt. And of course, you can also define your own. This however is beyond the scope of this tutorial.

Compile your app

You now have the basic knowledge for creating a GUI that responds to user input. Say you've written an app. It runs on your computer. How do you give it to other people, so they can run it as well?

You could ask the users of your app to install Python and PyQt like we did above, then give them your source code. But that is very tedious (and usually impractical). What we want instead is a standalone version of your app. That is, a binary executable that other people can run on their systems without having to install anything.

In the Python world, the process of turning source code into a self-contained executable is called freezing. Although there are many libraries that address this issue – such as PyInstaller, py2exe, cx_Freeze, bbfreze, py2app, ... – freezing PyQt apps has traditionally been a surprisingly hard problem.

Qt signal and slots

We will use a new library called fbs that lets you create standalone executables for PyQt apps. To install it, enter the command:

Then, execute the following:

This prompts you for a few values:

When you type in the suggested run command, an empty window should open:

This is a PyQt5 app just like the ones we have seen before. Its source code is in src/main/python/main.py in your current directory. But here's the cool part: We can use fbs to turn it into a standalone executable!

This places a self-contained binary in the target/MyApp/ folder of your current directory. You can send it to your friends (with the same OS as yours) and they will be able to run your app!

(Please note that fbs currently targets Python 3.5 or 3.6. If you have a different version and the above does not work, please install Python 3.6 and try again. On macOS, you can also install Python 3.5 with Homebrew.)

Bonus: Create an installer

fbs also lets you create an installer for your app via the command fbs installer:

(If you are on Windows, you first need to install NSIS and place it on your PATH.)

Qt Virtual Slot

Qt Private Slots

For more information on how you can use fbs for your existing application, please see this article. Or fbs's tutorial.

Summary

If you have made it this far, then big congratulations. Hopefully, you now have a good idea of how PyQt (and its various parts) can be used to write a desktop application with Python. We also saw how fbs lets you create standalone executables and installers.

Due to the popularity of this article, I wrote a PyQt5 book.

The book explains in more detail how you can create your own apps. Even Phil Thompson, the creator of PyQt, read the book and said it's 'very good'. So check it out!

Michael has been working with PyQt5 since 2016, when he started fman, a cross-platform file manager. Frustrated with the difficulties of creating a desktop app, Michael open sourced fman's build system (fbs). It saves you months when creating Python Qt GUIs. Recently, Michael also wrote a popular book about these two technologies.

Qt Connect Slot

It is common in Qt programming to override virtual C++ methods to customizebehavior, like listening for mouse events, implement drawing routines, etc.

Fortunately, both PyQt5 and PySide2 support overriding this virtual methodsnaturally in your python code:

In PyQt5 and PySide2, exceptions invirtual methods will by default call abort(), which will crash theinterpreter.

This might be surprising for python users which are used to exceptionsbeing raised at the calling point: for example, the following code will justprint a stack trace without raising any exception:

To make testing Qt code less surprising, pytest-qt automaticallyinstalls an exception hook which captures errors and fails tests when exceptionsare raised inside virtual methods, like this:

Disabling the automatic exception hook¶

You can disable the automatic exception hook on individual tests by using aqt_no_exception_capture marker:

Or even disable it for your entire project in your pytest.ini file:

This might be desirable if you plan to install a custom exception hook.

Note

Qt Virtual Slot

Starting with PyQt5.5, exceptions raised during virtual methods willactually trigger an abort(), crashing the Python interpreter. For thisreason, disabling exception capture in PyQt5.5+ is not recommendedunless you install your own exception hook.

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