Back from ELCE 2019: our talks videos, slides, and more!

With 8 engineers participating to the Embedded Linux Conference Europe, almost the entire Bootlin engineering team took part to the conference. As usual, we not only attended the event, but also contributed by giving a total of 5 talks and 2 tutorials, for which we’re happy to share below the videos and slides. Also, as part of this conference, Bootlin CTO Thomas Petazzoni received an award for his contribution to the conference.

Buildroot, what’s new ?

Talk given by Thomas Petazzoni, slides in PDF and slides source code.

Timing boot time reduction techniques

Talk given by Michael Opdenacker, slides in PDF, slides source code.

Integrating hardware-accelerated video decoding with the display stack

Talk given by Paul Kocialkowski, slides in PDF, slides source code.

RTC subsystem, recent changes and where it is heading

Talk given by Alexandre Belloni, slides in PDF, slides source code.

Flash subsystems status update

Talk given by Miquèl Raynal (from Bootlin) and Richard Weinberger (from sigma star gmbh), slides in PDF, slides source code.

Offloading network traffic classification to hardware

Talk given by Maxime Chevallier, slides in PDF, slides source code.

Introduction to Linux Kernel driver programming

Tutorial given by Michael Opdenacker, slides in PDF, slides source document. The video is not yet available, but should be published in the future.

Introduction to the Buildroot embedded Linux build system

Tutorial given by Thomas Petazzoni, slides in PDF, slides source code. The video is not yet available, but should be published in the future.

Award to Thomas Petazzoni

During the traditional closing game of the conference, we were really happy to have Bootlin’s CTO Thomas Petazzoni called on stage, to receive from the hands of Tim Bird, an award for his continuous 11 year participation to the conference, with 24 presentations given, one keynote and for the past two years, participation to the conference program committee. We are honored and proud by this recognition of Thomas contribution to the conference.

Thomas Petazzoni receives ELCE conference award

Thomas Petazzoni receives ELCE conference award

Thomas Petazzoni receives ELCE conference award

Internships for 2020 at Bootlin

Bootlin penguins at workFor 2020, Bootlin proposes five internship topics, this time open to all students from the European Union, studying in European Universities.

All these topics will give you an opportunity to make substantial (and very useful!) contributions to an open-source project.

Here are the details about our internship topics:

As you can see, all these topics propose both a challenging technical opportunity, but also require strong interaction with the community of users and developers of free and open-source software used in embedded projects.

More details are available in the descriptions. The internships can start from February 2020, for a minimum duration of 4 months. These internships will take place either in our offices in Toulouse, Lyon or Orange, in France, depending on the topics. These internships are open to all students from the European Union.

For all questions about our internships, please contact jobs@bootlin.com

Yocto Project training course available on STM32MP1 platform

Back in May 2019, we announced the availability of our Embedded Linux system development course on the STMicroelectronics STM32MP1 platform, in addition to the already supported Microchip SAMA5D3 Xplained board.

In the context of our partnership with STMicroelectronics, we are now happy to announce the availability of our Yocto Project and OpenEmbedded development training also on the STM32MP1 platform for the practical labs. We now support either the BeagleBoneBlack Wireless or the STMicroelectronics STM32MP1 platforms for this training course.

The complete training materials are available: detailed agenda, slides and practical labs. The complete source code of the training materials is also available in our Github repository.

Bootlin Yocto course on STM32MP1
Slides of Bootlin’s Yocto course for the STM32MP1

This will hopefully help customers around the world to get started with using Yocto on the STM32MP1 system-on-chip. The Yocto experts at Bootlin are available to deliver this 3-day course anywhere in the world, at your location. The first edition of this new variant of the course is going to be given this week to one of our customers in Spain. Contact us if you’re interested by having this course organized at your location!

Publication of Linux graphics training materials

Back in June 2019, we announced the availability of a new training course, Displaying and rendering graphics with Linux. At the time of this announcement, the training materials were not available though.

Since then, Bootlin engineer Paul Kocialkowski has been very busy preparing those training materials, and has successfully delivered the first edition of this course to one of our customers in Spain early September. After taking the time to polish those training materials following this first course, we are now very happy to publish and share this 200+ slides deck, covering a wide range of graphics related topics:

  • Image and color representation
  • Basic drawing
  • Basic and advanced operations
  • Hardware aspects overview
  • Hardware for display
  • Hardware for rendering
  • Memory aspects
  • Performance aspects
  • Software aspects overview
  • Kernel components in Linux
  • Userspace components with Linux

See also the detailed agenda of this training course. The LaTeX source code for all our training materials, including this graphics training, is available in a Git repository. It is worth mentioning that this training only consists of slides and demos, and does not include practical labs done by the participants, in order to keep the training logistics manageable and the duration reasonably short (2 days).

Here are a few slides showing various aspects of this training course:

Graphics training

Graphics training

Graphics training

Graphics training

Graphics training

By publishing this training materials right after our first course, and under the Creative Commons CC-BY-SA license, Bootlin sticks to its commitment of publishing all its training materials under a free documentation license, to better spread the knowledge in the entire embedded Linux community.

We are available to deliver this Displaying and rendering graphics with Linux course anywhere in the world, at your location. Contact us for more details.

Linux 5.3 released, Bootlin contributions inside

Penguin from Mylène Josserand
Drawing from Mylène Josserand, based on a picture from Samuel Blanc (https://commons.wikimedia.org/wiki/File:Manchot_royal_-_King_Penguin.jpg)
The 5.3 version of the Linux kernel was released recently. As usual, we recommend our readers to look at the LWN coverage for this release merge window: part 1 and part 2. Together with the KernelNewbies page, these articles give a very nice overview of the major features and improvements of this new release.

For this release, Bootlin is the 16th contributing company by number of commits, with 143 patches merged in the Linux kernel. Our significant contributions this time were:

  • Support for Allwinner processors
    • The support for H264 video decoding, from Maxime Ripard, was finally merged in the cedrus VPU driver that we have developed thanks to the funding of our Kickstarter campaign last year. The last missing piece is H265 video decoding, which we have submitted several times and we hope to get merged soon.
  • Support for Marvell platforms
    • Antoine Ténart contributed a number of bug fixes and updates to the inside-secure crypto driver, which is used for the cryptographic hardware accelerator found on Marvell Armada 3700 and Marvell Armada 7K/8K.
    • Maxime Chevallier contributed many improvements to the mvpp2 network driver, used on the Marvell Armada 375 and Armada 7K/8K systems. His patches improve the traffic classification offloading capabilities, a topic he will present in detail at the next Embedded Linux Conference Europe.
    • Miquèl Raynal added PHY support for the PCIe Armada 8K driver, and adjusted a few things in the Marvell Armada 7K/8K Device Tree files.
  • Support for Microchip MPU (formerly Atmel) platforms
    • Alexandre Belloni converted the remaining SoCs (SAM9x5, SAM9G45, SAM9RL and SAMA5D3) to the new slow clock controller bindings.
    • Antoine Ténart contributed a few small improvements to the macb driver, for the Cadence network controller used on Microchip platforms.
  • Maxime Ripard contributed numerous YAML Device Tree schemas, to help the effort of converting many Device Tree bindings to the new YAML format, which can be used to validate Device Trees against their bindings.
  • Maxime Ripard contributed numerous patches to the core DRM subsystem: a complete rewrite of the command line parser that parses the DRM-related options of the kernel command line, and support for new options. This was done as part of an effort to make sure the upstream Linux kernel can support all the possible options that the downstream RaspberryPi kernel+firmware combination provides to configure the display.
  • Paul Kocialkowski contributed a few improvements to the RaspberryPi vc4 display controller driver, related to buffer allocation.

Also, several of Bootlin engineers are also kernel maintainers, so they review and merge patches from other contributors:

  • Miquèl Raynal as the NAND subsystem maintainer and MTD subsystem co-maintainer, reviewed and merged 51 patches from other contributors
  • Maxime Ripard as the Allwinner platform co-maintainer, reviewed and merged 38 patches from other contributors
  • Alexandre Belloni as the RTC maintainer and Microchip platform co-maintainer, reviewed and merged 36 patches from other contributors
  • Grégory Clement as the Marvell EBU platform co-maintainer, reviewed and merged 9 patches from other contributors

Here is the details of all our contributions, patch by patch:

Building a Linux system for the STM32MP1: developing a Qt5 graphical application

After showing how to build a minimal Linux system for the STM32MP157 platform, how to connect and use an I2C based pressure/temperature/humidity sensor and how to integrate Qt5 in our system, how to set up a development environment to write our own Qt5 application, we are finally going to write our Qt5 application.

List of articles in this series:

  1. Building a Linux system for the STM32MP1: basic system
  2. Building a Linux system for the STM32MP1: connecting an I2C sensor
  3. Building a Linux system for the STM32MP1: enabling Qt5 for graphical applications
  4. Building a Linux system for the STM32MP1: setting up a Qt5 application development environment
  5. Building a Linux system for the STM32MP1: developing a Qt5 graphical application

Disclaimer

Before we get started in this blog post, it is important to mention that it is not meant to be a full introduction to programming applications with Qt5. This would require much more than a blog post, and the Qt web site has extensive documentation.

Also, we want to make it clear that Bootlin’s core expertise is in low-level embedded Linux development, not in Qt application development. Therefore, our example application may not show the best practices in terms of Qt development. We welcome comments and suggestions from our readers to improve the example used in this blog post.

Reading sensor data

As we’ve seen in a previous article, the sensor data is available by reading the following files:

  • /sys/bus/iio/devices/iio:device2/in_temp_input for the temperature
  • /sys/bus/iio/devices/iio:device2/in_pressure_input for the pressure
  • /sys/bus/iio/devices/iio:device2/in_humidityrelative_input for the humidity

So what we will do is writing a new class called DataProvider, which will read those files once per second, and emit a signal with the 3 values every second. Slots and signals is a fundamental mechanism in Qt, which allows to connect emitters of events to receivers for those events. In our case, the DataProvider class will emit a signal when new sensor values are read, while another class in charge of the graphical UI will receive those signals.

At this step, we don’t yet have a graphical UI, so we’ll simply add a few debugging messages in the DataProvider to make sure it works as expected.

Let’s start by adding a data-provider.h file to our project:

#ifndef DATA_PROVIDER_H
#define DATA_PROVIDER_H

#include <QtCore/QTimer>

class DataProvider: public QObject
{
    Q_OBJECT

public:
    DataProvider();

private slots:
    void handleTimer();

signals:
    void valueChanged(float temp, float pressure, float humidity);

private:
    QTimer timer;
};

#endif /* DATA_PROVIDER_H */

It creates a very simple class than inherits from QObject, with:

  • A constructor
  • A private slot handleTimer which will be used internally by the class QTimer’s instance to notify that a timer has expired. This is what will allow us to poll the sensor values every second.
  • A valueChanged signal, which will be emitted by the class every time new sensor values are available.

Then, the implementation of this class in data-provider.cpp is fairly straight-forward:

#include <QtCore/QFile>
#include <QDebug>
#include "data-provider.h"

DataProvider::DataProvider()
{
    QObject::connect(&timer, &QTimer::timeout,
		     this, &DataProvider::handleTimer);
    timer.setInterval(1000);
    timer.start();
}

void DataProvider::handleTimer()
{
    QFile temp_f("/sys/bus/iio/devices/iio:device2/in_temp_input");
    QFile pressure_f("/sys/bus/iio/devices/iio:device2/in_pressure_input");
    QFile humidity_f("/sys/bus/iio/devices/iio:device2/in_humidityrelative_input");

    if (!temp_f.open(QIODevice::ReadOnly | QIODevice::Text))
        return;
    if (!pressure_f.open(QIODevice::ReadOnly | QIODevice::Text))
        return;
    if (!humidity_f.open(QIODevice::ReadOnly | QIODevice::Text))
        return;

    float temp = QString(temp_f.readAll()).toDouble() / 1000;
    float pressure = QString(pressure_f.readAll()).toDouble() * 10;
    float humidity = QString(humidity_f.readAll()).toDouble() / 1000;

    qDebug() << "Temperature: " << temp << "Pressure: " << pressure << "Humidity: " << humidity;

    emit valueChanged(temp, pressure, humidity);
}

The constructor of the class connects the QTimer::timeout signal of the QTimer to this class handlerTimer slot, sets the timer interval to 1000 milliseconds, and starts the timer. This is what will ensure the handleTimer method gets called every second.

In the handleTimer method, we open the 3 files in sysfs, read their value and convert them to meaningful units: the temperature in Celcius, the pressure in hPA, and the humidity in percent. We then print a debugging message and emit the signal with the three values.

With this in place, we need to make sure those two files are properly taken into account by our project, by changing the .pro file as follows:

QT += widgets
SOURCES = main.cpp data-provider.cpp
HEADERS = data-provider.h
INSTALLS += target
target.path = /usr/bin

The data-provider.cpp file was added to SOURCES, while data-provider.h was added to the new HEADERS.

Now, we just need to change main.cpp to instantiate one DataProvider object:

#include <QApplication>
#include <QPushButton&ht;
#include "data-provider.h"

int main(int argc, char* argv[])
{
    QApplication app(argc, argv);
    QPushButton hello("Hello world!");
    DataProvider dp;
    hello.resize(100,30);
    hello.show();
    return app.exec();
}

With this, you can now build and run the application, and you should see every second the debugging message showing the temperature, pressure and humidity values:

# qt-sensor-demo -platform linuxfb
Temperature:  28.12  Pressure:  1003.08  Humidity:  32.235
Temperature:  28.12  Pressure:  1003.07  Humidity:  32.246
Temperature:  28.12  Pressure:  1003.06  Humidity:  32.256
Temperature:  28.12  Pressure:  1003.08  Humidity:  32.267

Displaying sensor data

We now want to display the sensor data. For this, we'll create a UI with two panels, one to display the numeric value of the temperature, humidity and pressure, and another panel with a chart of the temperature. At the bottom of the screen, two buttons Values and Chart will allow to switch between both panels.

So, we'll create a Window class to encapsulate the overall window layout and behavior, and a Values class providing the widget showing the 3 values. We'll leave the chart implementation to the next section. To help you follow the code in this section, here is a diagram that shows the different widgets and how they will be grouped together in our user interface:

Qt Sensor demo UI

Let's start by implementing the Values widget, which will be used to show the 3 numeric values, one below each other. The values.h file will look like this:

#ifndef VALUES_H
#define VALUES_H

#include <QWidget>

class QLabel;

class Values : public QWidget
{
    Q_OBJECT

public:
    Values();

public slots:
    void handleValueChanged(float temp, float pressure, float humidity);

private:
    QLabel *temperature_v;
    QLabel *pressure_v;
    QLabel *humidity_v;
};

#endif /* VALUES_H */

So it has a simple constructor, a slot to be notified of new values available, and 3 text labels to display the 3 values. The implementation in values.cpp is:

// SPDX-License-Identifier: MIT
#include <QtWidgets>
#include "values.h"

Values::Values()
{
    QVBoxLayout *layout = new QVBoxLayout;

    QLabel *temperature_l = new QLabel(tr("Temperature (°C)"));
    QLabel *pressure_l = new QLabel(tr("Pressure (hPa)"));
    QLabel *humidity_l = new QLabel(tr("Humidity (%)"));

    temperature_v = new QLabel();
    pressure_v = new QLabel();
    humidity_v = new QLabel();

    QFont f = temperature_v->font();
    f.setPointSize(28);
    f.setBold(true);
    temperature_v->setFont(f);
    pressure_v->setFont(f);
    humidity_v->setFont(f);
    temperature_v->setAlignment(Qt::AlignRight | Qt::AlignVCenter);
    pressure_v->setAlignment(Qt::AlignRight | Qt::AlignVCenter);
    humidity_v->setAlignment(Qt::AlignRight | Qt::AlignVCenter);

    layout->addWidget(temperature_l);
    layout->addWidget(temperature_v);
    layout->addWidget(pressure_l);
    layout->addWidget(pressure_v);
    layout->addWidget(humidity_l);
    layout->addWidget(humidity_v);

    setLayout(layout);
}

void Values::handleValueChanged(float temp, float pressure, float humidity)
{
    temperature_v->setText(QString::number(temp, 'f', 2));
    pressure_v->setText(QString::number(pressure, 'f', 1));
    humidity_v->setText(QString::number(humidity, 'f', 1));
}

The constructor creates 3 text labels for the legends ("Temperature (°C)", "Pressure (hPA)" and "Humidity (%)"), then instantiates the 3 text labels for the values themselves. It sets up the font and text alignment properties for those labels, and then adds all widgets in a QVBoxLayout so that they all appear vertically below each other.

The handleValueChanged slot simply updates the text labels contents with the new sensor values, doing the proper text formatting on the way.

With the Values class implemented, we can now implement the main Window class. The window.h will contain:

#ifndef WINDOW_H
#define WINDOW_H

#include <QWidget>

class Values;

class Window : public QWidget
{
    Q_OBJECT

public slots:
    void handleValueChanged(float temp, float pressure, float humidity);

public:
    Window();

private:
    Values *values;
};

#endif

Beyond a simple constructor, it has a slot to receive new sensor values, and a reference to a Values widget instance.

The implementation in window.cpp is as follows:

#include <QtWidgets>

#include "window.h"
#include "values.h"

Window::Window()
{
    values = new Values;
    QVBoxLayout *layout = new QVBoxLayout;
    QHBoxLayout *buttons = new QHBoxLayout;

    QPushButton *values_button = new QPushButton("Values");
    QPushButton *chart_button = new QPushButton("Chart");

    buttons->addWidget(values_button);
    buttons->addWidget(chart_button);

    layout->addWidget(values);
    layout->addLayout(buttons);

    setLayout(layout);

    setWindowTitle(tr("Sensors"));
}

void Window::handleValueChanged(float temp, float pressure, float humidity)
{
    values->handleValueChanged(temp, pressure, humidity);
}

The constructor creates a horizontal layout QHBoxLayout with two buttons: Values and Chart. Those will be used in the next section to switch between the Values panel and the Chart panel. For now, they don't do anything.

Then, the constructor adds the Value widget, and the horizontal layout box with the buttons into a vertical box layout, assigns the main window layout and defines the window title.

The handleValueChanged slot implementation just forwards the call to the Values::handleValueChanged method.

Now, obviously main.cpp needs to be changed: instead of creating a button, we'll create our window, and do a bit of additional setup:

#include <QApplication>
#include "window.h"
#include "data-provider.h"

int main(int argc, char* argv[])
{
    QApplication app(argc, argv);
    DataProvider dp;
    Window window;

    QObject::connect(&dp, &DataProvider::valueChanged,
		     &window, &Window::handleValueChanged);

    window.setFixedSize(480, 800);
    window.setStyleSheet("background-color: white;");
    window.show();
    return app.exec();
}

So, not only we create the Window, but more importantly, we connect the valueChanged signal of DataProvider to the handleValueChanged slot of Window. We define the window size (which is fixed, to match the STM32MP15 Discovery board panel) and set the background color of the application.

Obviously, the qt-sensor-demo.pro file needs to be adjusted to build our new files. It now looks like this:

QT += widgets
SOURCES = main.cpp data-provider.cpp window.cpp values.cpp
HEADERS = data-provider.h window.h values.h
INSTALLS += target
target.path = /usr/bin

With this done, we can run the Qt5 application on our target, and see:

Qt5 application showing the I2C sensor data

Graphing the temperature

The final part of developing our application is to implement a graph showing the evolution of temperature over time. For this, we are going to use the very convenient Qt Charts module, which is available in a separate Qt module from the base of Qt.

To implement the graph widget itself, we'll create a new Chart class:

#ifndef CHART_H
#define CHART_H

#include <QtCharts/QChart>

QT_CHARTS_BEGIN_NAMESPACE
class QSplineSeries;
class QValueAxis;
QT_CHARTS_END_NAMESPACE

QT_CHARTS_USE_NAMESPACE

class Chart: public QChart
{
    Q_OBJECT

public:
    Chart(QGraphicsItem *parent = 0, Qt::WindowFlags wFlags = 0);

public slots:
    void handleValueChanged(float temp, float pressure, float humidity);

private:
    QSplineSeries *m_series;
    QStringList m_titles;
    QValueAxis *m_axisX;
    QValueAxis *m_axisY;
    int xpos;
};

#endif /* CHART_H */

This class inherits from the QChart class provided by Qt. It provides a constructor and destructor, a slot that allows to receive notification of new sensor values, and it has a number of private variables to manage the chart itself.

Let's go through the implementation of this class now:

#include "chart.h"
#include <QtCharts/QAbstractAxis>
#include <QtCharts/QSplineSeries>
#include <QtCharts/QValueAxis>

Chart::Chart(QGraphicsItem *parent, Qt::WindowFlags wFlags):
    QChart(QChart::ChartTypeCartesian, parent, wFlags),
    m_series(0),
    m_axisX(new QValueAxis()),
    m_axisY(new QValueAxis()),
    xpos(0)
{
    m_series = new QSplineSeries(this);
    QPen pen(Qt::red);
    pen.setWidth(2);
    m_series->setPen(pen);
    m_series->append(xpos, 30);

    addSeries(m_series);

    addAxis(m_axisX,Qt::AlignBottom);
    addAxis(m_axisY,Qt::AlignLeft);
    m_series->attachAxis(m_axisX);
    m_series->attachAxis(m_axisY);
    m_axisX->setTickCount(5);
    m_axisX->setRange(0, 60);
    m_axisY->setRange(0, 50);

    QFont f = m_axisX->labelsFont();
    f.setPointSize(8);
    m_axisX->setLabelsFont(f);
    m_axisY->setLabelsFont(f);

    setMargins(QMargins(0,0,0,0));

    setTitle("Temperature (°C)");
    legend()->hide();
}

void Chart::handleValueChanged(float temp, float pressure, float humidity)
{
    Q_UNUSED(pressure);
    Q_UNUSED(humidity);
    m_series->append(xpos, temp);
    xpos++;
    if (xpos >= 60)
      scroll(plotArea().width() / 60, 0);
}

The constructor simply sets up the QChart we inherit from: defining the axis, their range, the pen width and color, etc. On the X axis (time), we are going to show 60 measurements, and since our handleValueChanged slot is going to be called every second, it means our graph will show the last 60 seconds of temperature measurement. On the Y axis (temperature), we can show temperatures from 0°C to 50°C. Of course, this is all very hardcoded in this example, for simplicity.

The handleValueChanged slot appends the new temperature value to the graph, and then updates the area displayed by the graph so that always the last 60 seconds are visible.

Now, we need to integrate this to our existing Window class, so that we can display the chart, and switch between the numeric values and the chart. First, we need to do some changes in window.h, and below we'll show only the diff to make the differences very clear:

diff --git a/window.h b/window.h
index 3d63d38..05d1f39 100644
--- a/window.h
+++ b/window.h
@@ -3,8 +3,12 @@
 #define WINDOW_H
 
 #include <QWidget>
+#include <QtCharts/QChartView>
+
+QT_CHARTS_USE_NAMESPACE
 
 class Values;
+class Chart;
 
 class Window : public QWidget
 {
@@ -13,11 +17,17 @@ class Window : public QWidget
 public slots:
     void handleValueChanged(float temp, float pressure, float humidity);
 
+private slots:
+    void chartButtonClicked();
+    void valuesButtonClicked();
+
 public:
     Window();
 
 private:
     Values *values;
+    QChartView *chartView;
+    Chart *chart;
 };
 
 #endif

So, we're defining two private slots that will be used for the two buttons that allow to switch between the numeric values and the chart, and then we add two variables, one for the chart itself, and one for the QChartView (which basically renders the graph into a widget).

Then, in window.cpp, we do the following changes:

diff --git a/window.cpp b/window.cpp
index aba2862..d654964 100644
--- a/window.cpp
+++ b/window.cpp
@@ -3,28 +3,54 @@
 
 #include "window.h"
 #include "values.h"
+#include "chart.h"
 
 Window::Window()
 {
     values = new Values;
+    chart = new Chart;
     QVBoxLayout *layout = new QVBoxLayout;
     QHBoxLayout *buttons = new QHBoxLayout;
 
     QPushButton *values_button = new QPushButton("Values");
     QPushButton *chart_button = new QPushButton("Chart");
 
+    QObject::connect(chart_button, &QPushButton::clicked,
+                    this, &Window::chartButtonClicked);
+    QObject::connect(values_button, &QPushButton::clicked,
+                    this, &Window::valuesButtonClicked);
+
     buttons->addWidget(values_button);
     buttons->addWidget(chart_button);
 
+    chartView = new QChartView(chart);
+    chartView->setRenderHint(QPainter::Antialiasing);
+
     layout->addWidget(values);
+    layout->addWidget(chartView);
     layout->addLayout(buttons);
 
     setLayout(layout);
 
+    chartView->hide();
+
     setWindowTitle(tr("Sensors"));
 }
 
 void Window::handleValueChanged(float temp, float pressure, float humidity)
 {
     values->handleValueChanged(temp, pressure, humidity);
+    chart->handleValueChanged(temp, pressure, humidity);
+}
+
+void Window::chartButtonClicked()
+{
+    values->hide();
+    chartView->show();
+}
+
+void Window::valuesButtonClicked()
+{
+    values->show();
+    chartView->hide();
 }

So, in the constructor we are connecting the clicked signals of the two buttons to their respective slots. We create the Chart object, and then the QChartView to render the graph. We add the latter as an additional widget in the QVBoxLayout, and we hide it.

The existing handleValueChanged slot is modified to also update the Chart object with the new sensor values.

Finally, the new chartButtonClicked and valuesButtonClicked slots implement the logic that is executed when the buttons are pressed. We simply hide or show the appropriate widget to display either the numeric values or the chart. There is probably a nicer way to achieve this in Qt, but this was good enough for our example.

Now that the source code is in place, we of course need to adjust the build logic in qt-sensor-demo.pro:

--- a/qt-sensor-demo.pro
+++ b/qt-sensor-demo.pro
@@ -1,6 +1,6 @@
 # SPDX-License-Identifier: MIT
-QT += widgets
-SOURCES = main.cpp data-provider.cpp window.cpp values.cpp
-HEADERS = data-provider.h window.h values.h
+QT += widgets charts
+SOURCES = main.cpp data-provider.cpp window.cpp values.cpp chart.cpp
+HEADERS = data-provider.h window.h values.h chart.h
 INSTALLS += target
 target.path = /usr/bin

Besides the obvious addition of the chart.cpp and chart.h file, the other important addition is charts to the QT variable. This tells qmake that our application is using the Qt Charts, and that we therefore need to link against the appropriate libraries.

Building the application

At this point, if you try to build the application, it will fail because QtCharts has not been built as part of our Buildroot configuration. In order to address this, run Buildroot's make menuconfig, enable the BR2_PACKAGE_QT5CHARTS option (in Target packages -> Graphic libraries and applications -> Qt5 -> qt5charts).

Then, run the Buildroot build with make, and reflash the resulting SD card image.

Now, you can build again your application, either with Qt Creator if you've been using Qt Creator, or manually. If you build it manually, you'll have to run qmake again to regenerate the Makefile, and then build with make.

When you run the application on the target, the GUI will display the same numeric values as before, but now if you press the Chart button, it will show something like:

Qt5 application with chart

Adjusting the Buildroot package

We have for now been building this application manually, but as explained in our previous blog post, we really want Buildroot to be able to build our complete system, including our application. For this reason, we had created a qt-sensor-demo package, which gets our application source code, configures it with qmake, builds it and installs it.

However, with the new use of Qt Charts, our qt-sensor-demo package needs a few adjustements:

  • The Config.in file needs an additional select BR2_PACKAGE_QT5CHARTS, to make sure Qt Charts are enabled in the Buildroot configuration
  • The qt-sensor-demo.mk file needs an additional qt5charts in the QT_SENSOR_DEMO_DEPENDENCIES variable to make sure the qt5charts package gets built before qt-sensor-demo

With this in place, you can run:

make qt-sensor-demo-rebuild
make

And you have an SD card image that includes our application!

Starting the application automatically at boot time

The next and almost final step for this blog post is to get our application automatically started at boot time. We can simply add a small shell script on the target in /etc/init.d/: the default Buildroot configuration for the init system will execute all scripts named Ssomething in /etc/init.d/. We'll add a file named package/qt-sensor-demo/S99qt-sensor-demo with these contents:

#!/bin/sh

DAEMON="qt-sensor-demo"
DAEMON_ARGS="-platform linuxfb"
PIDFILE="/var/run/qt-sensor-demo.pid"

start() {
	printf 'Starting %s: ' "$DAEMON"
	start-stop-daemon -b -m -S -q -p "$PIDFILE" -x "/usr/bin/$DAEMON" -- $DAEMON_ARGS
	status=$?
	if [ "$status" -eq 0 ]; then
		echo "OK"
	else
		echo "FAIL"
	fi
	return "$status"
}

stop () {
	printf 'Stopping %s: ' "$DAEMON"
	start-stop-daemon -K -q -p "$PIDFILE"
	status=$?
	if [ "$status" -eq 0 ]; then
		rm -f "$PIDFILE"
		echo "OK"
	else
		echo "FAIL"
	fi
	return "$status"
}

restart () {
	stop
	sleep 1
	start
}

case "$1" in
        start|stop|restart)
		"$1";;
	reload)
		# Restart, since there is no true "reload" feature.
		restart;;
        *)
                echo "Usage: $0 {start|stop|restart|reload}"
                exit 1
esac

This is the canonical init script used in Buildroot to start system daemons and services, and is modeled after the one in package/busybox/S01syslogd. It uses the start-stop-daemon program to start our application in the background.

Then, to get this init script installed, we need to adjust package/qt-sensor-demo/qt-sensor-demo.mk with the following additional lines:

define QT_SENSOR_DEMO_INSTALL_INIT_SYSV
        $(INSTALL) -D -m 755 package/qt-sensor-demo/S99qt-sensor-demo \
                $(TARGET_DIR)/etc/init.d/S99qt-sensor-demo
endef

This ensures that the init script gets installed in /etc/init.d/S99qt-sensor-demo as part of the build process of our qt-sensor-demo package. Note that an init script works fine if you're using the Busybox init implementation or the sysvinit init implementation (we're using the default Buildroot setup here, which uses the Busybox init implementation). If you want to use systemd as an init implementation, then a different setup is necessary.

With this done, you simply need to reinstall the application and regenerate the SD card image

$ make qt-sensor-demo-reinstall
$ make

You can now test your SD card image on you board, and you should see the application being started automatically, with the following messages at boot time

Starting dropbear sshd: OK
Starting qt-sensor-demo: OK

Welcome to Buildroot

Avoid unnecessary logging on the display panel

In our current setup, the kernel messages are being sent to both the serial port and the framebuffer console, which means they appear on the display panel. This is not very pretty, and we would like the display to remain black until the application starts, while keeping the kernel messages on the serial port for debugging purposes. Also, we would like the framebuffer console text cursor to not be displayed, to really have a fully black screen. To achieve this we will add two arguments on the Linux kernel command line:

  • console=ttySTM0,115200, which will tell the Linux kernel to only use the serial port as the console, and not all registered consoles, which would include the framebuffer console. This option will make sure the kernel messages are not displayed on the screen.
  • vt.global_cursor_default=0, which will tell the Linux kernel to not display any cursor on the framebuffer console.

So, to add those options, we simply modify board/stmicroelectronics/stm32mp157-dk/overlay/boot/extlinux/extlinux.conf in Buildroot as follows:

label stm32mp15-buildroot
  kernel /boot/zImage
  devicetree /boot/stm32mp157c-dk2.dtb
  append root=/dev/mmcblk0p4 rootwait console=ttySTM0,115200 vt.global_cursor_default=0

Of course, rebuild the SD card image with make, reflash and test the result on your STM32MP1 platform.

Conclusion

In this blog post, we have seen how to write a real (but admittedly very simple) Qt application, how to make it read and display sensor data, and how to integrate this application so that it gets started at boot time.

You can find the Buildroot changes corresponding to this blog post in the 2019.02/stm32mp157-dk-blog-5 branch of our repository. The qt-sensor-demo application code can be found in the blog-5 branch of this application Git repository.

Stay tuned for our next blog post about factory flashing and OTA update!

Bootlin contributes Linux DRM driver for LogicBricks logiCVC-ML IP

LogicBricks is a vendor of numerous IP blocks, ranging from display controllers, audio controllers, 3D accelerators and many other specialized IP blocks. Most of these IP blocks are designed to work with the Xilinx Zynq 7000 system-on-chip, which includes an FPGA area. And indeed, because the Zynq 7000 does not have a display controller, one of Bootlin customers has selected the LogicBricks logiCVC-ML IP to provide display support for their Zynq 7000 design.

logiCVC-ML

LogiBricks provide one driver based on the framebuffer subsystem and another one based on the DRM subsystem, but none of these drivers are in the upstream Linux kernel. Bootlin engineer Paul Kocialkowski worked on a clean DRM driver for this IP block, and submitted the first version to the upstream Linux kernel. We already received some useful comments on the Device Tree binding for this IP block, which is pretty elaborate due to the number of aspects/features that can be tuned at IP synthesis time, and we will of course take into account those comments and send new iterations of the patch series until it gets merged.

In the e-mail containing the driver patch itself, Paul gives a summary of the IP features that are supported and tested, and those that re either untested or unsupported:

Introduces a driver for the LogiCVC display controller, a programmable
logic controller optimized for use in Xilinx Zynq-7000 SoCs and other
Xilinx FPGAs. The controller is mostly configured at logic synthesis
time so only a subset of configuration is left for the driver to
handle.

The following features are implemented and tested:
- LVDS 4-bit interface;
- RGB565 pixel formats;
- Multiple layers and hardware composition;
- Layer-wide alpha mode;

The following features are implemented but untested:
- Other RGB pixel formats;
- Layer framebuffer configuration for version 4;
- Lowest-layer used as background color;
- Per-pixel alpha mode.

The following features are not implemented:
- YUV pixel formats;
- DVI, LVDS 3-bit, ITU656 and camera link interfaces;
- External parallel input for layer;
- Color-keying;
- LUT-based alpha modes.

Additional implementation-specific notes:
- Panels are only enabled after the first page flip to avoid flashing a
  white screen.
- Depth used in context of the LogiCVC driver only counts color components
  to match the definition of the synthesis parameters.

Support is implemented for both version 3 and 4 of the controller.

With version 3, framebuffers are stored in a dedicated contiguous
memory area, with a base address hardcoded for each layer. This requires
using a dedicated CMA pool registered at the base address and tweaking a
few offset-related registers to try to use any buffer allocated from
the pool. This is done on a best-effort basis to have the hardware cope
with the DRM framebuffer allocation model and there is no guarantee
that each buffer allocated by GEM CMA can be used for any layer.
In particular, buffers allocated below the base address for a layer are
guaranteed not to be configurable for that layer. See the implementation of
logicvc_layer_buffer_find_setup for specifics.

Version 4 allows configuring each buffer address directly, which
guarantees that any buffer can be configured.

Improvements to Buildroot maintenance tooling

From mid-April to end of August, Victor Huesca, a student from the University of Toulouse joined Bootlin’s team for a 3.5 months internship. His internship was focused on the Buildroot project, and Victor’s mission was to improve various aspect of the tooling around Buildroot to help in the maintenance of this build system. In this blog post, we will present the different improvements and features implemented by Victor during his internship. This internship was funded by Bootlin, and entirely focused on contributing to the Buildroot project.

Notifications of new upstream versions of packages

Buildroot has over 2400 packages for a wide variety of software components, and it is a challenge to keep all of those packages updated with the latest releases from the upstream developers. Buildroot has a nice statistics page with all its packages, and in early 2019, your author added support for querying the release-monitoring.org service to find the latest upstream version of each package. This allowed our statistics page to show the current version in Buildroot and the latest version available upstream for all Builroot packages.

Victor improved this by implementing e-mail notifications to Buildroot developers about their package having new upstream releases available. Indeed, Buildroot has a DEVELOPERS file which associates the name and e-mail of Buildroot contributors/developers with the packages they take care of. So, what Victor did is:

  • Extend the pkg-stats script, which generates the statistics page, to not only generate a HTML output, but also a JSON output. A JSON output is obviously a lot more usable by other tools. Victor also improved the efficiency of this script in several ways, especially by parallelizing the requests made to release-monitoring.org.
  • Extend the daily-mail script, which until now was only sending autobuild results, to also send notifications about packages that are not up to date with their latest upstream version

The notifications are sent only once a week, both individually to the developers, and globally on the mailing list. They are grouped in a single e-mail with the existing autobuild results notifications, to minimize the amount of e-mails received by developers. You can see an example of such a notification in this e-mail, with a small excerpt below:

Packages having a newer version
===============================

             name              | found by |        link to release-monitoring.org        |   version    |   upstream   | orph?
-------------------------------+----------+----------------------------------------------+--------------+--------------+-------
                           4th |  DISTRO  | https://release-monitoring.org/project/20471 | 3.62.5       | 3625         |     
                        acpica |  DISTRO  | https://release-monitoring.org/project/00018 | 20190703     | 20190816     |     
                         acpid |  DISTRO  | https://release-monitoring.org/project/00019 | 2.0.30       | 2.0.32       | ORPH
                       acsccid |  DISTRO  | https://release-monitoring.org/project/15661 | 1.1.4        | 1.1.7        |     
            adwaita-icon-theme |  DISTRO  | https://release-monitoring.org/project/13117 | 3.22.0       | 3.33.92      |     
                       aespipe |  GUESS   | https://release-monitoring.org/project/21320 | 2.4d         | 2.4e         | ORPH
                 android-tools |  GUESS   | https://release-monitoring.org/project/13989 | 4.2.2+git... | 10.0.0_r2    |     
                      argparse |  GUESS   | https://release-monitoring.org/project/02100 | 0.7.0-1      | 1.0.10       |     
                         argus |  GUESS   | https://release-monitoring.org/project/00107 | 3.0.8        | 3.0.8.2      | ORPH
                     armadillo |  GUESS   | https://release-monitoring.org/project/07006 | 7.900.1      | 9.700.2      |     
                   at-spi2-atk |  GUESS   | https://release-monitoring.org/project/07840 | 2.26.2       | 2.33.92      |     
                  at-spi2-core |  GUESS   | https://release-monitoring.org/project/07841 | 2.28.0       | 2.33.92      |     
                         atkmm |  GUESS   | https://release-monitoring.org/project/07962 | 2.24.2       | 2.29.1       |     
                      automake |  DISTRO  | https://release-monitoring.org/project/00144 | 1.15.1       | 1.16.1       | ORPH
[...]

As part of this work, Victor also improved the matching of versions between the Buildroot package versions and the upstream versions. Indeed, for many packages, Buildroot used to use the full Git tag name as the version (for example v1.3), while release-monitoring.org removes any prefix and keeps only 1.3.

As of today, not all Buildroot packages match with a project known by release-monitoring.org, either because release-monitoring.org doesn’t know the project, or because the name is slightly different, but we are improving this progressively (the name mismatch can be handled by creating a mapping on release-monitoring.org, thanks to the concept of distribution they have).

The work of Victor has already proven to be very useful: a number of infrequent contributors suddenly started taking care of the packages they had contributed a long time ago and perhaps forgotten since then, which is very good.

Notifications of defconfig and runtime test failures

Buildroot provides a number of defconfig files, which are example Buildroot configuration for a wide range of hardware platforms (Raspberry Pi, BeagleBone, Qemu emulated machines, NXP or Microchip evaluation boards, and more). These defconfigs offers a very simple way for users to get a minimal Buildroot system up and running on those hardware platforms, making them a great starting point. Of course, to make them useful, they have to build properly, and we regularly build them using Gitlab CI to ensure they continue to build.

Buildroot also has runtime tests, which were initially introduced in the project by your author back in 2017. Those runtime tests are test cases that will each build a specific well-defined Buildroot configuration, boot it under Qemu, and verify that everything works properly. For example, the filesystem test cases will each make a Buildroot build with a specific filesystem image format selected, and boot the result under Qemu, to make sure that the filesystem image is correct and working. We also have a significant number of test cases for Perl or Python modules, which simply build the Perl or Python interpreter with a collection of modules, boot under Qemu, and verify that those modules can be loaded/imported. Just like the defconfigs, these runtime tests are already tested on a regular basis using Gitlab CI, to detect and fix any regression.

However, the results of those tests in Gitlab CI (and especially failures) were not notified to the Buildroot community in a meaningful way. This is where Victor filled in the gap, by adding the appropriate notifications.

He further extended the daily-mail script so that using the Gitlab CI API, the latest Gitlab CI pipelines for the Buildroot project are retrieved, the defconfig and runtime test failures are identified, and the appropriate Buildroot developers and contributors are notified. Indeed, just like packages are referenced in Buildroot’s DEVELOPERS file, the defconfigs and runtime tests are also referenced. The daily-mail script will notify individual developers about the defconfig and runtime tests they take care of, and it will also globally notify the mailing list about all defconfig and runtime test failures.

An example output, visible in this notification e-mail is:


Detail of defconfig failures
----------------------------

                        defconfig |                        link to the job                        | orph?
----------------------------------+---------------------------------------------------------------+------
                amarula_a64_relic |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126211  |      
               arcturus_ucls1012a |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126214  |      
                        bananapro |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126246  |      
                   beaglebone_qt5 |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126249  | ORPH 
        engicam_imx6qdl_icore_qt5 |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126255  |      
                 imx6-sabresd_qt5 |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126282  |      
                       imx6ulpico |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126286  |      
                        imx7dpico |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126288  |      
                    licheepi_zero |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126292  |      
               linksprite_pcduino |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126293  |      
                    orangepi_lite |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126321  |      
                   orangepi_lite2 |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126320  |      
                 orangepi_pc_plus |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126326  |      
                    orangepi_zero |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126331  |      
              orangepi_zero_plus2 |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126332  |      
                   pc_x86_64_bios |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126334  |      
                    pc_x86_64_efi |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126335  |      
               raspberrypi3_qt5we |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126382  | ORPH 
                            warp7 |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126413  |      
                        warpboard |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126414  | ORPH 


Detail of runtime-test failures
-------------------------------

             runtime-test |                        link to the job                        | orph?
--------------------------+---------------------------------------------------------------+------
...ystemSystemdRoIfupdown |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126471  | ORPH 
...ystemSystemdRoNetworkd |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126473  | ORPH 
...nitSystemSystemdRwFull |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126475  | ORPH 
...ystemSystemdRwIfupdown |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126476  | ORPH 
...ystemSystemdRwNetworkd |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126477  | ORPH 
             TestSyslogNg |  https://gitlab.com/buildroot.org/buildroot/-/jobs/289126581  | ORPH 

Overall, thanks to Victor’s work, a single e-mail now reports autobuilder failures, the need to update packages to a newer upstream versions, defconfig build failures and runtime tests failures. This is a really good improvement in the tooling of the Buildroot community!

Buildroot autobuilder search capabilities

Buildroot provides over 2400 packages, and many of them have configurable features and optional dependencies. This creates a massive amount of possible configuration combinations, making it impossible to test all of them. To make sure as many Buildroot configurations build properly, the project has been running for many years the Buildroot autobuilders. A number of build machines build random Buildroot configurations 24/7, and report their results to autobuild.buildroot.org. This helps tremendously the Buildroot developers and maintainers to detect the problematic packages and configurations.

For a long time, the autobuild.buildroot.org allowed to filter build results by architecture, C library, failing package, and a few other criterias. Such filtering is very often useful to understand when a package started failing to build, and in which situations it fails to build.

autobuild.buildroot.org was also collecting in a database all the configuration symbols (the BR2_something symbols) for every Buildroot configuration that was built. However, the size of this database made any query excessively long, so we were not able to make use of it so far. This was annoying because it would sometimes be useful to ask could you tell me which configuration had BR2_PACKAGE_STRACE=y and built successfully ?.

That’s where Victor jumped in:

  • He improved the database by adding the appropriate indexes and found a reasonably efficient way to query the database when configuration symbols are involved
  • He added filtering per configuration symbol, which can be done using GET arguments on the main autobuild.buildroot.org page: http://autobuild.buildroot.org/?status=OK&symbols[BR2_PACKAGE_STRACE]=y will show the builds that had BR2_PACKAGE_STRACE=y and that ended successfully. Multiple symbols[name]=value arguments can be passed.
  • Since writing such queries by hand was a bit cumbersome, Victor also added a new search page.
Autobuild search page
Autobuild search page

This work will be very useful in the future to analyze build failures and understand better in which situations they are happening.

Conclusion

Victor’s internship has been very productive in improving the tooling used by the Buildroot community to maintain the project. All the work done by Victor has been merged, is in production, and is already showing some useful results.

Bootlin at the Embedded Linux Conference Europe 2019

This year, Bootlin missed the Embedded Linux Conference North America which took place late August in San Diego, US. It was the first time in many years that Bootlin was completely absent from an Embedded Linux Conference.

But the coming Embedded Linux Conference Europe is going to be different in that respect: Bootlin will once again have a strong presence at this event, which in 2019 takes in Bootlin’s home country, France, from October 28 to October 30. And this year, ELCE is not only in France, but more precisely in Lyon, the city where one of the 3 Bootlin offices is located, so for some of our engineers it will be a very local conference!

Embedded Linux Conference Europe 2019

Of Bootlin staff, Michael Opdenacker, Alexandre Belloni, Grégory Clement, Kamel Bouhara, Miquèl Raynal, Maxime Chevallier, Paul Kocialkowski and Thomas Petazzoni will participate to the event. The schedule of the event, which also includes talks from the Open Source Summit and a number of co-located events, shows a nice selection of interesting talks.

As usual, we don’t limit our participation to just attending: we also give talks and tutorials. This year, the following proposals we made have been accepted:

In addition to being present at the Embedded Linux Conference Europe, Bootlin will also be present:

  • at the Buildroot Developers Meeting, which will take place on the 3 days before the conference, through to the participation of Buildroot co-maintainer Thomas Petazzoni
  • at the Linux media summit, which will take place in parallel to the Embedded Linux Conference Europe. Bootlin engineer Paul Kocialkowski will be part of the attendees.

Bootlin at the X.Org Developers Conference 2019

Every year, the X.Org community organizes the X.Org Developers Conference, the main conference to discuss graphics support in Linux. Despite the name, the conference is no longer restricted to X.Org topics, but also covers Wayland, Mesa3D and many other topics.

XDC 2019

The 2019 edition will take place on October 2-4 in Montréal, Canada, and the schedule of this event is already available.

Bootlin engineer Paul Kocialkowski will participate to this conference. Paul is Bootlin’s display and graphics expert, he is one of the developer of the Allwinner VPU support in Linux and has made several contributions to the Allwinner DRM driver, as well as worked on the RaspberryPi graphics controller automated testing. Participating to this conference allows us to stay up-to-date with the latest developments in the Linux graphics community.

If you’re attending the conference, do not hesitate to get in touch with Paul!