https://www.maketecheasier.com/run-python-script-using-docker

How to Run a Python Script Using Docker

Table of Contents

• Why Use Docker for Python Scripts
• Write the Python Script
• Create the Dockerfile
• Build the Docker Image
• Create a Sample Folder with Files
• Run the Script Inside Docker

Running Python scripts is one of the most common tasks in automation. However, managing dependencies across different systems can be challenging. That’s where Docker comes in. Docker lets you package your Python script along with all its required dependencies into a container, ensuring it runs the same way on any machine. In this step-by-step guide, we’ll walk through the process of creating a real-life Python script and running it inside a Docker container.

Why Use Docker for Python Scripts

When you’re working with Python scripts, things can get messy/complex very fast. Different projects need different libraries, and what runs on your machine might break on someone else’s. Docker solves that by packaging your script and its environment together. So instead of saying “It works on my machine”, you can be sure it works the same everywhere.

It also keeps your system clean. You don’t have to install every Python package globally or worry about version conflicts. Everything stays inside the container.

If you’re deploying or handing your script off to someone else, Docker makes that easy, too. No setup instructions, no “install this and that”. Just one command, and it runs.

Write the Python Script

Let’s create a project directory to keep your Python script and Dockerfile. Once created, navigate into this directory using the cd command:

mkdir docker_file_organizer
cd docker_file_organizer

Create a script named “organize_files.py” to scan a directory and group files into folders based on their file extensions:

nano organize_files.py

Paste the following code into the “organize_file.py” file. Here, we use two pre-built Python modules, named os and shutil, to handle files and create directories dynamically:

import os
import shutil

SOURCE_DIR = "/files"

def organize_by_extension(directory):
    try:
        for fname in os.listdir(directory):
            path = os.path.join(directory, fname)
            if os.path.isfile(path):
                ext = fname.split('.')[-1].lower() if '.' in fname else 'no_extension'
                dest_dir = os.path.join(directory, ext)
                os.makedirs(dest_dir, exist_ok=True)
                shutil.move(path, os.path.join(dest_dir, fname))
                print(f"Moved: {fname} → {ext}/")
    except Exception as e:
        print(f"Error organizing files: {e}")

if __name__ == "__main__":
    organize_by_extension(SOURCE_DIR)

In this script, we organize files in a given directory based on their extensions. We use the os module to list the files, check if each item is a file, extract its extension, and create folders named after those extensions (if they don’t already exist). Then, we use the shutil module to move each file into its corresponding folder. For each move, we print a message showing the file’s new location.

Create the Dockerfile

Now, create a Dockerfile to define the environment in which your script will run:

FROM python:latest
LABEL maintainer="you@example.com"
WORKDIR /usr/src/app
COPY organize_files.py .
CMD ["python", "./organize_files.py"]

We use this Dockerfile to create a container with Python, add our script to it, and make sure the script runs automatically when the container starts:

Build the Docker Image

Before you can build the Docker image, you need to install Docker first. After that, run the following command to package everything into a Docker image:

sudo docker build -t file-organizer .

It reads our Dockerfile and puts together the Python setup and our script so they’re ready to run in a single container image:

Create a Sample Folder with Files

To see our script in action, we create a test folder named “sample_files” with a few files of different types. We created these files just to make the folder a bit messy and see how our Python script handles it:

mkdir ~/sample_files
touch ~/sample_files/test.txt
touch ~/sample_files/image.jpg
touch ~/sample_files/data.csv

Run the Script Inside Docker

Finally, we run our Docker container and mount the sample folder into it. The -v flag mounts your local “~/sample_files” directory to the “/files” directory in the container, which allows the Python script to read and organize files on your host machine:

docker run --rm -v ~/sample_files:/files file-organizer

Here, we use the --rm option to remove the container automatically after it finishes running, which saves disk space:

In the end, we use the tree command to check if the files have been sorted into folders based on their extensions:

tree sample_files

Note: The tree command isn’t pre-installed on most systems. You can easily install it using a package manager like apt on Ubuntu, brew on macOS, and so on.

Final Thoughts

With your Python script running inside Docker, you’re all set to take full advantage of a clean, portable, and consistent development setup. You can easily reuse this containerized workflow for other automation tasks, share your script without worrying about dependencies, and keep your system clutter-free. As a next step, consider exploring how to build multi-script Docker images, schedule containers with cron jobs, or integrate your scripts with other tools like Git, Jenkins, or even cloud platforms to streamline your automation and deployment process. 

https://www.tecmint.com/logkeys-monitor-keyboard-keystroke-linux

LogKeys: Monitor Keyboard Keystrokes in Linux

Keylogging, short for “keystroke logging” is the process of recording the keys struck on a keyboard, usually without the user’s knowledge.

Keyloggers can be implemented via hardware or software:

• Hardware keyloggers intercept data at the physical level (e.g., between the keyboard and computer).
• Software keyloggers, like LogKeys, capture keystrokes through the operating system.

This article explains how to use a popular open-source Linux keylogger called LogKeys for educational or testing purposes only. Unauthorized use of keyloggers to monitor someone else’s activity is unethical and illegal.

What is LogKeys?

LogKeys is an open-source keylogger for Linux that captures and logs keyboard input, including characters, function keys, and special keys. It is designed to work reliably across a wide range of Linux systems without crashing the X server.

LogKeys also correctly handles modifier keys like Alt and Shift, and is compatible with both USB and serial keyboards.

While there are numerous keylogger tools available for Windows, Linux has fewer well-supported options. Although LogKeys has not been actively maintained since 2019, it remains one of the more stable and functional keyloggers available for Linux as of today.

Installation of Logkeys in Linux

If you’ve previously installed Linux packages from a tarball (source), you should find installing the LogKeys package straightforward.

However, if you’ve never built a package from source before, you’ll need to install some required development tools first, such as C++ compilers and GCC libraries, before proceeding.

Installing Prerequisites

Before building LogKeys from source, ensure your system has the required development tools and libraries installed:

On Debian/Ubuntu:

sudo apt update
sudo apt install build-essential autotools-dev autoconf kbd

On Fedora/CentOS/RHEL:

sudo dnf install automake make gcc-c++ kbd

On openSUSE:

sudo zypper install automake gcc-c++ kbd

On Arch Linux:

sudo pacman -S base-devel kbd

Installing LogKeys from Source

First, download the latest LogKeys source package using the wget command, then, extract the ZIP archive and navigate into the extracted directory:

wget https://github.com/kernc/logkeys/archive/master.zip
unzip master.zip  
cd logkeys-master/

or clone the repository using Git, as shown below:

git clone https://github.com/kernc/logkeys.git
cd logkeys

Next, run the following commands to build and install LogKeys:

./autogen.sh         # Generate build configuration scripts
cd build                  # Switch to build directory
../configure              # Configure the build
make                      # Compile the source code
sudo make install         # Install binaries and man pages

If you encounter issues related to keyboard layout or character encoding, regenerate your locale settings:

sudo locale-gen

Usage of LogKeys in Linux

Once LogKeys is installed, you can begin using it to monitor and log keyboard input using the following commands.

Start Keylogging

This command starts the keylogging process, which must be run with superuser (root) privileges because it needs access to low-level input devices. Once started, LogKeys begins recording all keystrokes and saves them to the default log file: /var/log/logkeys.log.

Note: You won’t see any output in the terminal; logging runs silently in the background.

sudo logkeys --start

Stop Keylogging

This command terminates the keylogging process that was started earlier, which is important to stop LogKeys when you’re done, both to conserve system resources and to ensure the log file is safely closed.

sudo logkeys --kill

Get Help / View Available Options

The follwing command will displays all available command-line options and flags you can use with LogKeys.

logkeys --help

Useful options include:

• --start : Start the logger
• --kill : Stop the logger
• --output <file> : Specify a custom log output file
• --no-func-keys : Don’t log function keys (F1-F12)
• --no-control-keys : Skip control characters (e.g., Ctrl+C, Backspace)

View the Logged Keystrokes

The cat command displays the contents of the default log file where LogKeys saves keystrokes.

sudo cat /var/log/logkeys.log

You can also open it with a text editor like nano or less:

sudo nano /var/log/logkeys.log
or
sudo less /var/log/logkeys.log

Uninstall LogKeys in Linux

To remove LogKeys from your system and clean up the installed binaries, manuals, and scripts, use the following commands:

cd build
sudo make uninstall

This will remove all files that were installed with make install, including the logkeys binary and man pages.

Conclusion

LogKeys is a powerful keylogger for Linux that enables users to monitor keystrokes in a variety of environments. Its compatibility with modern systems and ease of installation make it a valuable tool for security auditing, parental control testing, and educational research.

However, it’s crucial to emphasize that keylogging should only be used in ethical, lawful contexts—such as with explicit user consent or for personal system monitoring. Misuse can lead to serious legal consequences. Use responsibly and stay informed.

https://www.tecmint.com/create-new-service-units-in-systemd

How to Use Systemd to Run Bash Scripts at Boot in Linux

A few days ago, I came across a CentOS 8 32-bit distro and decided to test it on an old 32-bit machine. After booting up, I realized there was a bug causing the network connection to drop. Every time I rebooted, I had to manually bring the network back up, which led me to wonder: How can I automate this process with a script that runs every time the system boots?

The solution is straightforward, and today, I’ll show you how to do this using systemd service units, but before we jump into that, let’s first take a quick look at what a service unit is and how it works.

In this article, we’ll cover the basics of systemd service units, their relationship with “targets,” and how to set up a service unit to run a script at boot. I’ll keep things simple, focusing on the practical steps, so you’ll have everything you need to know to tackle this on your own.

What is a Systemd Service Unit?

In simple terms, a service unit in systemd is a configuration file that defines how a service should behave on your system. It could be something like a network service, a program, or even a script that needs to run when your computer boots or at a specific point during the boot process.

These service units are grouped into targets, which can be seen as milestones or stages in the boot process. For example, when your system reaches the multi-user target (runlevel 3), certain services will be started. You can think of these targets as “collections” of services that work together at various stages of the boot sequence.

If you’d like to see the services running in a particular target (for example, graphical.target), you can use the systemctl command:

systemctl --type=service

This will show you all active services in your current target. Some services run continuously, while others start up once and then exit.

List All Active Services

Checking the Status of a Service

If you’re curious about a particular service, you can use systemctl status to see whether it’s active or inactive:

systemctl status firewalld.service

This command checks the status of the firewalld service. You’ll notice that it’s active, meaning it’s running, and enabled, which means it will start automatically on the next boot.

You can also stop a service temporarily (until the next boot) using:

systemctl stop firewalld.service
systemctl status firewalld.service

This will stop the firewalld service for this session, but won’t prevent it from starting up next time.

Check Status of Service

Enabling and Disabling Services

To ensure a service starts automatically on boot, you need to enable it, which will create a symbolic link in the appropriate target’s wants folder:

systemctl enable firewalld.service

To disable it, you would simply run:

systemctl disable firewalld.service

Enabling and Disabling Systemd Services

Creating a Custom Service Unit

To set up a service that runs a script at boot, we’ll create a new service unit under the /etc/systemd/system directory, here you’ll see existing service unit files and folders for different targets.

cd /etc/systemd/system
ls -l

Existing Service Unit Files

Let’s create our own service unit called connection.service using Vim or your preferred text editor to create it:

vim connection.service
Or
vi connection.service

Add the following content to the file.

[Unit]
Description=Bring up network connection
After=network.target

[Service]
ExecStart=/root/scripts/conup.sh

[Install]
WantedBy=multi-user.target

Explanation:

• [Unit]: The unit’s metadata. We’ve given it a description and told it to run after network.target, meaning it will only execute after the network has been initialized.
• [Service]: This section defines the command to execute when the service starts. In this case, it runs the script conup.sh.
• [Install]: This section tells systemd that the service should be loaded at the multi-user target, which is the standard runlevel for most systems.

Now, enable the service so it will start automatically on the next boot:

systemctl enable connection.service

You can confirm that it has been enabled by checking the multi-user.target.wants directory:

ls -l multi-user.target.wants/

The symbolic link to connection.service should now be present. However, we still need to create the script that this service will run.

Verify Service Unit File

Creating the Script

Let’s now create the conup.sh script that will bring the network connection up.

cd /root
mkdir scripts
cd scripts
vi conup.sh

Add the following line to bring the network up, here the script uses the nmcli command to bring the network connection on the enp0s3 interface up.

#!/bin/bash
nmcli connection up enp0s3

Don’t forget to make the script executable.

chmod +x conup.sh

At this point, the service is ready to go.

SELinux Contexts (For RHEL/CentOS Users)

If you’re using a RHEL-based system (like CentOS or Rocky Linux), don’t forget about SELinux, which can block scripts from running if the correct security context isn’t applied.

To temporarily set the context so the system treats the script as a regular executable, use:

chcon -t bin_t /root/scripts/conup.sh

However, this change won’t survive a reboot or file relabeling.

To make it permanent, use:

semanage fcontext -a -t bin_t "/root/scripts/conup.sh"
restorecon -v /root/scripts/conup.sh

This step ensures the script continues to run properly even after reboots or SELinux policy reloads.

Testing the Service

To test it without rebooting, you can start it manually.

systemctl start connection.service

If everything is set up correctly, the service will execute the script, and your network connection should be restored.

Alternatively, if you wrote a simpler script like touch /tmp/testbootfile, you can check if the file was created in /tmp to confirm the service is running as expected.

Conclusion

By now, you should have a good understanding of systemd service units and how to create and manage them on your system. You’ve also automated a common task – bringing up the network connection on boot using a simple service unit.

Hopefully, this guide helps you get more comfortable with managing services, targets, and scripts in systemd, making your system more automated and efficient.