Everything in a PC, laptop, or server is represented as binary digits (a.k.a. bits, where each bit can only be 1 or 0). There are no characters like we use for writing or numbers as we write them anywhere in a computer’s memory or secondary storage such as disk drives. For general purposes, the unit of measure for groups of binary bits is the byte — eight bits. Bytes are an agreed-upon measure that helped standardize computer memory, storage, and how computers handled data.

There are various terms in use to specify the capacity of a disk drive (either magnetic or electronic). The same measures are applied to a computers random access memory (RAM) and other memory devices that inhabit your computer. So now let’s see how the numbers are made up.

Suffixes are used with the number that specifies the capacity of the device. The suffixes designate a multiplier that is to be applied to the number that preceded the suffix. Commonly used suffixes are:

• Kilo = 10³ = 1,000 (one thousand)
• Mega = 10⁶ = 1,000,000 (one million)
• Giga = 10⁹ = 1000,000,000 (one billion)
• Tera = 10¹² = 1,000,000,000,000 (one trillion)

As an example 500 GB (gigabytes) is 500,000,000,000 bytes.

The units that memory and storage are specified in  advertisements, on boxes in the store, and so on are in the decimal system as shown above. However since computers only use binary bits, the actual capacity of these devices is different than the advertised capacity.

You saw that the decimal numbers above were shown with their equivalent powers of ten. In the binary system numbers can be represented as powers of two. The table below shows how bits are used to represent powers of two in an 8 bit Byte. At the bottom of the table there is an example of how the decimal number 109 can be represented as a binary number that can be held in a single byte of 8 bits (01101101).

The example bit values comprise the binary number 01101101. To get the equivalent decimal value just add the decimal values from the table where the bit is set to 1. That is 64 + 32 + 8 + 4 + 1 = 109.

By the time you get out to 2³⁰ you have decimal 1,073,741,824 with just 31 bits (don’t forget the 2⁰) You’ve got a large enough number to start specifying memory and storage sizes.

Now comes what you have been waiting for. The table below lists common designations as they are used for labeling decimal and binary values.

Note that all of the quantities of bytes in the table above are expressed as decimal numbers. They are not shown as binary numbers because those numbers would be more than 30 characters long.

Most users and programmers need not be concerned with the small differences between the binary and decimal storage size numbers. If you’re developing software or hardware that deals with data at the binary level you may need the binary numbers.

As for what this means to your PC: Your PC will make use of the full capacity of your storage and memory devices. If you want to see the capacity of your disk drives, thumb drives, etc, the Disks utility in Fedora will show you the actual capacity of the storage device in number of bytes as a decimal number.

There are also command line tools that can provide you with more flexibility in seeing how your storage bytes are being used. Two such command line tools are du (for files and directories) and df (for file systems). You can read about these by typing man du or man df at the command line in a terminal window.

Photo by Franck V. on Unsplash.

The Cockpit series continues to focus on some of the tools users and administrators can use to perform everyday tasks within the web user-interface. So far we’ve covered introducing the user-interface, storage and network management, and user accounts. Hence, this article will highlight how Cockpit handles software and services.

The menu options for Applications and Software Updates are available through Cockpit’s PackageKit feature. To install it from the command-line, run:

 sudo dnf install cockpit-packagekit

For Fedora Silverblue, Fedora CoreOS, and other ostree-based operating systems, install the cockpit-ostree package and reboot the system:

sudo rpm-ostree install cockpit-ostree; sudo systemctl reboot

Software updates

On the main screen, Cockpit notifies the user whether the system is updated, or if any updates are available. Click the Updates Available link on the main screen, or Software Updates in the menu options, to open the updates page.

RPM-based updates

The top of the screen displays general information such as the number of updates and the number of security-only updates. It also shows when the system was last checked for updates, and a button to perform the check. Likewise, this button is equivalent to the command sudo dnf check-update.

Below is the Available Updates section, which lists the packages requiring updates. Furthermore, each package displays the name, version, and best of all, the severity of the update. Clicking a package in the list provides additional information such as the CVE, the Bugzilla ID, and a brief description of the update. For details about the CVE and related bugs, click their respective links.

Also, one of the best features about Software Updates is the option to only install security updates. Distinguishing which updates to perform makes it simple for those who may not need, or want, the latest and greatest software installed. Of course, one can always use Red Hat Enterprise Linux or CentOS for machines requiring long-term support.

The example below demonstrates how Cockpit applies RPM-based updates.

OSTree-based updates

The popular article What is Silverblue states:

OSTree is used by rpm-ostree, a hybrid package/image based system… It atomically replicates a base OS and allows the user to “layer” the traditional RPM on top of the base OS if needed.

Because of this setup, Cockpit uses a snapshot-like layout for these operating systems. As seen in the demo below, the top of the screen displays the repository (fedora), the base OS image, and a button to Check for Updates.

Clicking the repository name (fedora in the demo below) opens the Change Repository screen. From here one can Add New Repository, or click the pencil icon to edit an existing repository. Editing provides the option to delete the repository, or Add Another Key. To add a new repository, enter the name and URL. Also, select whether or not to Use trusted GPG key.

There are three categories that provide details of its respective image: Tree, Packages, and Signature. Tree displays basic information such as the operating system, version of the image, how long ago it was released, and the origin of the image. Packages displays a list of installed packages within that image. Signature verifies the integrity of the image such as the author, date, RSA key ID, and status.

The current, or running, image displays a green check-mark beside it. If something happens, or an update causes an issue, click the Roll Back and Reboot button. This restores the system to a previous image.

Applications

The Applications screen displays a list of add-ons available for Cockpit. This makes it easy to find and install the plugins required by the user. At the time of this article, some of the options include the 389 Directory Service, Fleet Commander, and Subscription Manager. The demo below shows a complete list of available Cockpit add-ons.

Also, each item displays the name, a brief description, and a button to install, or remove, the add-on. Furthermore, clicking the item displays more information (if available). To refresh the list, click the icon at the top-right corner.

Subscription Management

Subscription managers allow admins to attach subscriptions to the machine. Even more, subscriptions give admins control over user access to content and packages. One example of this is the famous Red Hat subscription model. This feature works in relation to the subscription-manager command

The Subscriptions add-on can be installed via Cockpit’s Applications menu option. It can also be installed from the command-line with:

sudo dnf install cockpit-subscriptions

To begin, click Subscriptions in the main menu. If the machine is currently unregistered, it opens the Register System screen. Next, select the URL. You can choose Default, which uses Red Hat’s subscription server, or enter a Custom URL. Enter the Login, Password, Activation Key, and Organization ID. Finally, to complete the process, click the Register button.

The main page for Subscriptions show if the machine is registered, the System Purpose, and a list of installed products.

Services

To start, click the Services menu option. Because Cockpit uses systemd, we get the options to view System Services, Targets, Sockets, Timers, and Paths. Cockpit also provides an intuitive interface to help users search and find the service they want to configure. Services can also be filtered by it’s state: All, Enabled, Disabled, or Static. Below this is the list of services. Each row displays the service name, description, state, and automatic startup behavior.

For example, let’s take bluetooth.service. Typing bluetooth in the search bar automatically displays the service. Now, select the service to view the details of that service. The page displays the status and path of the service file. It also displays information in the service file such as the requirements and conflicts. Finally, at the bottom of the page, are the logs pertaining to that service.

Also, users can quickly start and stop the service by toggling the switch beside the service name. The three-dots to the right of that switch expands those options to Enable, Disable, Mask/Unmask the service

To learn more about systemd, check out the series in the Fedora Magazine starting with What is an init system?

In the next article we’ll explore the security features available in Cockpit.

This article shows you how to set up some powerful tools in your command line interpreter (CLI) shell on Fedora. If you use bash (the default) or zsh, Fedora lets you easily setup these tools.

Requirements

Some installed packages are required. On Workstation, run the following command:

sudo dnf install git wget curl ruby ruby-devel zsh util-linux-user redhat-rpm-config gcc gcc-c++ make

On Silverblue run:

sudo rpm-ostree install git wget curl ruby ruby-devel zsh util-linux-user redhat-rpm-config gcc gcc-c++ make

Note: On Silverblue you need to restart before proceeding.

Fonts

You can give your terminal a new look by installing new fonts. Why not fonts that display characters and icons together?

Nerd-Fonts

Open a new terminal and type the following commands:

git clone --depth=1 https://github.com/ryanoasis/nerd-fonts ~/.nerd-fonts
cd .nerd-fonts 
sudo ./install.sh

Awesome-Fonts

On Workstation, install using the following command:

sudo dnf install fontawesome-fonts

On Silverblue, type:

sudo rpm-ostree install fontawesome-fonts

Powerline

Powerline is a statusline plugin for vim, and provides statuslines and prompts for several other applications, including bash, zsh, tmus, i3, Awesome, IPython and Qtile. You can find more information about powerline on the official documentation site.

Installation

To install powerline utility on Fedora Workstation, open a new terminal and run:

sudo dnf install powerline vim-powerline tmux-powerline powerline-fonts

On Silverblue, the command changes to:

sudo rpm-ostree install powerline vim-powerline tmux-powerline powerline-fonts

Note: On Silverblue, before proceeding you need restart.

Activating powerline

To make the powerline active by default, place the code below at the end of your ~/.bashrc file

if [ -f `which powerline-daemon` ]; then
  powerline-daemon -q
  POWERLINE_BASH_CONTINUATION=1
  POWERLINE_BASH_SELECT=1
  . /usr/share/powerline/bash/powerline.sh
fi

Finally, close the terminal and open a new one. It will look like this:

Oh-My-Zsh

Oh-My-Zsh is a framework for managing your Zsh configuration. It comes bundled with helpful functions, plugins, and themes. To learn how set Zsh as your default shell this article.

Installation

Type this in the terminal:

sh -c "$(curl -fsSL https://raw.github.com/robbyrussell/oh-my-zsh/master/tools/install.sh)"

Alternatively, you can type this:

sh -c "$(wget https://raw.github.com/robbyrussell/oh-my-zsh/master/tools/install.sh -O -)"

At the end, you see the terminal like this:

Congratulations, Oh-my-zsh is installed.

Themes

Once installed, you can select your theme. I prefer to use the Powerlevel10k. One advantage is that it is 100 times faster than powerlevel9k theme. To install run this line:

git clone https://github.com/romkatv/powerlevel10k.git ~/.oh-my-zsh/themes/powerlevel10k

And set ZSH_THEME in your ~/.zshrc file

ZSH_THEME=powerlevel10k/powerlevel10k

Close the terminal. When you open the terminal again, the Powerlevel10k configuration wizard will ask you a few questions to configure your prompt properly.

After finish Powerline10k configuration wizard, your prompt will look like this:

If you don’t like it. You can run the powerline10k wizard any time with the command p10k configure.

Enable plug-ins

Plug-ins are stored in .oh-my-zsh/plugins folder. You can visit this site for more information. To activate a plug-in, you need edit your ~/.zshrc file. Install plug-ins means that you are going create a series of aliases or shortcuts that execute a specific function.

For example, to enable the firewalld and git plugins, first edit ~/.zshrc:

plugins=(firewalld git)

Note: use a blank space to separate the plug-ins names list.

Then reload the configuration

source ~/.zshrc 

To see the created aliases, use the command:

alias | grep firewall

Additional configuration

I suggest the install syntax-highlighting and syntax-autosuggestions plug-ins.

git clone https://github.com/zsh-users/zsh-syntax-highlighting.git ${ZSH_CUSTOM:-~/.oh-my-zsh/custom}/plugins/zsh-syntax-highlighting
git clone https://github.com/zsh-users/zsh-autosuggestions ${ZSH_CUSTOM:-~/.oh-my-zsh/custom}/plugins/zsh-autosuggestions

Add them to your plug-ins list in your file ~/.zshrc

plugins=( [plugins...] zsh-syntax-highlighting zsh-autosuggestions)

Reload the configuration

source ~/.zshrc 

See the results:

Colored folders and icons

Colorls is a Ruby gem that beautifies the terminal’s ls command, with colors and font-awesome icons. You can visit the official site for more information.

Because it’s a ruby gem, just follow this simple step:

sudo gem install colorls

To keep up to date, just do:

sudo gem update colorls

To prevent type colorls everytime you can make aliases in your ~/.bashrc or ~/.zshrc.

alias ll='colorls -lA --sd --gs --group-directories-first'
alias ls='colorls --group-directories-first'

Also, you can enable tab completion for colorls flags, just entering following line at end of your shell configuration:

source $(dirname $(gem which colorls))/tab_complete.sh

Reload it and see what it happens:

If you ever attach to a WiFi system outside your home or office, you often see a portal page. This page may ask you to accept terms of service or some other agreement to get access. But what happens when you can’t connect through this kind of portal? This article shows you how to use NetworkManager on Fedora to deal with some failure cases so you can still access the internet.

How captive portals work

Captive portals are web pages offered when a new device is connected to a network. When the user first accesses the Internet, the portal captures all web page requests and redirects them to a single portal page.

The page then asks the user to take some action, typically agreeing to a usage policy. Once the user agrees, they may authenticate to a RADIUS or other type of authentication system. In simple terms, the captive portal registers and authorizes a device based on the device’s MAC address and end user acceptance of terms. (The MAC address is a hardware-based value attached to any network interface, like a WiFi chip or card.)

Sometimes a device doesn’t load the captive portal to authenticate and authorize the device to use the location’s WiFi access. Examples of this situation include mobile devices and gaming consoles (Switch, Playstation, etc.). They usually won’t launch a captive portal page when connecting to the Internet. You may see this situation when connecting to hotel or public WiFi access points.

You can use NetworkManager on Fedora to resolve these issues, though. Fedora will let you temporarily clone the connecting device’s MAC address and authenticate to the captive portal on the device’s behalf. You’ll need the MAC address of the device you want to connect. Typically this is printed somewhere on the device and labeled. It’s a six-byte hexadecimal value, so it might look like 4A:1A:4C:B0:38:1F. You can also usually find it through the device’s built-in menus.

Cloning with NetworkManager

First, open nm-connection-editor, or open the WiFI settings via the Settings applet. You can then use NetworkManager to clone as follows:

• For Ethernet – Select the connected Ethernet connection. Then select the Ethernet tab. Note or copy the current MAC address. Enter the MAC address of the console or other device in the Cloned MAC address field.
• For WiFi – Select the WiFi profile name. Then select the WiFi tab. Note or copy the current MAC address. Enter the MAC address of the console or other device in the Cloned MAC address field.

Bringing up the desired device

Once the Fedora system connects with the Ethernet or WiFi profile, the cloned MAC address is used to request an IP address, and the captive portal loads. Enter the credentials needed and/or select the user agreement. The MAC address will then get authorized.

Now, disconnect the WiFi or Ethernet profile, and change the Fedora system’s MAC address back to its original value. Then boot up the console or other device. The device should now be able to access the Internet, because its network interface has been authorized via your Fedora system.

This isn’t all that NetworkManager can do, though. For instance, check out this article on randomizing your system’s hardware address for better privacy.

Fedora 31 Workstation comes with a Firefox backend moved from X11 to Wayland by default. That’s just another step in the ongoing effort of moving to Wayland. This affects GNOME on Wayland only. This article helps you understand some changes and extra steps you may wish to take depending on your preferences.

There is a firefox-wayland package available to activate the Wayland backend on KDE and Sway desktop environments.

The Wayland architecture is completely different than X11. The team merged various aspects of Firefox internals to the new protocol where possible. However, some X11 features are missing completely. For such cases you can install and run firefox-x11 package as a fallback.

If you want to run the Flash plugin, you must install the firefox-x11 package, since Flash requires X11 and GTK 2. Wayland also has a slightly different drag and drop behavior and strict popup window hierarchy.

Generally, if you think Firefox is not behaving like you want, try the firefox-x11 package. In this case, ideally you should report the misbehavior in Bugzilla.

The Wayland architecture comes with many benefits, and overcomes many limitations of X11. For instance, it can deliver smoother rendering and better HiDPI and screen scale support. You can also enable EGL hardware acceleration on Intel and AMD graphics cards. This decreases your power consumption and also gives you partially accelerated video playback. To enable it, navigate to about:config, and search for layers.acceleration.force-enabled. Set this option to true and restart Firefox.

Brave users may wish to try the Firefox next-generation renderer, called WebRender, written in Rust. To do that, search for gfx.webrender.enabled and gfx.webrender.all in about:config. Set them to true, then cross your fingers and restart Firefox.

But don’t worry — even if Firefox crashes at start after these experiments, you can launch it in safe mode to reset these options. Start Firefox from a terminal using the following command:

$ firefox -safe-mode