Fedora aims to provide a kernel with as many configuration options enabled as possible. Sometimes users may want to change those options for testing or for a feature Fedora doesn’t support. This is a brief guide to how kernel configurations are generated and how to best make changes for a custom kernel.

Finding the configuration files

Fedora generates kernel configurations using a hierarchy of files. Kernel options common to all architectures and configurations are listed in individual files under baseconfig. Subdirectories under baseconfig can override the settings as needed for architectures. As an example:

$ find baseconfig -name CONFIG_SPI
baseconfig/x86/CONFIG_SPI
baseconfig/CONFIG_SPI
baseconfig/arm/CONFIG_SPI
$ cat baseconfig/CONFIG_SPI
# CONFIG_SPI is not set
$ cat baseconfig/x86/CONFIG_SPI
CONFIG_SPI=y
$ cat baseconfig/arm/CONFIG_SPI
CONFIG_SPI=y

As shown above, CONFIG_SPI is initially turned off for all architectures but x86 and arm enable it.

The directory debugconfig contains options that get enabled in kernel debug builds. The file config_generation lists the order in which directories are combined and overridden to make configs. After you change a setting in one of the individual files, you must run the script build_configs.sh to combine the individual files into configuration files. These exist in kernel-$flavor.config.

When rebuilding a custom kernel, the easiest way to change kernel configuration options is to put them in kernel-local. This file is merged automatically when building the kernel for all configuration options. You can set options to be disabled (# CONFIG_FOO is not set), enabled (CONFIG_FOO=y), or modular (CONFIG_FOO=M) in kernel-local.

Catching and fixing errors in your configuration files

The Fedora kernel build process does some basic checks on configuration files to help catch errors. By default, the Fedora kernel requires that all kernel options are  explicitly set. One common error happens when enabling one kernel option exposes another option that needs to be set. This produces errors related to .newoptions, as an example:

+ Arch=x86_64
+ grep -E '^CONFIG_'
+ make ARCH=x86_64 listnewconfig
+ '[' -s .newoptions ']'
+ cat .newoptions
CONFIG_R8188EU
+ exit 1
error: Bad exit status from /var/tmp/rpm-tmp.6BXufs (%prep)

RPM build errors:
 Bad exit status from /var/tmp/rpm-tmp.6BXufs (%prep)

To fix this error, explicitly set the options (CONFIG_R8188EU in this case) in kernel-local as well.

Another common mistake is setting an option incorrectly. The kernel Kconfig dependency checker silently changes configuration options that are not what it expects. This commonly happens when one option selects another option, or has a dependency that isn’t satisfied. Fedora attempts a basic sanity check that the options specified in tree match what the kernel configuration engine expects. This may produce errors related to mismatches:

+ ./check_configs.awk configs/kernel-4.13.0-i686-PAE.config temp-kernel-4.13.0-i686-PAE.config
+ '[' -s .mismatches ']'
+ echo 'Error: Mismatches found in configuration files'
Error: Mismatches found in configuration files
+ cat .mismatches
Found CONFIG_I2C_DESIGNWARE_CORE=y  after generation, had CONFIG_I2C_DESIGNWARE_CORE=m in Fedora tree
+ exit 1

In this example, the Fedora configuration specified CONFIG_I2C_DESIGNWARE_CORE=m, but the kernel configuration engine set it to CONFIG_I2C_DESIGNWARE_CORE=y. The kernel configuration engine is ultimately what gets used, so the solution is either to change the option to what the kernel expects (CONFIG_I2C_DESIGNWARE_CORE=y in this case) or to further investigate what is causing the unexpected configuration setting.

Once the kernel configuration options are set to your liking, you can follow standard kernel build procedures to build your custom kernel.

By now you’ve likely heard the benefits of two factor authentication. Enabling multi-factor authentication can increase the security of accounts you use to access various social media websites like Twitter, Facebook, or even your Google Account. This post is going to be about a bit more.

The U.S. Armed Services spans millions of military and civilian employees. If you’re a member of these services, you’ve probably been issued a DoD CAC smartcard to access various websites. With the smartcard comes compatibility issues, specific instructions tailored to each operating system, and a host of headaches. It’s difficult to find reliable instructions to access military websites from Linux operating systems. This article shows you how to set up your Fedora system to login to DoD CAC enabled websites.

Installing and configuring OpenSC

First, install the opensc package:

sudo dnf install -y opensc

This package provides the necessary middleware to interface with the DoD Smartcard. It also includes tools to test and debug the functionality of your smartcard.

With that installed, next set it up under the Security Devices section of Firefox. Open the menu in Firefox, and navigate to Preferences -> Advanced.

In the Certificates tab, select Security Devices. From this page select the Load button on the right side of the page. Now set a module name (“OpenSC” will work fine) and use this screen to browse to the location of the shared library you need to use.

Browse to the /lib64/pkcs11/ directory, select opensc-pkcs11.so, and click Open. If you’re currently a “dual status” employee, you may wish to select the onepin-opensc-pkcs11.so shared library. If you have no idea what “dual status” means, carry on and simply select the former package.

Click OK to finish the process.

Now you can navigate to your chosen DoD CAC enabled site and login. You’ll be prompted to enter the PIN for your CAC, then select a certificate to use. If you’re logging into a normal DoD website, select the Authentication certificate. If you’re logging into a webmail service such as https://web.mail.mil, select the Digital Signing certificate. NOTE: “Dual status” personnel should use the Authentication certificate.

Welcome to Part 2 in a series on taking smart backups with duplicity. This article builds on the basics of duplicity with a tool called duply.

Duply is a frontend for duplicity that integrates smoothly with recurring tools like cron or systemd. Its headline features are:

• keeps recurring settings in profiles per backup job
• automates import/export of keys between profile and keyring
• enables batch operations eg. backup_verify_purge
• runs pre/post scripts
• precondition checking for flawless duplicity operation

The general form for running duply is:

duply PROFILE COMMAND [OPTIONS]

Installation

duply is available in the Fedora repositories. To install it, use the sudo command with dnf:

dnf install duply

Create a profile

duply stores configuration settings for a backup job in a profile. To create a profile, use the create command.

$ duply documents create

Congratulations. You just created the profile 'documents'.
The initial config file has been created as 
'/home/link/.duply/documents/conf'.
You should now adjust this config file to your needs.

IMPORTANT:
  Copy the _whole_ profile folder after the first backup to a safe place.
  It contains everything needed to restore your backups. You will need 
  it if you have to restore the backup from another system (e.g. after a 
  system crash). Keep access to these files restricted as they contain 
  _all_ informations (gpg data, ftp data) to access and modify your backups.

  Repeat this step after _all_ configuration changes. Some configuration 
  options are crucial for restoration.

The newly created profile includes two files: conf and exclude. The main file, conf, contains comments for variables necessary to run duply. Read over the comments for any settings unique to your backup environment. The important ones are SOURCE, TARGET, GPG_KEY and GPG_PW.

To convert the single invocation of duplicity from the first article, split it into 4 sections:

duplicity --name duply_documents --encrypt-sign-key **************** --include $HOME/Documents --exclude '**'  $HOME   s3+http://**********-backup-docs
          [                         OPTIONS                        ] [                 EXCLUDES             ] [SOURCE] [             TARGET           ]

Comment out the lines starting with TARGET, SOURCE, GPG_KEY and GPG_PW by adding # in front of each line. Add the following lines to conf:

SOURCE=/home/link
TARGET=s3+http://**********-backup-docs
GPG_KEY=****************
GPG_PW=************
AWS_ACCESS_KEY_ID=********************
AWS_SECRET_ACCESS_KEY=****************************************

The second file, exclude, stores file paths to include/exclude from the backup. In this case, add the following to $HOME/.duply/documents/exclude.

+ /home/link/Documents
- **

Running duply

Run a backup with the backup command. An example run appears below.

$ duply documents backup
Start duply v2.0.2, time is 2017-07-04 17:14:03.
Using profile '/home/link/.duply/documents'.
Using installed duplicity version 0.7.13.1, python 2.7.13, gpg 1.4.21 (Home: ~/.gnupg), awk 'GNU Awk 4.1.4, API: 1.1 (GNU MPFR 3.1.5, GNU MP 6.1.2)', grep 'grep (GNU grep) 3.0', bash '4.4.12(1)-release (x86_64-redhat-linux-gnu)'.
Autoset found secret key of first GPG_KEY entry 'XXXXXXXXXXXXXXXX' for signing.
Checking TEMP_DIR '/tmp' is a folder and writable (OK)
Test - Encrypt to 'XXXXXXXXXXXXXXXX' & Sign with 'XXXXXXXXXXXXXXXX' (OK)
Test - Decrypt (OK)
Test - Compare (OK)
Cleanup - Delete '/tmp/duply.15349.1499213643_*'(OK)
Backup PUB key 'XXXXXXXXXXXXXXXX' to profile. (OK)
Write file 'gpgkey.XXXXXXXXXXXXXXXX.pub.asc' (OK)
Backup SEC key 'XXXXXXXXXXXXXXXX' to profile. (OK)
Write file 'gpgkey.XXXXXXXXXXXXXXXX.sec.asc' (OK)

INFO:

duply exported new keys to your profile.
You should backup your changed profile folder now and store it in a safe place.


--- Start running command PRE at 17:14:04.115 ---
Skipping n/a script '/home/link/.duply/documents/pre'.
--- Finished state OK at 17:14:04.129 - Runtime 00:00:00.014 ---

--- Start running command BKP at 17:14:04.146 ---
Reading globbing filelist /home/link/.duply/documents/exclude
Local and Remote metadata are synchronized, no sync needed.
Last full backup date: Tue Jul  4 14:16:00 2017
Reuse configured PASSPHRASE as SIGN_PASSPHRASE
--------------[ Backup Statistics ]--------------
StartTime 1499213646.13 (Tue Jul  4 17:14:06 2017)
EndTime 1499213646.40 (Tue Jul  4 17:14:06 2017)
ElapsedTime 0.27 (0.27 seconds)
SourceFiles 1205
SourceFileSize 817997271 (780 MB)
NewFiles 1
NewFileSize 4096 (4.00 KB)
DeletedFiles 0
ChangedFiles 0
ChangedFileSize 0 (0 bytes)
ChangedDeltaSize 0 (0 bytes)
DeltaEntries 1
RawDeltaSize 0 (0 bytes)
TotalDestinationSizeChange 787 (787 bytes)
Errors 0
-------------------------------------------------

--- Finished state OK at 17:14:07.789 - Runtime 00:00:03.643 ---

--- Start running command POST at 17:14:07.806 ---
Skipping n/a script '/home/link/.duply/documents/post'.
--- Finished state OK at 17:14:07.823 - Runtime 00:00:00.016 ---

Remember duply is a wrapper around duplicity. Because you specified –name during the backup creation in part 1, duply picked up the local cache for the documents profile. Now duply runs an incremental backup on top of the full one created last week.

Restoring a file

duply offers two commands for restoration. Restore the entire backup with the restore command.

$ duply documents restore ~/Restore
Start duply v2.0.2, time is 2017-07-06 22:06:23.
Using profile '/home/link/.duply/documents'.
Using installed duplicity version 0.7.13.1, python 2.7.13, gpg 1.4.21 (Home: ~/.gnupg), awk 'GNU Awk 4.1.4, API: 1.1 (GNU MPFR 3.1.5, GNU MP 6.1.2)', grep 'grep (GNU grep) 3.0', bash '4.4.12(1)-release (x86_64-redhat-linux-gnu)'.
Autoset found secret key of first GPG_KEY entry 'XXXXXXXXXXXXXXXX' for signing.
Checking TEMP_DIR '/tmp' is a folder and writable (OK)
Test - Encrypt to 'XXXXXXXXXXXXXXXX' & Sign with 'XXXXXXXXXXXXXXXX' (OK)
Test - Decrypt (OK)
Test - Compare (OK)
Cleanup - Delete '/tmp/duply.12704.1499403983_*'(OK)

--- Start running command RESTORE at 22:06:24.368 ---
Local and Remote metadata are synchronized, no sync needed.
Last full backup date: Thu Jul 6 21:46:01 2017
--- Finished state OK at 22:06:44.216 - Runtime 00:00:19.848 ---

Restore a single file or directory with the fetch command.

$ duply documents fetch Documents/post_install ~/Restore
Start duply v2.0.2, time is 2017-07-06 22:11:11.
Using profile '/home/link/.duply/documents'.
Using installed duplicity version 0.7.13.1, python 2.7.13, gpg 1.4.21 (Home: ~/.gnupg), awk 'GNU Awk 4.1.4, API: 1.1 (GNU MPFR 3.1.5, GNU MP 6.1.2)', grep 'grep (GNU grep) 3.0', bash '4.4.12(1)-release (x86_64-redhat-linux-gnu)'.
Autoset found secret key of first GPG_KEY entry 'XXXXXXXXXXXXXXXX' for signing.
Checking TEMP_DIR '/tmp' is a folder and writable (OK)
Test - Encrypt to 'XXXXXXXXXXXXXXXX' & Sign with 'XXXXXXXXXXXXXXXX' (OK)
Test - Decrypt (OK)
Test - Compare (OK)
Cleanup - Delete '/tmp/duply.14438.1499404312_*'(OK

--- Start running command FETCH at 22:11:52.517 ---
Local and Remote metadata are synchronized, no sync needed.
Last full backup date: Thu Jul 6 21:46:01 2017
--- Finished state OK at 22:12:44.447 - Runtime 00:00:51.929 ---

duply includes quite a few commands. Read the documentation for a full list of commands.

Other features

Timer runs become easier with duply than with duplicity. The systemd user session lets you create automated backups for your data. To do this, modify ~/.config/systemd/user/backup.service, replacing ExecStart=/path/to/backup.sh with ExecStart=duply documents backup. The wrapper script backup.sh is no longer required.

duply also makes a great tool for backing up a server. You can create system wide profiles inside /etc/duply to backup any part of a server. Now with a combination of system and user profiles, you’ll spend less time worrying about your data being backed up.

Fedora 26 is available now, providing a wide range of improvements across the entire operating system. Anaconda — the Fedora installer — has many new features and improvements implemented for Fedora 26. The most visible addition is the introduction of Blivet GUI, providing power users an alternate way to configure partitioning. Additionally, there are improvements to automated installation with kickstart, a range of networking improvements, better status reporting when your install is under way, and much more.

Enhanced storage configuration with Blivet GUI

The main highlight of Anaconda in Fedora 26 is the integration of Blivet GUI storage configuration tool into the installation environment. Previously, there were two options for storage configuration — automatic partitioning and manual partitioning. Automatic partitioning is mostly useful for really simple configurations, like installing Fedora on an empty hard drive or alongside of another existing operating system. The existing manual partitioning tool provides more control over partition layouts and size, enabling more complicated setups.

The previously-available manual partitioning tool is quite unique. Instead of creating all the storage components manually, the user just specifies future mountpoints and their properties. For example, you simply create two “mountpoints” for /home and / (root), specify properties like encryption or RAID and Anaconda properly configures all the necessary components below. This top-down model is really powerful and easy to use but might be too simple for some complicated storage setups.

This is where Blivet GUI can help — it is a storage configuration tool that works in the standard way. If you want an LVM storage on top of RAID, you need to create it manually from the building blocks — from bottom up. With a good knowledge of custom partitioning layouts, complicated custom storage setups are easily created with BlivetGUI.

Using Blivet GUI in Anaconda

Blivet GUI has been available from Fedora repositories as a standalone desktop application since Fedora 21 and now comes also to Anaconda as a third option for storage configuration. Simply choose Advanced Custom (Blivet-GUI) from the Installation Destination window in Anaconda.

Installation Destination window in Anaconda

Blivet GUI has full integration into the Anaconda installation workflow. Only the selected disks in the Installation Destination window show in BlivetGUI. Changes remain unwritten to the disks until you leave the window and choose Begin Installation. Additionally, you can always go back and use one of the other partitioning methods. However, Blivet GUI discards changes if you switch to a different partitioning method.

Storage configuration using Blivet GUI in Anaconda

Adding a new device using Blivet GUI in Anaconda

Automated install (kickstart) improvements

Kickstart is the configuration file format for automation of the installation process. A Kickstart file can configure all options available in the graphical and text interfaces and much more. View the Kickstart documentation for more information about Kickstart and how to use it.

Support for –nohome, –noswap and –noboot options in auto partitioning

When you don’t want to specify your partitions, you can let anaconda do that for you with the autopart command. It will automatically create a root partition, a swap partition and a boot partition. With Fedora Workstation, the installed creates a /home partition on large enough drives. To make the auto partitioning more flexible, anaconda now supports the –nohome, –noswap and –noboot options that disable the creation of the given partition.

Strict validation of the kickstart file with inst.ksstrict

It is not uncommon for sysadmins to have complicated kickstart files, and sometimes kickstart files have errors. At the beginning of the installation, anaconda checks the kickstart file and produces errors and warnings. Errors result in the termination of the installation.The log records warnings and the installation continues.

To ensure a kickstart file doesn’t produce any warnings, enable the new strict validation with the boot option inst.ksstrict. This treats warnings in kickstart in the same way as errors.

Snapshot support

Sometimes it is helpful to save an old installation or have a backup of freshly installed system for recovery. For these situations the snaphost kickstart command is now available. View the pykickstart documentation for full usage instructions of this new command. This feature is currently supported on LVM thin pools only. To request support for other partition types please file an RFE bug on bugzilla.

Networking improvements

Networking is a critical part of Anaconda as many installations are partially or fully network based. Anaconda also supports installation to network attached storage devices such as iSCSI, FCoE and Multipass. For this reason Anaconda needs to be able to support complex networking setups not only to even just start the installation but also to correctly setup networking for the installed system.

For this Fedora cycle we have mostly bug fixes, adaptation to NetworkManager rebase, enhancements to the network kickstart tests suite to discover issues caused by NM changes and some changes in components we are using in general. Also adding support for various – mostly enterprise driven – features:

• Support for IPoIB (IP over infiniband) devices in TUI.
• Support for setting up bridge device at early stage of installation (eg to fetch kickstart).
• New inst.waitfornet boot option for waiting for connectivity at later stage of installation in cases where default waiting for DHCP configuration is not sufficient due to special network environment (DHCP servers) setup.

Other improvements

Anaconda and Pykickstart documentation on Read the Docs

The Anaconda and Pykickstart documentation have a new home on ReadTheDocs:

• https://anaconda-installer.readthedocs.io/
• https://pykickstart.readthedocs.io

Also the Pykickstart documentation now contains full detailed kickstart command reference, both for Fedora and RHEL.

Progress reporting for all installation phases

Do you also hate it when Anaconda says “processing post installation setup tasks” for many minutes (or even tens of minutes!) without any indication what’s actually going on and how much longer it might take?

The cause of the previous lack of status reporting was simple – during the final parts of the RPM installation transaction RPM post & posttrans scriptlets are running and that can take a significant amount of time. And until recently there was no support from RPM and DNF for progress reporting from this installation phase.

But this has been rectified, RPM & DNF now provide the necessary progress reporting, so Anaconda can finally report what’s actually happening during the full installation run.

Run Initial Setup TUI on all usable consoles

Initial Setup is a utility to configure a freshly installed system on the first start. Initial Setup provides both graphical and text-mode interfaces and is basically just a launcher for the configuration screens normally provided by Anaconda.

During a “normal” installation everything is configured in Anaconda and Initial Setup does not run. However, the situation is different for the various ARM boards supported by Fedora. Here the installation step is generally skipped and users boot from a Fedora image on an SD card. In this scenario Initial Setup is a critical component, enabling users to customize the pre-made system image as needed.

The Initial Setup text interface (TUI) is generally used on ARM systems. During the Fedora 25 time frame two nasty issues showed up:

• some ARM board have both serial and graphical consoles with no easy way detect which the user is using
• some ARM board consoles appear functional, but throw errors when Initial Setup tries to run the TUI on them

To solve these issues, the Initial Setup TUI is run on all consoles that appear to be usable. This solves the first issue – the TUI will run on both the serial and graphical consoles. It also solves the second issue, as consoles that fail to work as expected are simply skipped.

Built in help is now also available for the TUI

Previously, only the graphical installation mode featured help. However, help is accessible in the TUI from every screen that offers the ‘h to help’ option.

Help displayed in the TUI

New log-capture script

The new log-capture script is an addition from community contributor Pat Riehecky. This new script makes it easy to gather many installation relevant log files into a tarball, which is easily transferred outside of the installation environment for detailed analysis.

The envisioned use case is running the log-capture script in kickstart %onerror scriptlets.

Structured installation tasks

Anaconda does a lot of things during the installation phase (configures storage, installs packages, creates users & groups, etc.). To make the installation phase easier to monitor and to debug any issues the individual installation tasks are now distinct units (eq. user creation, user group creation, root user configuration.) that can be part of task groups (eq. user & group configuration).

End result – it is now easy to see in the logs how long each task took to execute, which task is currently running & how many tasks still need to be executed until the installation is done.

User interaction config file

Anaconda supports the new user interaction config file. A special configuration file to record the screens and (optionally) the settings manipulated by the user.

The main idea behind the user interaction config file is that a user generally comes into contact with multiple separate applications (Anaconda, Gnome Initial Setup, Initial Setup, a hypothetical language selector on a live CD, etc.) during an installation run and it would make sense to only present each configuration option (say language or timezone selection) only once and not multiple times. This should help to reduce the amount of screens a user needs to click through, making the installation faster.

Anaconda will record visited screens and will hide screens marked as visited in an existing user interaction config file. But once other pre & post installations tools (such as for example Gnome Initial Setup) start picking up support it should be easy to spot as users should no longer be asked to configure the same setting twice. But we might not have to wait for long as a Fedora 27 change proposal for adding Gnome Initial Setup support already exists.