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This post will cover building a two factor authentication provider using RADIUS and Google Authenticator. This is an update to a post from over three years ago. The basic configuration is roughly the same, there are just a few minor updates to account for the move from Ubuntu 16.04 to 18.04.

1. Create Ubuntu 20.04 VM
   • Previous post: Lab Updates: Ubuntu Server 20.04 LTS Template
   • Previous post: Deploy Ubuntu 18.04 from Template [These steps work for Ubuntu 20.04 as well.]
2. Modify Ubuntu to only allow login by specific Two Factor Users
3. Install and configure required packages
4. Enroll 2FA Users
5. Migrate existing google_authenticator config files to a new server
6. Testing with radtest

Modify Ubuntu to only allow login by Specific Two Factor Users

The default Ubuntu template we created has a configuration that will grant all members of the Domain Users group the ability to login. While this is generally ‘good enough’ for a lab, in this specific case we want to limit the users who have the ability to login using Two Factor Authentication (2FA), as we will be using the 2FA solution to provide remote access to the network and want to ensure that only trusted users are permitted.

The specific setting we previously defined in joinad.sh was RequireMembershipOf. We can use the following command to see which groups have the ability to login:

Running this command shows four rows — multistring, lab\domain^users, blank, and local policy. This is because of our ./joinad.sh script that previously set the default group to Domain Users.  If I run the ./config RequireMembershipOf command again, it replaces domain users with the new group.  For my purposes I want two groups — the Linux Sudoers group (which is defined in the sudoers group, which contains my Linux Admin users) and the 2FA Users group.  We can do that by passing both group names in one command, like this:

This will replace the Domain Users row with the two groups specified above. When searching to see if there was an easier way to append, I found the following blog post which contains a script that uses regex to find the existing group and then add the group that is needed: https://techblog.jeppson.org/2017/01/append-users-groups-powerbroker-open-requiremembershipof/

Install and configure required packages

The first command we will run is identical to the previous instructions — we’ll install the pluggable authentication module (PAM) for Google Authenticator and FreeRadius. With Ubuntu 18.04 this will install FreeRadius 3.0, which will lead to a few of the changes from the initial article (mainly paths and one extra command).

By default, FreeRadius 3.0 does not enable the PAM module. We will manually do that by creating a link in the available mods directory using this command:

We will be storing our per-user Google Authenticator files in each users home directory. This will prevent users from finding/using other users 2FA secret. Because of this configuration, we need the FreeRadius service to be able to run as root (so it can read all users Google Authenticator configuration files). To do this we will edit the radiusd.conf using a text editor:

We will find the rows that state user = freerad and group = freerad and replace them with:

Next we will append the users file to set PAM as the default authentication type.

Next we need to update a file to enable PAM pluggable authentication modules in FreeRadius. Note: to find text using nano, you can use CTRL+W.

When we find the text for #PAM, remove the pound sign (which will remove the example/comment and enable PAM).

We will now configure the PAM Radius service to use Google Authenticator.

Comment out the @include lines in the file, then add the following text:

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auth requisite pam_google_authenticator.so forward_pass

account required pam_unix.so use_first_pass

Now we need to define which clients can use our RADIUS server, and what their ‘secret’ will be. It is common to restrict this so only specific hosts can access RADIUS, and each server can have a unique secret. However, for my lab, I’m going to allow all servers to connect to RADIUS using the same secret. Password/secret re-use is a bad security practice. We do this by editing this file:

And add a client entry like this one:

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client 192.168.0.0/16 {

        secret          = s3cur3.rad

        shortname       = PrimaryLabSubnet

}

We can have multiple secrets, for example one per host, which would be more secure. Note: the secret should only contain alphanumeric and _-+.  (underscore hyphen plus period) characters.

Now that we have all of the configuration files edited, we can restart the freeradius service:

Enroll 2FA Users

When an authorized user logs into the Radius server (over SSH) they can run google-authenticator to generate a configuration file. This interactive prompt will ask them a few questions and then generate a QR code that they can scan from a mobile phone with the Google Authenticator application. However, we can suppress some of these questions and ensure a consistent experience for our users.

We can do this by adding an alias to the bashrc file, which is executed at every interactive login.

Now we scroll down to where the other aliases are and add one of our own:

This will create an alias named google-auth that will pass in all the expected inputs. Users will now run google-auth instead of google-authenticator. If you have already logged in, the changes to the default bashrc file may not be available in your profile. You can fix this by copying the updated bashrc file (cp /etc/skel/.bashrc /home/yourusername/.bashrc).

Migrate existing google_authenticator config files to a new server

In each users home directory, there is a hidden .google_authenticator file. This file is only readable by the user and root (permissions = 400) and contains the information on the clients one time use key. In my scenario I have an existing FreeRadius server running on Ubuntu 16.04 that I want to replace with this new 18.04 server, and as such I have some existing files that I’d like to move over to the new server. This same process (coupled with cron) could be tweaked slightly to use as a backup solution for these .google_authenticator files. Here is what I did to get these moved over, starting with commands ran on the source server:

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tar -czvf googleauth-backup.tar.gz /home/*/.google_authenticator

scp googleauth-backup.tar.gz bwuchner@new-radius-01.lab.enterpriseadmins.org:/tmp

Once the files are backed up and copied to the new server, we will run this command on the destination server:

This will extract the .google_authenticator files, retaining the previous owner for the files. If the user home directory did not exist, a new folder will be created. The problem is that this new folder structure is created & owned by root. This isn’t an issue for the operation of the 2FA solution, but could be a problem if the user needs to log back in to the Radius server at some point — as they won’t be able to save files in their profile. We can fix that by resetting the ownership of each home directory back to the specific user & Domain Users group. To do that we could run a command like this on the destination server:

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cd /home

for i in *; do sudo chown $i:domain^users /home/$i; done

To confirm this worked, we can execute a ls -lha /home on destination server, to ensure that we see expected ownership on each directory.

Testing with radtest

When we installed FreeRadius we also received some handy command line tools that we can use to test our configuration. This syntax of rad test expects a username, one time passcode, RADIUS server iP address, port, and secret, like this:

The response should show Access-Accept. If you get something else, like Access-Reject, then check /var/log/auth.log to see what went wrong. I find that it is easiest to have two SSH sessions opened — one running radtest and the other running

At this point you should be able to use the Radius server to provide Two Factor Authentication (2FA) to any necessary service. To see one example of doing this with a VMware Unified Access Gateway (UAG) check out this video I recorded as part of the VMware TAM Lab program: https://www.youtube.com/watch?v=8Ybl58x0CLg.

I was recently showing someone my homelab and they noticed that I had templates for multiple Linux distributions including Ubuntu Server, Photon OS, and Tiny Core, as well as different versions of each. They asked why I didn’t standardize on just one Linux distribution or version. The version issue is easy — I can be lazy when it comes to cleaning up old templates. The reason for multiple distributions required a bit of extra explanation, so I figured I would type it up here.

Tiny Core is a very small Linux distribution that I can clone in seconds. If I want to test something like network connectivity, a new DHCP scope, scripting something against a handful of VMs, or something that deals with the disk of a VM like vSphere Replication or a VM image backup/restore Tiny Core is perfect… just enough of a VM to get the job done. Instructions on how to create such a template can be found in this previous post: https://enterpriseadmins.org/blog/lab-infrastructure/lightweight-vm-for-testing-tinycore-linux/.

Photon OS is a minimal Linux distribution optimized to run on VMware platforms. Its already available as an OVA here: https://github.com/vmware/photon/wiki/Downloading-Photon-OS, so I just imported it once and saved it as a template. It only takes a couple minutes to deploy one of these and configure it to run Docker containers. For an example of something you can use it for, check out this previous post https://enterpriseadmins.org/blog/scripting/vrealize-operations-alerts-using-rest-notification-plugin/.

Ubuntu Server is the largest Linux template I have on disk, but is still relatively small compared to a Windows template (my configured Ubuntu Server 18.04 template is ~5GB). Ubuntu is a consumer friendly distribution with current support for a lot of different packages. I have one of these VMs running PiHole and another used as a 2FA/RADIUS server that I use for Two Factor Authentication with Horizon UAG. Here is a previous post for building an Ubuntu 18.04 template: https://enterpriseadmins.org/blog/virtualization/lab-updates-ubuntu-18-04-template/

What Linux distribution do you like that I am missing?

I’ve often found the need to have a very small VM for testing. Some use cases would be testing if a DHCP scope was working, to verify if a VM port group was correctly configured, to confirm if a site-to-site VPN tunnel was up/passing traffic, to deploy/modify with PowerCLI, and many, many more others. Typically all I’m looking for is a command prompt, a network stack, and preferably VMware Tools running. Many years ago I stumbled on TinyCore Linux — a very small distribution that with a GUI and open-vm-tools installed only took 53mb of disk space as an OVA. Such a small distribution was easy and fast to deploy and used nearly no resources, so it was ideal for testing. This OVA was super handy, I had it on various file shares, a web URL, and even as a VM Template so that I could easily get to it for testing. The OVA I created was based on TinyCore 3.6 (Linux kernel 2.6) — like I said, I’ve had this for many years. I recently went looking to see if TinyCore was still being developed and if a newer version was available. What I found was TinyCore 11 (Linux kernel 5.4) that was released earlier this month. The steps below show how you can create your very own lightweight VM based on this latest distribution.

To begin we should download the ISO. I used the CorePlus-11.0.iso from http://tinycorelinux.net/11.x/x86/release/. Once I had the ISO, I uploaded it to a datastore. (Note: These instructions were tested on an ESXi 6.7u3 host, but should be similar on different versions and/or hypervisors.) . Here are the settings I used for the new VM

• Compatible with ESXi 6.0 and later (hardware version 11). Note: as of this writing ESXi 6.0 is still supported, so I made this choice to ensure a the newest features would be available while maintaining maximum backwards compatibility (to all supported platforms).
• Guest OS = Linux \ Other 3.x Linux (32-bit). Note: if using a newer version of virtual hardware, additional / newer Other Linux options may exist. TinyCore is based on Linux kernel 5.4, so we want to pick the nearest option available.
• Memory = 256mb. Note: I tested with lower amounts of RAM, but this was the lowest that worked consistently. Your mileage may vary.
• New Hard Disk – Remove
• New CD/DVD Drive > Datastore ISO File, browse to CorePlus-11.0.iso uploaded earlier and select Connect…
• Expand CD/DVD Drive and change Virtual device Node to IDE1:0
• Add a new device > hard disk, size = 64mb, expand details and change virtual device node to IDE 0:0
• Remove the new SCSI controller as it is not used
• Under VM Options tab \ Boot Options \ confirm that Firmware = BIOS (recommended). Note: if you use a newer version of virtual hardware, a different firmware option may be selected by default.
• Power On VM
• Open with Remote Console (not web console). Note: this requires VMRC to be installed. By default in TinyCore the mouse pointer does not work with the web console.

Once the VM boots, you should see a menu of different boot options. Select the option “Boot Core with X/GUI (TinyCore) + Installation Extension.” Here are additional settings I selected:

• Once the GUI has loaded, run tc-install (the last icon on the bar at the bottom of the screen)
• Select Whole Disk and sda (Frugal and install boot loader should be checked by default)
• Next > ext4 > next > next > Core Only (Text Based Interface) > next > Proceed
• The wizard should say ‘Installation has completed’
• Click Exit on the tool bar at the bottom of the screen, then Reboot

The VM will now boot into the shell prompt of the locally installed copy of TinyCore. We will now install some additional packages from the command line. This assumes the network in use has DHCP available and we already have an IP / internet connectivity.

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tce-load -wi pcre.tcz

tce-load -wi open-vm-tools.tcz

tce-load -wi curl.tcz

Note: for me, the open-vm-tools install ended with text about fuse.conf not being a file or directory.  This did not cause any issues in my testing.

Next we check to ensure the new packages (pcre.tcz, open-vm-tools.tcz, and curl.tcz) are listed (one per row) in the list of packages loaded at boot (using command cat /etc/sysconfig/tcedir/onboot.lst).

In my testing, I noticed that sometimes open-vm-tools is not started correctly at boot. I’m not sure what causes this, but found a simple workaround by using a script that runs automatically at boot to restart the service. I did this by typing sudo vi /opt/bootlocal.sh

At the end of this file, I pressed i (to get into insert mode) and added the text /usr/local/etc/init.d/open-vm-tools restart.  We then save & exit from file by pressing the escape key (to exit insert mode) and typing :wq (to write changes and quit the vi editor).

By default the hostname of the VM is ‘box.’ However, I wanted to set a custom value. To do this we edit the bootsync.sh script by typing sudo vi /opt/bootsync.sh. We then replace the text ‘box’ on the line for sethostname with our FQDN. Note: this isn’t how hostnames are typically set in Linux, and I would assume this would not be updated by a vCenter customization spec. I’m only adding a value for reference when I see the hostname in vCenter that is presented by VMware Tools.

When the VM boots up, there is some text that’s automatically displayed from the message of the day (MOTD) file. We want to edit this to include some simple instructions. However, the changes to the MOTD file are not persistent by default. To include this file in the list of persistent files, we need to add an entry to a file. We can do this by typing vi /opt/.filetool.lst and adding an entry for “etc/motd” (without the quotes). Now that these changes persist, we can make changes to the MOTD with the command sudo vi /etc/motd. In this example I’ve added instructions for how to set a static IP address and to use curl to test a specific TCP port:

As a cleanup step, I like to remove the command history from templates. To do this for TinyCore we can type rm .ash_history to remove the file.

To trigger a backup of the files we’d like to persist, we simply type backup and press y for yes.

With all our changes complete, we can test that the VM starts up correctly by issuing the command sudo reboot.

Confirm that VMware Tools is working and that your message of the day is displayed.  On ESXi or vCenter you can confirm that VMware Tools are working by reviewing the status tab of the running VM. In this screenshot you can see that tools version 11269 is running. Clicking more info confirms that this is version 11.0.5 (the latest available as of this post).

You may notice that the Guest OS is showing Other 4.x or later Linux, even though we selected Other 3.x when creating the VM. This is because VMware Tools is presenting the property from within the guest, instead of defaulting to the property from the VM creation wizard.

You can now shutdown the VM and change the CD ROM back to Client Device (to detach the ISO image). From here we can export the VM to an OVF or convert to a virtual machine template. As an OVF this VM is roughly 19mb on disk. It will deploy very quick and is just enough of an appliance for many test cases.

Note: there are a few other recommended changes you may want to consider if you are building a template for use in VMware Fusion or Workstation that relate to display resizing and copy/paste. Those are documented here: http://wiki.tinycorelinux.net/wiki:vmware_installation.