The Fedora Classroom is a project to help people by spreading knowledge on subjects related to Fedora for others, If you would like to propose a session, feel free to open a ticket here with the tag classroom. If you’re interested in taking a proposed session, kindly let us know and once you take it, you will be awarded the Sensei Badge too as a token of appreciation. Recordings from the previous sessions can be found here.

We’re back with another awesome classroom on Git 101 with Pagure led by Akashdeep Dhar (t0xic0der).

About the session

In short, the Git 101 with Pagure session will be a guide for newcomers on how to get started with Git with the git forge Pagure used by the Fedora community. After finishing the session you will have the knowledge to manage Git and Pagure and generate the first contributions on the Fedora Project.

When and where

The Classroom session will be organized on Jul 17th, 17:00 UTC. Here’s a link to see what time it is in your timezone. The session will be streamed on Fedora Project’s YouTube channel.

Topics covered in the session

• Version Control Systems
• Why Git?
• VCS Hosting Sites
• Fedora Pagure
• Exploring Pagure
• Git Fundamentals

About the instructor

Akashdeep Dhar is a cybersecurity enthusiast with keen interests in networking, cloud computing and operating systems. He is currently in the final year of his computer science major with cybersecurity minor bachelor degree. He has over five years of experience in using GNU/Linux systems and is new to the Fedora community with contributions made so far in infrastructure, classroom and documentation.

If you miss the session, the recording will also be uploaded in the Fedora Project‘s YouTube channel.

We hope you can attend and enjoy this experience from some of the awesome people that work in Fedora Project. We look forward to seeing you in the Classroom session.

Photograph used in feature image is San Simeon School House by Anita Ritenour — CC-BY 2.0.

Ansible is a great automation tool for system and network engineers, with Ansible we can automate small network to a large scale enterprise network. I have been using Ansible to automate both Aruba, and Cisco switches from my Fedora powered laptops for a couple of years. This article covers the requirements and executing a couple of playbooks.

Configuring Ansible

If Ansible is not installed, it can be installed using the command below

$ sudo dnf -y install ansible

Once installed, create a folder in your home directory or a directory of your preference and copy the ansible configuration file. For this demonstration, I will be using the following.

$ mkdir -pv /home/$USER/network_automation
$ sudo cp -v /etc/ansible.cfg /home/$USER/network_automation
$ cd /home/$USER/network_automation
$ sudo chown $USER.$USER && chmod 0600 ansible.cfg

To prevent lengthy commands from failing, edit the ansible.cfg and append the following lines. We must add the persistent connection and set the desired time in seconds for the command_timeout as demonstrated below. A use case where this is useful is when you are performing backups of a network device that has a lengthy configuration.

$ vim ansible.cfg
[persistent_connection]
command_timeout = 300
connection_timeout = 30

Requirements

If SELinux is enabled, you will need to install SELinux binding, which is required when using the copy module.

# Install SELinux bindings
dnf -y install python3-libselinux python3-libsemanage

Creating the inventory

The inventory holds the names of the network assets, and grouping of the assets are in square brackets [], below is a  sample inventory.

[site_a]
Core_A ansible_host=192.168.122.200
Distro_A ansible_host=192.168.122.201
Distro_B ansible_host=192.168.122.202

Playbook

Read Operations

Let us create a simple playbook to run a show command to read the configuration on a few switches.

  1 ---

  2 - name: Basic Playbook

  3   hosts: site_a

  4   connection: local

  5 

  6   tasks:

  7   - name: Get Interface Brief

  8     ios_command:

  9       commands:

 10         - show ip interface brief | e una

 11     register: interfaces

 12 

 13   - name: Print results

 14     debug:

 15       msg: "{{ interfaces.stdout[0] }}

<figure></figure>

<figure></figure>

The above images show the differences without and with the debug module respectively.

Let’s break the playbook into three blocks, starting with lines 1 to 4.

• The three dashes/hyphens starts the YAML document
• The hosts defines the hosts or host groups, multiple groups are comma-separated
• Connection defines the methodology to connect to the network devices. Another option is network_cli (recommended method) and will be used later in this article. See IOS Platform Options for more details.

Lines 6 to 11 starts the tasks, we will be using ios_command and ios_config. This play will execute the show command show ip interface brief | e una and save the output from the command into the interfaces variable, with the register key.

Lines 13 to 15, by default, when you execute a show command you will not see the output, though this is not used during automation. It is very useful for debugging; therefore, the debug module was used.

The below video shows the execution of the playbook. There are a couple of ways you can execute the playbook.

• Passing arguments to the command line, for example, include -u <username> -k to prompt for the remote user credentials

ansible-playbook -i inventory show_demo.yaml -u admin -k

• Include the credentials in the host or group vars

ansible-playbook -i inventory show_demo.yaml

If we want to save the output to a file, we will use the copy module as shown in the playbook below. In addition to using the copy module, we will include the backup_dir variable to specify the directory path.

---

- name: Get System Infomation

  hosts: site_a

  connection: network_cli

  gather_facts: no

  

  vars:

    backup_dir: /home/eramirez/dev/ansible/fedora_magazine

  

  tasks:

  - name: get system interfaces

    ios_command:

      commands:

        - show ip int br | e una

    register: interface

    

  - name: Save result to disk

    copy:

      content: "{{ interface.stdout[0] }}"

      dest: "{{ backup_dir }}/{{ inventory_hostname }}.txt"

[site_a]

Core_A ansible_host=192.168.122.200

Distro_A ansible_host=192.168.122.201

Distro_B ansible_host=192.168.122.202

[all:vars]

ansible_connection=network_cli

ansible_network_os=ios

ansible_user=admin

ansible_password=fedora

ansible_become=yes

ansible_become_password=yes

ansible_become_method=enable

Write Operations

---

- name: Get System Infomation

  hosts: site_a

  connection: network_cli

  gather_facts: no

  

  vars:

    backup_dir: /home/eramirez/dev/ansible/fedora_magazine

  

  tasks:

  - name: Backup configs

    ios_config:

      backup: yes

      backup_options:

        filename: "{{ inventory_hostname }}_running_cfg.txt"

        dir_path: "{{ backup_dir }}"

    

  - name: get system interfaces

    ios_config:

      lines:

        - description Raspberry Pi

        - switchport mode access

        - switchport access vlan 100

        - spanning-tree portfast

        - logging event link-status

        - no shutdown

      parents: "{{ item }}"

    with_items:

      - interface FastEthernet1/12

      - interface FastEthernet1/13

      

  - name: Save switch configuration

    ios_config:

      save_when: modified

Before we execute the playbook, we will first validate the interface configuration. We will then run the playbook and confirm the changes as illustrated below.

Conclusion

This article is a basic introduction to whet your appetite that demonstrates how Ansible is used to manage network devices. Ansible is capable of automating a vast network, which includes MPLS routing and performing validation before executing the next task.

Step 1 : Set-up systemd-resolved

Modify /etc/systemd/resolved.conf so that it is similar to what is shown below. Be sure to enable DNS over TLS and to configure the IP addresses of the DNS servers you want to use.

$ cat /etc/systemd/resolved.conf
[Resolve]
DNS=1.1.1.1 9.9.9.9
DNSOverTLS=yes
DNSSEC=yes
FallbackDNS=8.8.8.8 1.0.0.1 8.8.4.4
#Domains=~.
#LLMNR=yes
#MulticastDNS=yes
#Cache=yes
#DNSStubListener=yes
#ReadEtcHosts=yes

A quick note about the options:

• DNS: A space-separated list of IPv4 and IPv6 addresses to use as system DNS servers
• FallbackDNS: A space-separated list of IPv4 and IPv6 addresses to use as the fallback DNS servers.
• Domains: These domains are used as search suffixes when resolving single-label host names, ~. stand for use the system DNS server defined with DNS= preferably for all domains.
• DNSOverTLS: If true all connections to the server will be encrypted. Note that this mode requires a DNS server that supports DNS-over-TLS and has a valid certificate for it’s IP.

NOTE: The DNS servers listed in the above example are my personal choices. You should decide which DNS servers you want to use; being mindful of whom you are asking IPs for internet navigation.

Step 2 : Tell NetworkManager to push info to systemd-resolved

Create a file in /etc/NetworkManager/conf.d named 10-dns-systemd-resolved.conf.

$ cat /etc/NetworkManager/conf.d/10-dns-systemd-resolved.conf
[main]
dns=systemd-resolved

The setting shown above (dns=systemd-resolved) will cause NetworkManager to push DNS information acquired from DHCP to the systemd-resolved service. This will override the DNS settings configured in Step 1. This is fine on a trusted network, but feel free to set dns=none instead to use the DNS servers configured in /etc/systemd/resolved.conf.

Step 3 : start & restart services

To make the settings configured in the previous steps take effect, start and enable systemd-resolved. Then restart NetworkManager.

CAUTION: This will lead to a loss of connection for a few seconds while NetworkManager is restarting.

$ sudo systemctl start systemd-resolved
$ sudo systemctl enable systemd-resolved
$ sudo systemctl restart NetworkManager

NOTE: Currently, the systemd-resolved service is disabled by default and its use is opt-in. There are plans to enable systemd-resolved by default in Fedora 33.

Step 4 : Check if everything is fine

Now you should be using DNS over TLS. Confirm this by checking DNS resolution status with:

$ resolvectl status
MulticastDNS setting: yes                 
  DNSOverTLS setting: yes                 
      DNSSEC setting: yes                 
    DNSSEC supported: yes                 
  Current DNS Server: 1.1.1.1             
         DNS Servers: 1.1.1.1             
                      9.9.9.9             
Fallback DNS Servers: 8.8.8.8             
                      1.0.0.1             
                      8.8.4.4

/etc/resolv.conf should point to 127.0.0.53

$ cat /etc/resolv.conf
# Generated by NetworkManager
search lan
nameserver 127.0.0.53

To see the address and port that systemd-resolved is sending and receiving secure queries on, run:

$ sudo ss -lntp | grep '\(State\|:53 \)'
State     Recv-Q    Send-Q       Local Address:Port        Peer Address:Port    Process                                                                         
LISTEN    0         4096         127.0.0.53%lo:53               0.0.0.0:*        users:(("systemd-resolve",pid=10410,fd=18))

To make a secure query, run:

$ resolvectl query fedoraproject.org
fedoraproject.org: 8.43.85.67                  -- link: wlp58s0
                   8.43.85.73                  -- link: wlp58s0

[..]

-- Information acquired via protocol DNS in 36.3ms.
-- Data is authenticated: yes

BONUS Step 5 : Use Wireshark to verify the configuration

First, install and run Wireshark:

$ sudo dnf install wireshark
$ sudo wireshark

It will ask you which link device it have to begin capturing packets on. In my case, because I use a wireless interface, I will go ahead with wlp58s0. Set up a filter in Wireshark like tcp.port == 853 (853 is the DNS over TLS protocol port). You need to flush the local DNS caches before you can capture a DNS query:

$ sudo resolvectl flush-caches

Now run:

$ nslookup fedoramagazine.org

You should see a TLS-encryped exchange between your computer and your configured DNS server:

<figure class="aligncenter size-large"></figure>

— Poster in Cover Image Approved for Release by NSA on 04-17-2018, FOIA Case # 83661 —

The Rosetta@home project is a not-for-profit distributed computing project created by the Baker laboratory at the University of Washington. The project uses idle compute capacity from volunteer computers to study protein structure, which is used in research into diseases such as HIV, Malaria, Cancer, and Alzheimer’s.

In common with many other scientific organizations, Rosetta@home is currently expending significant resources on the search for vaccines and treatments for COVID-19.

Rosetta@home uses the open source BOINC platform to manage donated compute resources. BOINC was originally developed to support the SETI@home project searching for Extraterrestrial Intelligence. These days, it is used by a number of projects in many different scientific fields. A single BOINC client can contribute compute resources to many such projects, though not all projects support all architectures.

For the example shown in this article a Raspberry Pi 3 Model B was used, which is one of the tested reference devices for Fedora IoT. This device, with only 1GB of RAM, is only just powerful enough to be able to make a meaningful contribution to Rosetta@home, and there’s certainly no way the Raspberry Pi can be used for anything else – such as running a desktop environment – at the same time.

It’s also worth mentioning at this point that the first rule of Raspberry Pi computing is to get the recommended power supply. It is important to get as close to the specified 2.5A as you can, and use a good quality micro-usb cable.

Getting Fedora IoT

To install Fedora IoT on a Raspberry Pi, the first step is to download the aarch64 Raw Image from the iot.fedoraproject.org download page.

Then use the arm-image-installer utility (sudo dnf install fedora-arm-installer) to write the image to the SD card. As always, be very sure which device name corresponds to your SD Card before continuing. Check the device with the lsblk command like this:

$ lsblk
NAME      MAJ:MIN RM SIZE RO TYPE MOUNTPOINT
sdb         8:16 1 59.5G  0 disk
└─sdb1      8:17 1 59.5G  0 part /run/media/gavin/154F-1CEC
nvme0n1     259:0 0 477G  0 disk
├─nvme0n1p1 259:1 0 600M  0 part
...

If you’re still not sure, try running lsblk with the SD card removed, then again with the SD card inserted and comparing the outputs. In this case it lists the SD card as /dev/sdb. If you’re really unsure, there are some more tips described in the Getting Started guide.

We need to tell arm-image-installer which image file to use, what type of device we’re going to be using, and the device name – determined above – to use for writing the image. The arm-image-installer utility is also able to expand the filesystem to use the entire SD card at the point of writing the image.

Since we’re not going to use the zezere provisioning server to deploy SSH keys to the Raspberry Pi, we need to specify the option to remove the root password so that we can log in and set it at first boot.

In my case, the full command was:

sudo arm-image-installer --image ~/Downloads/Fedora-IoT-32-20200603.0.aarch64.raw.xz --target=rpi3 --media=/dev/sdb --resizefs --norootpass

After a final confirmation prompt:

= Selected Image:                                 
= /var/home/gavin/Downloads/Fedora-IoT-32-20200603.0.aarc...
= Selected Media : /dev/sdb
= U-Boot Target : rpi3
= Root Password will be removed.
= Root partition will be resized
=====================================================
 
*****************************************************
*****************************************************
******** WARNING! ALL DATA WILL BE DESTROYED ********
*****************************************************
*****************************************************
 
 Type 'YES' to proceed, anything else to exit now 

the image is written to the SD Card.

...
= Installation Complete! Insert into the rpi3 and boot.

Booting the Raspberry Pi

For the initial setup, you’ll need to attach a keyboard and mouse to the Raspberry Pi. Alternatively, you can follow the instructions for connecting with a USB-to-Serial cable.

When the Raspberry Pi boots up, just type root at the login prompt and press enter.

localhost login: root
[root@localhost~]#

The first task is to set a password for the root user.

[root@localhost~]# passwd
Changing password for user root.
New password: 
Retype new password:
passwd: all authentication tokens updated successfully
[root@localhost~]#

Verifying Network Connectivity

To verify the network connectivity, the checklist in the Fedora IoT Getting Started guide was followed. This system is using a wired ethernet connection, which shows as eth0. If you need to set up a wireless connection this can be done with nmcli.

ip addr will allow you to check that you have a valid IP address.

[root@localhost ~]# ip addr
1: lo: <LOOPBACK,UP,LOWER_UP> mtu 65536 qdisc noqueue state UNKNOWN group default qlen 1000
link/loopback 00:00:00:00:00:00 brd 00:00:00:00:00:00
inet 127.0.0.1/8 scope host lo
valid_lft forever preferred_lft forever
inet6 ::1/128 scope host
valid_lft forever preferred_lft forever
2: eth0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc fq_codel state UP group default qlen 1000
link/ether b8:27:eb:9d:6e:13 brd ff:ff:ff:ff:ff:ff
inet 192.168.178.60/24 brd 192.168.178.255 scope global dynamic noprefixroute eth0
valid_lft 863928sec preferred_lft 863928sec
inet6 fe80::ba27:ebff:fe9d:6e13/64 scope link
valid_lft forever preferred_lft forever
3: wlan0: <NO-CARRIER,BROADCAST,MULTICAST,UP> mtu 1500 qdisc fq_codel state DOWN group default qlen 1000
link/ether fe:d3:c9:dc:54:25 brd ff:ff:ff:ff:ff:ff

ip route will check that the network has a default gateway configured.

[root@localhost ~]# ip route
default via 192.168.178.1 dev eth0 proto dhcp metric 100 
192.168.178.0/24 dev eth0 proto kernel scope link src 192.168.178.60 metric 100 

To verify internet access and name resolution, use ping

[root@localhost ~]# ping -c3 iot.fedoraproject.org
PING wildcard.fedoraproject.org (8.43.85.67) 56(84) bytes of data.
64 bytes from proxy14.fedoraproject.org (8.43.85.67): icmp_seq=1 ttl=46 time=93.4 ms
64 bytes from proxy14.fedoraproject.org (8.43.85.67): icmp_seq=2 ttl=46 time=90.0 ms
64 bytes from proxy14.fedoraproject.org (8.43.85.67): icmp_seq=3 ttl=46 time=91.3 ms

--- wildcard.fedoraproject.org ping statistics ---
3 packets transmitted, 3 received, 0% packet loss, time 2003ms
rtt min/avg/max/mdev = 90.043/91.573/93.377/1.374 ms

Optional: Configuring sshd so we can disconnect the keyboard and monitor

Before disconnecting the keyboard and monitor, we need to ensure that we can connect to the Raspberry Pi over the network.

First we verify that sshd is running

[root@localhost~]# systemctl is-active sshd
active

and that there is a firewall rule present to allow ssh.

[root@localhost ~]# firewall-cmd --list-all
public (active)
  target: default
  icmp-block-inversion: no
  interfaces: eth0
  sources: 
  services: dhcpv6-client mdns ssh
  ports: 
  protocols: 
  masquerade: no
  forward-ports: 
  source-ports: 
  icmp-blocks: 
  rich rules: 

In the file /etc/ssh/sshd_config, find the section named

# Authentication

and add the line

PermitRootLogin yes

There will already be a line

#PermitRootLogin prohibit-password

which you can edit by removing the # comment character and changing the value to yes.

Restart the sshd service to pick up the change

[root@localhost ~]# systemctl restart sshd

If all this is in place, we should be able to ssh to the Raspberry Pi.

[gavin@desktop ~]$ ssh root@192.168.178.60
The authenticity of host '192.168.178.60 (192.168.178.60)' can't be established.
ECDSA key fingerprint is SHA256:DLdFaYbvKhB6DG2lKmJxqY2mbrbX5HDRptzWMiAUgBM.
Are you sure you want to continue connecting (yes/no/[fingerprint])? yes
Warning: Permanently added '192.168.178.60' (ECDSA) to the list of known hosts.
root@192.168.178.60's password: 
Boot Status is GREEN - Health Check SUCCESS
Last login: Wed Apr  1 17:24:50 2020
[root@localhost ~]#

It’s now safe to log out from the console (exit) and disconnect the keyboard and monitor.

Disabling unneeded services

Since we’re right on the lower limit of viable hardware for Rosetta@home, it’s worth disabling any unneeded services. Fedora IoT is much more lightweight than desktop distributions, but there are still a few optimizations we can do.

Like disabling bluetooth, Modem Manager (used for cellular data connections), WPA supplicant (used for Wi-Fi) and the zezere services, which are used to centrally manage a fleet of Fedora IoT devices.

[root@localhost /]# for serviceName in bluetooth ModemManager wpa_supplicant zezere_ignition zezere_ignition.timer zezere_ignition_banner; do 
   sudo systemctl stop $serviceName; 
   sudo systemctl disable $serviceName; 
   sudo systemctl mask $serviceName; 
   done

Getting the BOINC client

Instead of installing the BOINC client directly onto the operating system with rpm-ostree, we’re going to use podman to run the containerized version of the client.

This image uses a volume mount to store its data, so we create the directories it needs in advance.

[root@localhost ~]# mkdir -p /opt/appdata/boinc/slots /opt/appdata/boinc/locale

We also need to add a firewall rule to allow the container to resolve external DNS names.

[root@localhost ~]# firewall-cmd --permanent --zone=trusted --add-interface=cni-podman0 success [root@localhost ~]# systemctl restart firewalld

Finally we are ready to pull and run the BOINC client container.

[root@localhost ~]# podman run --name boinc -dt -p 31416:31416 -v /opt/appdata/boinc:/var/lib/boinc:Z -e BOINC_GUI_RPC_PASSWORD="blah"  -e BOINC_CMD_LINE_OPTIONS="--allow_remote_gui_rpc"  boinc/client:arm64v8 
Trying to pull...
...
...

787a26c34206e75449a7767c4ad0dd452ec25a501f719c2e63485479f...

We can inspect the container logs to make sure everything is working as expected:

[root@localhost ~]# podman logs boinc
20-Jun-2020 09:02:44 [---] cc_config.xml not found - using defaults
20-Jun-2020 09:02:44 [---] Starting BOINC client version 7.14.12 for aarch64-unknown-linux-gnu
...
...
...
20-Jun-2020 09:02:44 [---] Checking presence of 0 project files
20-Jun-2020 09:02:44 [---] This computer is not attached to any projects
20-Jun-2020 09:02:44 Initialization completed

Configuring the BOINC container to run at startup

We can automatically generate a systemd unit file for the container with podman generate systemd.

[root@localhost ~]# podman generate systemd --files --name boinc
/root/container-boinc.service

This creates a systemd unit file in root’s home directory.

[root@localhost ~]# cat container-boinc.service 
# container-boinc.service
# autogenerated by Podman 1.9.3
# Sat Jun 20 09:13:58 UTC 2020

[Unit]
Description=Podman container-boinc.service
Documentation=man:podman-generate-systemd(1)
Wants=network.target
After=network-online.target

[Service]
Environment=PODMAN_SYSTEMD_UNIT=%n
Restart=on-failure
ExecStart=/usr/bin/podman start boinc
ExecStop=/usr/bin/podman stop -t 10 boinc
PIDFile=/var/run/containers/storage/overlay-containers/787a26c34206e75449a7767c4ad0dd452ec25a501f719c2e63485479fbe21631/userdata/conmon.pid
KillMode=none
Type=forking

[Install]
WantedBy=multi-user.target default.target

We install the file by moving it to the appropriate directory.

[root@localhost ~]# mv -Z container-boinc.service  /etc/systemd/system
[root@localhost ~]# systemctl enable /etc/systemd/system/container-boinc.service
Created symlink /etc/systemd/system/multi-user.target.wants/container-boinc.service → /etc/systemd/system/container-boinc.service.
Created symlink /etc/systemd/system/default.target.wants/container-boinc.service → /etc/systemd/system/container-boinc.service.

Connecting to the Rosetta Stone project

You need to create an account at the Rosetta@home signup page, and retrieve your account key from your account home page. The key to copy is the “Weak Account Key”.

Finally, we execute the boinccmd configuration utility inside the container using podman exec, passing the Rosetta@home url and our account key.

[root@localhost ~]# podman exec boinc boinccmd --project_attach https://boinc.bakerlab.org/rosetta/ 2160739_cadd20314e4ef804f1d95ce2862c8f73

Running podman logs –follow boinc will allow us to see the container connecting to the project. You will probably see errors of the form

20-Jun-2020 10:18:40 [Rosetta@home] Rosetta needs 1716.61 MB RAM but only 845.11 MB is available for use.

This is because most, but not all, of the work units in Rosetta@Home require more memory than we have to offer. However, if you leave the device running for a while, it should eventually get some jobs to process. The polling interval seems to be approximately 10 minutes. We can also tweak the memory settings using BOINC manager to allow BOINC to use slightly more memory. This will increase the probability that Rosetta@home will be able to find tasks for us.

Installing BOINC Manager for remote access

You can use dnf to install the BOINC manager component to remotely manage the BOINC client on the Raspberry Pi.

[gavin@desktop ~]$ sudo dnf install boinc-manager

If you switch to “Advanced View” , you will be able to select “File -> Select Computer” and connect to your Raspberry Pi, using the IP address of the Pi and the value supplied for BOINC_GUI_RPC_PASSWORD in the podman run command, in my case “blah“.

Under “Options -> Computing Preferences”, increase the value for “When Computer is not in use, use at most _ %”. I’ve been using 93%; this seems to allow Rosetta@home to schedule work on the pi, whilst still leaving it just about usable. It is possible that further fine tuning of the operating system might allow this percentage to be increased.

These settings can also be changed through the Rosetta@home website settings page, but bear in mind that changes made through the BOINC Manager client override preferences set in the web interface.

Wait

It may take a while, possibly several hours, for Rosetta@home to send work to our newly installed client, particularly as most work units are too big to run on a Raspberry Pi. COVID-19 has resulted in a large number of new computers being joined to the Rosetta@home project, which means that there are times when there isn’t enough work to do.

When we are assigned some work units, BOINC will download several hundred megabytes of data. This will be stored on the SD Card and can be viewed using BOINC manager.

We can also see the tasks running in the Tasks pane:

The client has downloaded four tasks, but only one of them is currently running due to memory constraints. At times, two tasks can run simultaneously, but I haven’t seen more than that. This is OK as long as the tasks are completed by the deadline shown on the right. I’m fairly confident these will be completed as long as the Raspberry Pi is left running. I have found that the additional memory overhead created by the BOINC Manager connection and sshd services can reduce parallelism, so I try to disconnect these when I’m not using them.

Conclusion

Rosetta@home, in common with many other distributed computing projects, is currently experiencing a large spike in participation due to COVID-19. That aside, the project has been doing valuable work for many years to combat a number of other diseases.

Whilst a Raspberry Pi is never going to appear at the top of the contribution chart, I think this is a worthwhile project to undertake with a spare Raspberry Pi. The existence of work units aimed at low-spec ARM devices indicates that the project organizers agree with this sentiment. I’ll certainly be leaving mine running for the foreseeable future.