When recording sounds on a laptop — say for a simple first screencast — many users typically use the built-in microphone. However, these small microphones also capture a lot of background noise. In this quick tip, learn how to use Audacity in Fedora to quickly remove the background noise from audio files.

Installing Audacity

Audacity is an application in Fedora for mixing, cutting, and editing audio files. It supports a wide range of formats out of the box on Fedora — including MP3 and OGG. Install Audacity from the Software application.

If the terminal is more your speed, use the command:

sudo dnf install audacity

Import your Audio, sample background noise

After installing Audacity, open the application, and import your sound using the File > Import menu item. This example uses a sound bite from freesound.org to which noise was added:

Next, take a sample of the background noise to be filtered out. With the tracks imported, select an area of the track that contains only the background noise. Then choose Effect >  Noise Reduction from the menu, and press the Get Noise Profile button.

Filter the Noise

Next, select the area of the track you want to filter the noise from. Do this either by selecting with the mouse, or Ctrl + a to select the entire track. Finally, open the Effect > Noise Reduction dialog again, and click OK to apply the filter.

Additionally, play around with the settings until your tracks sound better. Here is the original file again, followed by the noise reduced track for comparison (using the default settings):

NoSQL databases are every bit as popular today as more conventional, relational ones. One of the most popular NoSQL systems is Apache Cassandra. It’s designed to deal with big data, and can be scaled across large numbers of servers. This makes it resilient and highly available.

This package is relatively new on Fedora, since it was introduced on Fedora 26. The following article is a short tutorial to set up Cassandra on Fedora for a development environment. Production deployments should use a different set-up to harden the service.

Install and configure Cassandra

The set of database packages in Fedora’s stable repositories are the client tools in the cassandra package. The common library is in the cassandra-java-libs package (required by both client and server). The most important part of the database, the daemon, is available in the cassandra-server package. Some more supporting packages may be listed by running the following command in a terminal.

dnf list cassandra\*

First, install and start the service:

$ sudo dnf install cassandra cassandra-server
$ sudo systemctl start cassandra

To enable the service to automatically start at boot time, run:

$ sudo systemctl enable cassandra

Finally, test the server initialization using the client:

$ cqlsh
Connected to Test Cluster at 127.0.0.1:9042.
[cqlsh 5.0.1 | Cassandra 3.11.1 | CQL spec 3.4.4 | Native protocol v4]
Use HELP for help.
cqlsh> CREATE KEYSPACE k1 WITH REPLICATION = { 'class' : 'SimpleStrategy', 'replication_factor' : 1 };
cqlsh> USE k1;
cqlsh:k1> CREATE TABLE users (user_name varchar, password varchar, gender varchar, PRIMARY KEY (user_name));
cqlsh:k1> INSERT INTO users (user_name, password, gender) VALUES ('John', 'test123', 'male');
cqlsh:k1> SELECT * from users;

 user_name | gender | password
-----------+--------+----------
      John |   male |  test123

(1 rows)

To configure the server, edit the file /etc/cassandra/cassandra.yaml. For more information about how to change configuration, see the the upstream documentation.

Controlling access with users and passwords

By default, authentication is disabled. To enable it, follow these steps:

1. By default, the authenticator option is set to AllowAllAuthenticator. Change the authenticator option in the cassandra.yaml file to PasswordAuthenticator:

authenticator: PasswordAuthenticator

2. Restart the service.

$ sudo systemctl restart cassandra

3. Start cqlsh using the default superuser name and password:

$ cqlsh -u cassandra -p cassandra

4. Create a new superuser:

cqlsh> CREATE ROLE <new_super_user> WITH PASSWORD = '<some_secure_password>' 
    AND SUPERUSER = true 
    AND LOGIN = true;

5. Log in as the newly created superuser:

$ cqlsh -u <new_super_user> -p <some_secure_password>

6. The superuser cannot be deleted. To neutralize the account, change the password to something long and incomprehensible, and alter the user’s status to NOSUPERUSER:

cqlsh> ALTER ROLE cassandra WITH PASSWORD='SomeNonsenseThatNoOneWillThinkOf'
    AND SUPERUSER=false;

Enabling remote access to the server

Edit the /etc/cassandra/cassandra.yaml file, and change the following parameters:

listen_address: external_ip
rpc_address: external_ip
seed_provider/seeds: "<external_ip>"

Then restart the service:

$ sudo systemctl restart cassandra

Other common configuration

There are quite a few more common configuration parameters. For instance, to set the cluster name, which must be consistent for all nodes in the cluster:

cluster_name: 'Test Cluster'

The data_file_directories option sets the directory where the service will write data. Below is the default that is used if unset. If possible, set this to a disk used only for storing Cassandra data.

data_file_directories:
    - /var/lib/cassandra/data

To set the type of disk used to store data (SSD or spinning):

disk_optimization_strategy: ssd|spinning

Running a Cassandra cluster

One of the main features of Cassandra is the ability to run in a multi-node setup. A cluster setup brings the following benefits:

• Fault tolerance: Automatically replicates data to multiple nodes for fault-tolerance. Also, it supports replication across multiple data centers. You can replace failed nodes with no downtime.
• Decentralization: There are no single points of failure, no network bottlenecks, and every node in the cluster is identical.
• Scalability & elasticity: Can run thousands of nodes with petabytes of data. Read and write throughput both increase linearly as new machines are added, with no downtime or interruption to applications.

The following sections describe how to setup a simple two-node cluster.

Clearing existing data

First, if the server is running now or has ever run before, you must delete all the existing data (make a backup first). This is because all nodes must have the same cluster name and it’s better to choose a different one from the default Test cluster name.

Run the following commands on each node:

$ sudo systemctl stop cassandra
$ sudo rm -rf /var/lib/cassandra/data/system/*

If you deploy a large cluster, you can do this via automation using Ansible.

Configuring the cluster

To setup the cluster, edit the main configuration file /etc/cassandra/cassandra.yaml. Modify these parameters:

• cluster_name: Name of your cluster.
• num_tokens: Number of virtual nodes within a Cassandra instance. This option partitions the data and spreads the data throughout the cluster. The recommended value is 256.
• seeds: Comma-delimited list of the IP address of each node in the cluster.
• listen_address: The IP address or hostname the service binds to for connecting to other nodes. It defaults to localhost and needs to be changed to the IP address of the node.
• rpc_address: The listen address for client connections (CQL protocol).
• endpoint_snitch: Set to a class that implements the IEndpointSnitch. Cassandra uses snitches to locate nodes and route requests. The default is SimpleSnitch, but for this exercise, change it to GossipingPropertyFileSnitch which is more suitable for production environments:
  • SimpleSnitch: Used for single-datacenter deployments or single-zone in public clouds. Does not recognize datacenter or rack information. It treats strategy order as proximity, which can improve cache locality when disabling read repair.
  • GossipingPropertyFileSnitch: Recommended for production. The rack and datacenter for the local node are defined in the cassandra-rackdc.properties file and propagate to other nodes via gossip.
• auto_bootstrap: This parameter is not present in the configuration file, so add it and set to false. It makes new (non-seed) nodes automatically migrate the right data to themselves.

Configuration files for a two-node cluster follow.

Node 1:

cluster_name: 'My Cluster'
num_tokens: 256
seed_provider:
    - class_name: org.apache.cassandra.locator.SimpleSeedProvider
        - seeds: 10.0.0.1, 10.0.0.2
listen_address: 10.0.0.1
rpc_address: 10.0.0.1
endpoint_snitch: GossipingPropertyFileSnitch
auto_bootstrap: false

Node 2:

cluster_name: 'My Cluster'
num_tokens: 256
seed_provider:
    - class_name: org.apache.cassandra.locator.SimpleSeedProvider
        - seeds: 10.0.0.1, 10.0.0.2
listen_address: 10.0.0.2
rpc_address: 10.0.0.2
endpoint_snitch: GossipingPropertyFileSnitch
auto_bootstrap: false

Starting the cluster

The final step is to start each instance of the cluster. Start the seed instances first, then the remaining nodes.

$ sudo systemctl start cassandra

Checking the cluster status

In conclusion, you can check the cluster status with the nodetool utility:

$ sudo nodetool status

Datacenter: datacenter1
===============
Status=Up/Down
|/ State=Normal/Leaving/Joining/Moving
--  Address      Load       Tokens       Owns    Host ID                               Rack
UN  10.0.0.2  147.48 KB  256          ?       f50799ee-8589-4eb8-a0c8-241cd254e424  rack1
UN  10.0.0.1  139.04 KB  256          ?       54b16af1-ad0a-4288-b34e-cacab39caeec  rack1
 
Note: Non-system keyspaces don't have the same replication settings, effective ownership information is meaningless

Cassandra in a container

Linux containers are becoming more popular. You can find a Cassandra container image here on DockerHub:

centos/cassandra-3-centos7

It’s easy to start a container for this purpose without touching the rest of the system. First, install and run the Docker daemon:

$ sudo dnf install docker
$ sudo systemctl start docker

Next, pull the image:

$ sudo docker pull centos/cassandra-3-centos7

Now prepare a directory for data:

$ sudo mkdir data
$ sudo chown 143:143 data

Finally, start the container with a few arguments. The container uses the prepared directory to store data into and creates a user and database.

$ docker run --name cassandra -d -e CASSANDRA_ADMIN_PASSWORD=secret -p 9042:9042 -v `pwd`/data:/var/opt/rh/sclo-cassandra3/lib/cassandra:Z centos/cassandra-3-centos7

Now you have the service running in a container while storing data into the data directory in the current working directory. If the cqlsh client is not installed on your host system, run the one provided by the image with the following command:

$ docker exec -it cassandra 'bash' -c 'cqlsh '`docker inspect -f '{{range .NetworkSettings.Networks}}{{.IPAddress}}{{end}}' cassandra`' -u admin -p secret'

Conclusion

The Cassandra maintainers in Fedora seek co-maintainers to help keep the package fresh on Fedora. If you’d like to help, simply send them email.

Photo by Glen Jackson on Unsplash.

A critical security vulnerability was discovered and disclosed earlier today in dhcp-client. This DHCP flaw carries a high risk to your system and data, especially if you use untrusted networks such as a WiFi access point you don’t own. Read more here for how to protect your Fedora system.

Dynamic Host Control Protocol (DHCP) allows your system to get configuration from a network it joins. Your system will make a request for DHCP data, and typically a server such as a router answers. The server provides the necessary data for your system to configure itself. This is how, for instance, your system configures itself properly for networking when it joins a wireless network.

However, an attacker on the local network may be able to exploit this vulnerability. Using a flaw in a dhcp-client script that runs under NetworkManager, the attacker may be able to run arbitrary commands with root privileges on your system. This DHCP flaw puts your system and your data at high risk. The flaw has been assigned CVE-2018-1111 and has a Bugzilla tracking bug.

Guarding against this DHCP flaw

New dhcp packages contain fixes for Fedora 26, 27, and 28, as well as Rawhide. The maintainers have submitted these updates to the updates-testing repositories. They should show up in stable repos within a day or so of this post for most users. The desired packages are:

• Fedora 26: dhcp-4.3.5-11.fc26
• Fedora 27: dhcp-4.3.6-10.fc27
• Fedora 28: dhcp-4.3.6-20.fc28
• Rawhide: dhcp-4.3.6-21.fc29

Updating a stable Fedora system

To update immediately on a stable Fedora release, use this command with sudo. Type your password at the prompt, if necessary:

sudo dnf --refresh --enablerepo=updates-testing update dhcp-client

Later, use the standard stable repos to update. To update your Fedora system from the stable repos, use this command:

sudo dnf --refresh update dhcp-client

Updating a Rawhide system

If your system is on Rawhide, use these commands to download and update the packages immediately:

mkdir dhcp && cd dhcp
koji download-build --arch={x86_64,noarch} dhcp-4.3.6-21.fc29
sudo dnf update ./dhcp-*.rpm

After the nightly Rawhide compose, simply run sudo dnf update to get the update.

Fedora Atomic Host

The fixes for Fedora Atomic Host are in ostree version 28.20180515.1. To get the update, run this command:

atomic host upgrade -r

This command reboots your system to apply the upgrade.

Photo by Markus Spiske on Unsplash.

Smart card support was introduced around 2010 with OpenSSH 5.4. The inital scope was restricted to the RSA keys — the only supported key type at that time in OpenSSH — other than legacy DSA keys. Previously, users needed to specify the PKCS#11 driver for the smart card. Additionally, the OpenSSH client had to query the server with all the stored keys in the card, until an acceptable key was found.  This slowed down authentication, and reveals public keys to the server that might not be necessary (e.g., if we have a single card with keys for distinct servers).

Over the years, OpenSSH gained support for additional authentication keys, such as ECDSA and later EdDSA. However, the smart card subsystem has not changed much since the early days. Cards with ECDSA keys are not yet supported, and there is no option for the user to specify the key to use when connecting to a server. Fedora 28 addresses these limitations. This article describes these improvements, the background behind them, and how they can be used.

Support for ECDSA keys

OpenSSH has supported ECDSA keys OpenSSH 5.7 (released in 2011). This  includes widespread support for smart cards such as Yubikey and Nitrokey. Nevertheless, ECDSA support was not reflected in the OpenSSH PKCS#11 subsystem, which is still RSA-only. A patch to support the ECDSA keys in PKCS#11 was submitted to the OpenSSH project in 2015, but despite a long history of revisions it is still not incorporated. The motivation to use ECDSA keys can be either to avoid hardware RSA key vulnerabilities (ROCA: CVE-2017-15361) or to use shorter keys for faster connection times.

In Fedora 28 we include that patch set to allow you to use ECDSA keys from your security tokens. You can list them with ssh-keygen as any other keys:

$ ssh-keygen -D /usr/lib64/pkcs11/opensc-pkcs11.so
[...]
ecdsa-sha2-nistp256 AAAAE2VjZHNhLXNoYTItbmlzdHA[...]k3J0hkYnnsM=

Or use them for authentication, if the server is configured to accept this key:

$ ssh -vvv -I /usr/lib64/pkcs11/opensc-pkcs11.so example.com
[...]
debug1: Offering public key: ECDSA SHA256:5BrE5wevULd5wipj2bXYAr4gXQIICiywfV+kF5hA9X8 ECDSA jjelen@example.com
[...]
debug1: Offering public key: ECDSA SHA256:q4zxb5Woucr1HlUSh9Fq66sKdv3r5hlxIIqQQtaQKy4 pkcs11:id=%01?module-path=/usr/lib64/pkcs11/opensc-pkcs11.so
[...]
debug1: Server accepts key: pkalg ecdsa-sha2-nistp256 blen 104
debug2: input_userauth_pk_ok: fp SHA256:q4zxb5Woucr1HlUSh9Fq66sKdv3r5hlxIIqQQtaQKy4
debug3: sign_and_send_pubkey: ECDSA SHA256:q4zxb5Woucr1HlUSh9Fq66sKdv3r5hlxIIqQQtaQKy4
Enter PIN for 'PIV Card Holder pin (PIV_II)': 
[...]
debug1: Authentication succeeded (publickey).

Specify the key to use

Historically, applications were using various ways how to reference keys in PKCS#11 modules, because there was no standard way to do so. Alternatively some applications were using just everything that was made available by a PKCS#11 module.

This works fine if the smart card is a company-issued with few keys. But this does not work well if one has several private keys to access different services or there are more security tokens aggregated in a single system-wide PKCS#11 module. In such cases, you need to map private keys to services, rather than to leave it on the tool to try all of them sequentially. Selecting an explicit key will always be faster, and prevents exceeding maximum of authentication tries. Furthermore, it allows to the use of different identities, for example on Github.

PKCS#11 URIs defined in RFC7512 provide a standard way to identify a specific object/key on PKCS#11 module according to their attributes. That, when supported universally, enables you to configure all the system and applications with the same configuration string in form of URI.

Additionally, as Fedora 28 provides p11-kit proxy which acts as a wrapper over the registered smart card drivers in the system,  we took advantage of it and it allows you to avoid the path to shared object altogether. The unique URI scheme allows you to specify the PKCS#11 URI in every place, where the path to a local private key file would be, including the configuration file, ssh-add or command-line ssh.

Examples

You can list all the keys provided by OpenSC PKCS#11 module (including their PKCS#11 URIs):

$ ssh-keygen -D /usr/lib64/pkcs11/opensc-pkcs11.so
ssh-rsa AAAAB3NzaC1yc2E...KKZMzcQZzx pkcs11:id=%02;object=SIGN%20pubkey;token=SSH%20key;manufacturer=piv_II?module-path=/usr/lib64/pkcs11/opensc-pkcs11.so
ecdsa-sha2-nistp256 AAA...J0hkYnnsM= pkcs11:id=%01;object=PIV%20AUTH%20pubkey;token=SSH%20key;manufacturer=piv_II?module-path=/usr/lib64/pkcs11/opensc-pkcs11.so

To connect to the server example.com using the ECDSA key from above (referenced by ID), you can use just a subset of the URI, which uniquely references our key:

$ ssh -i pkcs11:id=%01?module-path=/usr/lib64/pkcs11/opensc-pkcs11.so example.com
Enter PIN for 'SSH key':
[example.com] $

You can use the same URI string in ~/.ssh/config to make the configuration permanent:

$ cat ~/.ssh/config
IdentityFile pkcs11:id=%01?module-path=/usr/lib64/pkcs11/opensc-pkcs11.so
$ ssh example.com
Enter PIN for 'SSH key':
[example.com] $

Since the OpenSC PKCS#11 module is registered by default to p11-kit in Fedora, which is via p11-kit-proxy, used by OpenSSH, you can simplify the above commands:

$ ssh -i pkcs11:id=%01 example.com
Enter PIN for 'SSH key':
[example.com] $

The ssh-agent interface accepts the same URIs. For example, you can add only the ECDSA key to the agent and connect to example.com (this was not previously possible):

$ ssh-add pkcs11:id=%01
Enter passphrase for PKCS#11: 
Card added: pkcs11:id=%01
$ ssh example.com
[example.com] $

If you skip the ID, OpenSSH will load all the keys that are available in the proxy module, which usually matches the previous behavior, but is much less typing:

$ ssh -i pkcs11: example.com
Enter PIN for 'SSH key':
[example.com] $

Known issues

While the smart cards work generally fine, there are some corner cases, that are not handled ideally yet. Most of them are tracked upstream bugzilla.

From the most painful ones, we can note that the keys stored in ssh-agent do not support reauthentication. Therefore once you physically remove the token, you also need to remove and re-add it in the ssh-agent. Its interface does not provide a functionality to this automatically, so there is still some work to be done.

The ssh-agent also does not allow you to use keys that require PIN verification before signature (ALWAYS_AUTHENTICATE flag). This is very common in PIV cards to ensure non-repudiation of digital signatures. In this case, the easy workaround is to use different key, that does not enforce this policy.

Summary

The new OpenSSH comes with few improvements for private keys stored in smart cards and security tokens. These changes make the usage of security tokens easier for new users, allow them to take advantage of secure storage, in comparison to keys on disk. They also integrate OpenSSH into Fedora which already supports the RFC7512 identifiers for objects stored in tokens and uses p11-kit for smart card driver registration.

If you found an issue with the above functionality, or you have and idea what could be improved, feel free to comment, open a bug or start a discussion on Fedora or OpenSSH mailing lists.

The aforementioned features are available in Fedora, but not yet in the upstream OpenSSH releases. We include these changes in the hope they will be useful for users and it can make the upstream adoption of them faster.