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Quincy

Crates.io Documentation Build status codecov License: MIT Matrix

Quincy is a VPN client and server implementation using the QUIC protocol.

Design

Quincy uses the QUIC protocol implemented by quinn to create an encrypted tunnel between clients and the server.

This tunnel serves two purposes:

  • authentication using a reliable bi-directional stream
  • data transfer using unreliable datagrams (for lower latency and avoidance of multiple reliability layers)

After a connection is established and the client is authenticated, a TUN interface is spawned using an IP address provided by the server.

When all is set up, a connection task is spawned, which handles IO on the TUN interface and the QUIC connection, effectively relaying packets between them.

The tokio runtime is used to provide an efficient and scalable implementation.

Supported platforms

  • Windows (x86_64), using Wintun
  • Linux (x86_64, aarch64)
  • FreeBSD (x86_64, aarch64)
  • MacOS (aarch64)

Installation

Binaries are currently available for Windows, Linux (x86_64) and macOS (aarch64) for every official release.

Using cargo, installation of any published version can be done with a simple command:

cargo install quincy

Building from sources

As Quincy does not rely upon any non-Rust libraries, the build process is incredibly simple:

cargo build

If you additionally want to build Quincy in release mode with optimizations, add the --release switch:

cargo build --release

The resulting binaries can be found in the target/debug and target/release directories.

Quincy can optionally use the jemalloc memory allocator for slightly improved performance. To enable it, add the --features jemalloc switch to the build/install command:

cargo build --release --features jemalloc

Usage

Quincy is split into 3 binaries:

  • quincy-client: The VPN client
  • quincy-server: The VPN server
  • quincy-users: A utility binary meant for managing the users file

Client

The Quincy client requires a separate configuration file, an example of which can be found in examples/client.toml. The documentation for the client configuration file fields can be found here.

With the configuration file in place, the client can be started using the following command:

quincy-client --config-path examples/client.toml

Routes are set by default to the address and netmask received from the server. Any additional routes now have to be set up manually.

Server

The Quincy server requires a separate configuration file, an example of which can be found in examples/server.toml. The documentation for the server configuration file fields can be found here.

With the configuration file in place, the client can be started using the following command:

quincy-server --config-path examples/server.toml

Please keep in mind that the pre-generated certificate in examples/cert/server_cert.pem is self-signed and uses the hostname quincy. It should be replaced with a proper certificate, which can be generated using the instructions in the Certificate management section.

Users

The users utility can be used to manage entries in the users file. The users file contains usernames and password hashes in a format similar to /etc/shadow (example can be found in examples/users).

The following command can be used to add users to this file:

quincy-users --add examples/users

The prompts will look something like this:

Enter the username: test
Enter password for user 'test':
Confirm password for user 'test':

A similar command can be used to remove users from the file:

quincy-users --remove examples/users

The prompt will again look something like this:

Enter the username: test

Certificate management

There are a couple of options when it comes to setting up the certificates used by Quincy.

Certificate signed by a trusted CA

This is the proper way to manage certificates with Quincy.

You can either request/pay for a certificate from a service with a globally trusted CA (Let's Encrypt, GoDaddy, ...) or generate your own certificate authority and then sign an end-point certificate.

If you have a certificate signed by a globally trusted CA, you can simply add it to the server configuration file and run Quincy. The client will trust the certificate, as the signing certificate is most likely in the system's trusted root certificate store.

If you have a certificate signed by your own (self-signed) CA, follow the steps above and additionally add your CA certificate to the client configuration file.

You can use mkcert for generating your own CA certificate and using it to sign an end-point certificate.

Self-signed certificate

This is an easier set up that might be used by home-lab administrators or for local testing.

The steps to generate a self-signed certificate that can be used with Quincy:

  1. Generate a private key (I use ECC for my certificates, but RSA is fine)
openssl genpkey -algorithm EC -pkeyopt ec_paramgen_curve:secp384r1 -out <your_certificate_key_file>
  1. Generate a certificate request
openssl req -new -key <your_certificate_key_file> -out <your_certificate_request_file>
You are about to be asked to enter information that will be incorporated
into your certificate request.
What you are about to enter is what is called a Distinguished Name or a DN.
There are quite a few fields but you can leave some blank
For some fields there will be a default value,
If you enter '.', the field will be left blank.
-----
Country Name (2 letter code) [AU]:XX
State or Province Name (full name) [Some-State]:.
Locality Name (eg, city) []:.
Organization Name (eg, company) [Internet Widgits Pty Ltd]:.
Organizational Unit Name (eg, section) []:.
Common Name (e.g. server FQDN or YOUR name) []:quincy
Email Address []:

Please enter the following 'extra' attributes
to be sent with your certificate request
A challenge password []:
An optional company name []:
  1. Create a v3 extensions configuration file with the following content (fill out the subjectAltName field with the hostname/IP the clients will be connecting to)
subjectKeyIdentifier   = hash
authorityKeyIdentifier = keyid:always,issuer:always
basicConstraints       = CA:FALSE
keyUsage               = digitalSignature, nonRepudiation, keyEncipherment, dataEncipherment, keyAgreement, keyCertSign
subjectAltName         = DNS:quincy
issuerAltName          = issuer:copy
  1. Sign your certificate
openssl x509 -req -in cert.csr -signkey <your_certificate_key_file> -out <your_certificate_file> -days 365 -sha256 -extfile <your_v3_ext_file>
  1. Add the certificate to both your server and client configuration files.

Server

# Path to the certificate used for TLS
certificate_file = "server_cert.pem"
# Path to the certificate key used for TLS
certificate_key_file = "server_key.pem"

Client

[authentication]
# A list of trusted certificates the server can use or have its certificate signed by
trusted_certificates = ["server_cert.pem"]