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config.toml
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@ -90,11 +90,11 @@ logoText = "Hello there!"
logoHomeLink = "/fr/"
[menu]
# [[menu.main]]
# identifier = "blog"
# name = "Blog"
# url = "/posts"
# weight = 1
[[menu.main]]
identifier = "blog"
name = "Blog"
url = "/posts"
weight = 1
[[menu.main]]
identifier = "about_me"

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---
title: "How to do HTTPS at home (when your infrastructure is private)"
date: 2024-07-02T21:00:50+02:00
draft: true
toc: true
images:
tags:
- self-hosting
- sysadmin
---
## The problem of having a self-hosted infrastructure
I've been maintaining a personal homelab and self-hosted infrastructure for a few years
now, but one of the most infuriating pages when starting such project is this dreaded
**Warning: Potential Security Risk Ahead** page that appears when you're using a
self-hosted certificate, or when trying to use a password on a website or app that is
served through plain HTTP.
![A screenshot of a warning from Firefox indicating that the website that is being accessed is not secure.](/images/dns_article_firefox_warning.png)
While acceptable if you're alone on your own infrastructure or dev environment, this
poses several issues if many other contexts:
- It is not acceptable to publicly expose a website presenting this issue
- It's not advisable to say "hey look, I know that your browser gives you a big red
warning, but it's okay, you can just accept" to friends/family/etc. It's just a very
bad habit to have
- After a while, it really starts to get on your nerve
Thankfully a free solution for that, which you will probably know already, has existed
for almost ten (10) years now: [Let's Encrypt and the ACME protocol](https://letsencrypt.org/)
{{< callout type="note" >}}
I promise this is not yet another Let's Encrypt tutorial, well it is, but for a more
specific use-case
{{< /callout >}}
## The Let's Encrypt solution
### What is Let's Encrypt
[Let's Encrypt](https://letsencrypt.org/) is a nonprofit certificate authority founded
in November 2014. Its main goal was to provide an easy and free way to obtain a TLS
certificate in order to make it easy to use HTTPS everywhere.
The [ACME protocol](https://letsencrypt.org/docs/client-options/) developed by Let's
Encrypt is an automated verification system aiming at doing the following:
- verifying that you own the domain for which you want a certificate
- creating and registering that certificate
- delivering the certificate to you
Most client implementation also have an automated renewal system, further reducing the
workload for sysadmins.
The current specification for the ACME protocol proposes two (2) types of challenges
to prove ownership and control over a domain: [HTTP-01](https://letsencrypt.org/docs/challenge-types/#http-01-challenge) and [DNS-01](https://letsencrypt.org/docs/challenge-types/#dns-01-challenge) challenge.
{{< callout type="note" >}}
Actually there are two (2) others: [TLS-SNI-01](https://letsencrypt.org/docs/challenge-types/#tls-sni-01) which is now disabled, and [TLS-ALPN-01](https://letsencrypt.org/docs/challenge-types/#tls-alpn-01) which is only aimed at a very
specific category of users, which we will ignore here.
{{< /callout >}}
### The common solution: HTTP challenge
The [HTTP-01](https://letsencrypt.org/docs/challenge-types/#http-01-challenge) challenge
is the most common type of ACME challenge, and will satisfy most use-cases.
![A schema describing the HTTP challenge workflow for the ACME protocol and the interactions between the application server, Let's Encrypt, and the DNS server, all of them public.](/images/dns_article_http_challenge.svg)
For this challenge, you need the following elements :
- A domain name and a record for that domain in a public DNS server (it can be a self-hosted DNS server, your providers', etc)
- Access to a server with a public IP that can be publicly reached
When performing this type of challenge, the following happens (in a very simplified way):
1. Your ACME client will ask to start a challenge to the Let's Encrypt API
2. In return, it will get a token
3. It will then either start a standalone server, or edit the configuration for your
current web server (nginx, apache, etc) to serve a file containing the token and a fingerprint of your account key.
4. Let's Encrypt will try to resolve your domain `test.example.com`.
5. If resolution works, then it will check the url `http://test.example.com/.well-known/acme-challenge/<TOKEN>`, and verify that the file from step 3 is served with the correct
content.
If everything works as expected, then the ACME client can download the certificate and key, and you can configure your reverse proxy or server to use this valid certificate,
all is well.
{{< callout type="help" >}}
Okay, but my app contains my accounts, or my proxmox management interface, and I
don't really want to make it public, so how does it work here?
{{< /callout >}}
Well it doesn't. For this type of challenge to work, the application server **must** be
public. For this challenge you need to prove that you have control over the application
that uses the target domain (even if you don't control the domain itself). But the
DNS-01 challenge bypasses this limitation.
### When it's not enough: the DNS challenge
As we saw in the previous section, sometimes, for various reasons, your application
server is in a private zone. It must be only reachable from inside a private network,
but you still want to be able to use a free Let's Encrypt certificate.
For this purpose, the [DNS-01](https://letsencrypt.org/docs/challenge-types/#dns-01-challenge) challenge is based on proving that you have control over the **DNS
server** itself, instead of the application server.
![A schema describing the DNS challenge workflow for the ACME protocol and the interaction between Let's Encrypt, the public DNS server and the private application server](/images/dns_article_dns_challenge_1.svg)
For this type of challenge, the following elements are needed :
- A public DNS server you have control over (can be a self-hosted server, or your DNS provider)
- A ACME client (usually it would be on your application server), it doesn't need to be public
Then, the challenge is done the following way :
1. Your ACME client will ask to start a challenge to the Let's Encrypt API.
2. In return, it will get a token.
3. The client then created a `TXT` record at `_acme-challenge.test.example.com` derived from the token
and your account key.
4. Let's Encrypt will try to resolve the expected `TXT` record, and verify that the content is correct.
If the verification succeeds, you can download your certificate and key, just like the other
type of challenge.
It's important to note that **at no point in time did Let's Encrypt have access to the
application server itself**, because this challenges involves proving that you control
the domain, not that you control the destination of that domain.
As someone trying to use a valid certificate for my proxmox interface, this is the way I
would want to go, because it would allow me to have a valid certificate, despite my server
not being public at all. So let's see how it works in practice.
## DNS challenge in practice
For this example, I will try to obtain a certificate for my own domain
`example.internal.faercol.me`.As this name hints, it is an internal domain and should not
be publicly reachable, so this means I'm going to use a DNS challenge. I don't really want
to use my DNS provider API for this, so I'm going to use a self-hosted [bind](https://www.isc.org/bind/)
server for that.
### Configuring the DNS server
The first step is configuring the DNS server. For this, I'll just use a [bind](https://bind9.readthedocs.io/en/v9.18.27/)
server installed from my usual package manager.
```bash
# example on Debian 12
sudo apt install bind9
```
Most of the configuration happens in the `/etc/bind` directory, mostly in `/etc/bind/named.conf.local`
```text
root@dns-server: ls /etc/bind/
bind.keys db.127 db.empty named.conf named.conf.local rndc.key
db.0 db.255 db.local named.conf.default-zones named.conf.options zones.rfc1918
```
Let's declare a first zone, for `internal.example.com`. Add the following config to
`/etc/bind/named.conf.local`
```text
zone "internal.example.com." IN {
type master;
file "/var/lib/bind/internal.example.com.zone";
```
This simply declares a new zone which is described in the file `/var/lib/bind/internal.example.com.zone`
Let's now create the zone itself. A DNS zone has a base structure that you must follow
```dns
$ORIGIN .
$TTL 7200 ; 2 hours
internal.example.com IN SOA ns.internal.example.com. admin.example.com. (
2024070301 ; serial
3600 ; refresh (1 hour)
600 ; retry (10 minutes)
86400 ; expire (1 day)
600 ; minimum (10 minutes)
)
NS ns.internal.example.com.
$ORIGIN internal.example.com.
ns A 1.2.3.4
test A 192.168.1.2
```
This file declares a zone `internal.example.com` which master is `ns.internal.example.com`.
It also sets the parameters (time to live for the records, and the current serial for the
zone config).
Finally, two (2) A records are created, associating the name `ns.internal.example.com` to
the IP address `1.2.3.4`, and `test.internal.example.com` (the domain for which we want
a certificate) to a local IP address `192.168.1.2`.
A simple `systemctl restart bind9` would be enough to apply the modification, but we still
have one thing to do, which is allowing remote modifications to the zone.
### Enabling remote DNS zone modification
To allow remote modification of our DNS zone, we are going to use [TSIG](https://www.ibm.com/docs/en/aix/7.3?topic=ssw_aix_73/network/bind9_tsig.htm)
which stands for **Transaction signature**. It's a way to secure server to server operations
to edit a DNS zone, and is preferred to access control based on IP addresses.
Let's start with creating a key using the command `tsig-keygen <keyname>`
```shell
➜ tsig-keygen letsencrypt
key "letsencrypt" {
algorithm hmac-sha256;
secret "oK6SqKRvGNXHyNyIEy3hijQ1pclreZw4Vn5v+Q4rTLs=";
};
```
This creates a key with the given name using the default algorithm (which is `hmac-sha256`).
The entire output of this command is actually a code block that you can add to your bind9
configuration.
Finally, using `update-policy`, allow this key to be used to update the zone.
```text
update-policy {
grant letsencrypt. zonesub txt;
};
```
{{< callout type="note" >}}
Doing so allows users to update everything in your zone using this key. In fact
you would only need to update `_acme-challenge.test.internal.example.com` as seen
in the DNS challenge description.
If you want a better restriction, then you can use the following configuration instead
```text
update-policy {
grant letsencrypt. name _acme-challenge.test.internal.example.com. txt;
};
```
{{< /callout >}}
This means your entire `named.conf.local` would become something like this
```text
key "letsencrypt" {
algorithm hmac-sha256;
secret "oK6SqKRvGNXHyNyIEy3hijQ1pclreZw4Vn5v+Q4rTLs=";
};
zone "internal.example.com." IN {
type master;
file "/var/lib/bind/internal.example.com.zone";
update-policy {
grant letsencrypt. zonesub txt;
};
};
```
{{< callout type="warning" >}}
Be **very cautious** about the `.` at the end of the zone name and the key name, they are
easy to miss, and forgetting them will cause issues that would be hard to detect.
{{< /callout >}}
With that being done, you can restart the DNS server and everything is ready server side,
the only remaining thing to do would be the DNS challenge itself.
### Performing the challenge
Start by installing the certbot with the RFC2136 plugin (to perform the DNS challenge).
```shell
apt install python3-certbot-dns-rfc2136
```
It's handled using a `.ini` configuration file, let's put it in `/etc/certbot/credentials.ini`
```ini
dns_rfc2136_server = <you_dns_ip>
dns_rfc2136_port = 53
dns_rfc2136_name = letsencrypt.
dns_rfc2136_secret = oK6SqKRvGNXHyNyIEy3hijQ1pclreZw4Vn5v+Q4rTLs=
dns_rfc2136_algorithm = HMAC-SHA512
```
Finally, run the challenge using certbot (if it's the first time you're using certbot on
that machine, it might ask for an email to handle admin stuff).
```shell
root@toolbox:~# certbot certonly --dns-rfc2136 --dns-rfc2136-credentials /etc/certbot/credentials.ini -d 'test.internal.example.com'
Saving debug log to /var/log/letsencrypt/letsencrypt.log
Requesting a certificate for test.internal.example.com
Waiting 60 seconds for DNS changes to propagate
Successfully received certificate.
Certificate is saved at: /etc/letsencrypt/live/test.internal.example.com/fullchain.pem
Key is saved at: /etc/letsencrypt/live/test.internal.example.com/privkey.pem
This certificate expires on 2024-09-30.
These files will be updated when the certificate renews.
Certbot has set up a scheduled task to automatically renew this certificate in the background.
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
If you like Certbot, please consider supporting our work by:
* Donating to ISRG / Let's Encrypt: https://letsencrypt.org/donate
* Donating to EFF: https://eff.org/donate-le
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
```
And that's done, you have a certificate, and a no point in time did you need to
actually expose your application to the outside world.
Now because I like to go way too far, I can propose two (2) improvements to this
setup:
- Using ACL in addition to the TSIG key to secure operations on the DNS server
- Using a second DNS server only locally accessible for your private records, and
using the public server to only perform challenges
## Bonus 1: adding a second layer of authentication to connect to the DNS
In our setup, we used **TSIG** to secure our access to the DNS server, meaning that
having the key is necessary to perform the operations. If you are paranoid, or if you
want to do a little bit more, then you could add a second layer of authentication based
on [Access Control List (ACL)](https://bind9.readthedocs.io/en/v9.18.1/security.html).
**ACL** allow to filter allowed operations based on several characteristics, such as
IP address, TSIG key, subnet. In our case, we will use an IPV4 subnet from inside a
Wireguard tunnel between the application servers (DNS clients) and the DNS server. It
could be any form of tunnel, but Wireguard is easy to configure and perfect for
point-to-point tunnels such as what we are doing here.
### Wireguard configuration
First, let's create the [Wireguard](https://www.wireguard.com/quickstart/) tunnel.
We start by creating two wireguard key pairs, which can be done this way
```shell
# Install wireguard tools
apt install wireguard-tools
# Create the keypair
wg genkey | tee privatekey | wg pubkey > publickey
```
Private key is in the `privatekey` file, and public key in the `publickey` file.
Then we can create the server configuration, create a file `/etc/wg/wg0.conf` on
the DNS server.
```ini
[Interface]
PrivateKey = <server_private_key>
Address = 192.168.42.1/24
ListenPort = 51820
[Peer]
PublicKey = <client_public_key>
AllowedIPs = 192.168.42.0/24
```
Then on the client side you can do the same
```ini
[Interface]
PrivateKey = <client_private_key>
Address = 192.168.42.2/24
[Peer]
PublicKey = <server_public_key>
Endpoint = <dns_public_ip>:51820
AllowedIPs = 192.168.42.1/32
```
Then you can start the tunnel on both sides using `wg-quick up wg0`, check that ip works
by pinging the server from the client
```shell
root@toolbox:~ ping 192.168.42.1
PING 192.168.42.1 (192.168.42.1) 56(84) bytes of data.
64 bytes from 192.168.42.1: icmp_seq=1 ttl=64 time=19.2 ms
64 bytes from 192.168.42.1: icmp_seq=2 ttl=64 time=8.25 ms
```
Basically, we created a new network `192.168.42.0/24` which links the DNS server and our client,
and we can restrict modification to the DNS zone to force them to be from inside the
virtual network, instead of allowing them from anywhere.
{{< callout type="note" >}}
The ACL that we are going to use here can have many other purposes, such as hiding
some domains, or serving different versions of a zone depending on the origin of
the client. This is not our topic of concern here though.
{{< /callout >}}
## Bonus 2: completely hiding your private domains from outside
![A schema describing the DNS challenge workflow for the ACME protocol using a public and private DNS servers](/images/dns_article_dns_challenge_2.svg)

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