forked from cadey/xesite
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14 KiB
Markdown
333 lines
14 KiB
Markdown
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---
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title: Encrypted Secrets with NixOS
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date: 2021-01-20
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series: nixos
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tags:
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- age
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- ed25519
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---
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# Encrypted Secrets with NixOS
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One of the best things about NixOS is the fact that it's so easy to do
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configuration management using it. The Nix store (where all your packages live)
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has a huge flaw for secret management though: everything in the Nix store is
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globally readable. This means that anyone logged into or running code on the
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system could read any secret in the Nix store without any limits. This is
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sub-optimal if your goal is to keep secret values secret. There have been a few
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approaches to this over the years, but I want to describe how I'm doing it.
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Here are my goals and implementation for this setup and how a few other secret
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management strategies don't quite pan out.
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At a high level I have these goals:
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* It should be trivial to declare new secrets
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* Secrets should never be globally readable in any useful form
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* If I restart the machine, I should not need to take manual human action to
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ensure all of the services come back online
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* GPG should be avoided at all costs
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As a side goal being able to roll back secret changes would also be nice.
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The two biggest tools that offer a way to help with secret management on NixOS
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that come to mind are NixOps and Morph.
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[NixOps](https://github.com/NixOS/nixops) is a tool that helps administrators
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operate NixOS across multiple servers at once. I use NixOps extensively in my
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own setup. It calls deployment secrets "keys" and they are documented
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[here](https://hydra.nixos.org/build/115931128/download/1/manual/manual.html#idm140737322649152).
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At a high level they are declared like this:
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```nix
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deployment.keys.example = {
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text = "this is a super sekrit value :)";
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user = "example";
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group = "keys";
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permissions = "0400";
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};
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```
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This will create a new secret in `/run/keys` that will contain our super secret
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value.
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[Wait, isn't `/run` an ephemeral filesystem? What happens when the system
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reboots?](conversation://Mara/hmm)
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Let's make an example system and find out! So let's say we have that `example`
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secret from earlier and want to use it in a job. The job definition could look
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something like this:
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```nix
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# create a service-specific user
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users.users.example.isSystemUser = true;
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# without this group the secret can't be read
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users.users.example.extraGroups = [ "keys" ];
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systemd.services.example = {
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wantedBy = [ "multi-user.target" ];
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after = [ "example-key.service" ];
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wants = [ "example-key.service" ];
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serviceConfig.User = "example";
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serviceConfig.Type = "oneshot";
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script = ''
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stat /run/keys/example
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'';
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};
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```
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This creates a user called `example` and gives it permission to read deployment
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keys. It also creates a systemd service called `example.service` and runs
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[`stat(1)`](https://linux.die.net/man/1/stat) to show the permissions of the
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service and the key file. It also runs as our `example` user. To avoid systemd
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thinking our service failed, we're also going to mark it as a
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[oneshot](https://www.digitalocean.com/community/tutorials/understanding-systemd-units-and-unit-files#the-service-section).
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Altogether it could look something like
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[this](https://gist.github.com/Xe/4a71d7741e508d9002be91b62248144a). Let's see
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what `systemctl` has to report:
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```console
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$ nixops ssh -d blog-example pa -- systemctl status example
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● example.service
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Loaded: loaded (/nix/store/j4a8f6mnaw3v4sz7dqlnz95psh72xglw-unit-example.service/example.service; enabled; vendor preset: enabled)
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Active: inactive (dead) since Wed 2021-01-20 20:53:54 UTC; 37s ago
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Process: 2230 ExecStart=/nix/store/1yg89z4dsdp1axacqk07iq5jqv58q169-unit-script-example-start/bin/example-start (code=exited, status=0/SUCCESS)
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Main PID: 2230 (code=exited, status=0/SUCCESS)
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IP: 0B in, 0B out
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CPU: 3ms
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Jan 20 20:53:54 pa example-start[2235]: File: /run/keys/example
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Jan 20 20:53:54 pa example-start[2235]: Size: 31 Blocks: 8 IO Block: 4096 regular file
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Jan 20 20:53:54 pa example-start[2235]: Device: 18h/24d Inode: 37428 Links: 1
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Jan 20 20:53:54 pa example-start[2235]: Access: (0400/-r--------) Uid: ( 998/ example) Gid: ( 96/ keys)
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Jan 20 20:53:54 pa example-start[2235]: Access: 2021-01-20 20:53:54.010554201 +0000
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Jan 20 20:53:54 pa example-start[2235]: Modify: 2021-01-20 20:53:54.010554201 +0000
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Jan 20 20:53:54 pa example-start[2235]: Change: 2021-01-20 20:53:54.398103181 +0000
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Jan 20 20:53:54 pa example-start[2235]: Birth: -
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Jan 20 20:53:54 pa systemd[1]: example.service: Succeeded.
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Jan 20 20:53:54 pa systemd[1]: Finished example.service.
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```
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So what happens when we reboot? I'll force a reboot in my hypervisor and we'll
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find out:
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```console
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$ nixops ssh -d blog-example pa -- systemctl status example
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● example.service
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Loaded: loaded (/nix/store/j4a8f6mnaw3v4sz7dqlnz95psh72xglw-unit-example.service/example.service; enabled; vendor preset: enabled)
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Active: inactive (dead)
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```
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The service is inactive. Let's see what the status of `example-key.service` is:
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```console
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$ nixops ssh -d blog-example pa -- systemctl status example-key
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● example-key.service
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Loaded: loaded (/nix/store/ikqn64cjq8pspkf3ma1jmx8qzpyrckpb-unit-example-key.service/example-key.service; linked; vendor preset: enabled)
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Active: activating (start-pre) since Wed 2021-01-20 20:56:05 UTC; 3min 1s ago
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Cntrl PID: 610 (example-key-pre)
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IP: 0B in, 0B out
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IO: 116.0K read, 0B written
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Tasks: 4 (limit: 2374)
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Memory: 1.6M
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CPU: 3ms
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CGroup: /system.slice/example-key.service
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├─610 /nix/store/kl6lr3czkbnr6m5crcy8ffwfzbj8a22i-bash-4.4-p23/bin/bash -e /nix/store/awx1zrics3cal8kd9c5d05xzp5ikazlk-unit-script-example-key-pre-start/bin/example-key-pre-start
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├─619 /nix/store/kl6lr3czkbnr6m5crcy8ffwfzbj8a22i-bash-4.4-p23/bin/bash -e /nix/store/awx1zrics3cal8kd9c5d05xzp5ikazlk-unit-script-example-key-pre-start/bin/example-key-pre-start
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├─620 /nix/store/kl6lr3czkbnr6m5crcy8ffwfzbj8a22i-bash-4.4-p23/bin/bash -e /nix/store/awx1zrics3cal8kd9c5d05xzp5ikazlk-unit-script-example-key-pre-start/bin/example-key-pre-start
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└─621 inotifywait -qm --format %f -e create,move /run/keys
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Jan 20 20:56:05 pa systemd[1]: Starting example-key.service...
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```
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The service is blocked waiting for the keys to exist. We have to populate the
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keys with `nixops send-keys`:
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```console
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$ nixops send-keys -d blog-example
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pa> uploading key ‘example’...
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```
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Now when we check on `example.service`, we get the following:
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```console
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$ nixops ssh -d blog-example pa -- systemctl status example
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● example.service
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Loaded: loaded (/nix/store/j4a8f6mnaw3v4sz7dqlnz95psh72xglw-unit-example.service/example.service; enabled; vendor preset: enabled)
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Active: inactive (dead) since Wed 2021-01-20 21:00:24 UTC; 32s ago
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Process: 954 ExecStart=/nix/store/1yg89z4dsdp1axacqk07iq5jqv58q169-unit-script-example-start/bin/example-start (code=exited, status=0/SUCCESS)
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Main PID: 954 (code=exited, status=0/SUCCESS)
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IP: 0B in, 0B out
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CPU: 3ms
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Jan 20 21:00:24 pa example-start[957]: File: /run/keys/example
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Jan 20 21:00:24 pa example-start[957]: Size: 31 Blocks: 8 IO Block: 4096 regular file
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Jan 20 21:00:24 pa example-start[957]: Device: 18h/24d Inode: 27774 Links: 1
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Jan 20 21:00:24 pa example-start[957]: Access: (0400/-r--------) Uid: ( 998/ example) Gid: ( 96/ keys)
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Jan 20 21:00:24 pa example-start[957]: Access: 2021-01-20 21:00:24.588494730 +0000
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Jan 20 21:00:24 pa example-start[957]: Modify: 2021-01-20 21:00:24.588494730 +0000
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Jan 20 21:00:24 pa example-start[957]: Change: 2021-01-20 21:00:24.606495751 +0000
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Jan 20 21:00:24 pa example-start[957]: Birth: -
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Jan 20 21:00:24 pa systemd[1]: example.service: Succeeded.
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Jan 20 21:00:24 pa systemd[1]: Finished example.service.
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```
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This means that NixOps secrets require _manual human intervention_ in order to
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repopulate them on server boot. If your server went offline overnight due to an
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unexpected issue, your services using those keys could be stuck offline until
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morning. This is undesirable for a number of reasons. This plus the requirement
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for the `keys` group (which at time of writing was undocumented) to be added to
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service user accounts means that while they do work, they are not very
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ergonomic.
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[You can read secrets from files using something like
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`deployment.keys.example.text = "${builtins.readFile ./secrets/example.env}"`,
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but it is kind of a pain to have to do that. It would be better to just
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reference the secrets by filesystem paths in the first
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place.](conversation://Mara/hacker)
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On the other hand [Morph](https://github.com/DBCDK/morph) gets this a bit
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better. It is sadly even less documented than NixOps is, but it offers a similar
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experience via [deployment
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secrets](https://github.com/DBCDK/morph/blob/master/examples/secrets.nix). The
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main differences that Morph brings to the table are taking paths to secrets and
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allowing you to run an arbitrary command on the secret being uploaded. Secrets
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are also able to be put anywhere on the disk, meaning that when a host reboots it
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will come back up with the most recent secrets uploaded to it.
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However, like NixOps, Morph secrets don't have the ability to be rolled back.
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This means that if you mess up a secret value you better hope you have the old
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information somewhere. This violates what you'd expect from a NixOS machine.
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So given these examples, I thought it would be interesting to explore what the
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middle path could look like. I chose to use
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[age](https://github.com/FiloSottile/age) for encrypting secrets in the Nix
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store as well as using SSH host keys to ensure that every secret is decryptable
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at runtime by _that machine only_. If you get your hands on the secret
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cyphertext, it should be unusable to you.
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One of the harder things here will be keeping a list of all of the server host
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keys. Recently I added a
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[hosts.toml](https://github.com/Xe/nixos-configs/blob/master/ops/metadata/hosts.toml)
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file to my config repo for autoconfiguring my WireGuard overlay network. It was
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easy enough to add all the SSH host keys for each machine using a command like
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this to get them:
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[We will cover how this WireGuard overlay works in a future post.](conversation://Mara/hacker)
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```console
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$ nixops ssh-for-each -d hexagone -- cat /etc/ssh/ssh_host_ed25519_key.pub
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firgu....> ssh-ed25519 AAAAC3NzaC1lZDI1NTE5AAAAIB8+mCR+MEsv0XYi7ohvdKLbDecBtb3uKGQOPfIhdj3C root@nixos
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chrysalis> ssh-ed25519 AAAAC3NzaC1lZDI1NTE5AAAAIGDA5iXvkKyvAiMEd/5IruwKwoymC8WxH4tLcLWOSYJ1 root@chrysalis
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lufta....> ssh-ed25519 AAAAC3NzaC1lZDI1NTE5AAAAIMADhGV0hKt3ZY+uBjgOXX08txBS6MmHZcSL61KAd3df root@lufta
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keanu....> ssh-ed25519 AAAAC3NzaC1lZDI1NTE5AAAAIGDZUmuhfjEIROo2hog2c8J53taRuPJLNOtdaT8Nt69W root@nixos
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```
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age lets you use SSH keys for decryption, so I added these keys to my
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`hosts.toml` and ended up with something like
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[this](https://github.com/Xe/nixos-configs/commit/14726e982001e794cd72afa1ece209eed58d3f38#diff-61d1d8dddd71be624c0d718be22072c950ec31c72fded8a25094ea53d94c8185).
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Now we can encrypt secrets on the host machine and safely put them in the Nix
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store because they will be readable to each target machine with a command like
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this:
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```shell
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age -d -i /etc/ssh/ssh_host_ed25519_key -o $dest $src
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```
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From here it's easy to make a function that we can use for generating new
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encrypted secrets in the Nix store. First we need to import the host metadata
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from the toml file:
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```nix
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let
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cfg = config.within.secrets;
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metadata = lib.importTOML ../../ops/metadata/hosts.toml;
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mkSecretOnDisk = name:
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{ source, ... }:
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pkgs.stdenv.mkDerivation {
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name = "${name}-secret";
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phases = "installPhase";
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buildInputs = [ pkgs.age ];
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installPhase =
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let key = metadata.hosts."${config.networking.hostName}".ssh_pubkey;
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in ''
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age -a -r "${key}" -o $out ${source}
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'';
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};
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```
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And then we can generate systemd oneshot jobs with something like this:
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```nix
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mkService = name:
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{ source, dest, owner, group, permissions, ... }: {
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description = "decrypt secret for ${name}";
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wantedBy = [ "multi-user.target" ];
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serviceConfig.Type = "oneshot";
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script = with pkgs; ''
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rm -rf ${dest}
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${age}/bin/age -d -i /etc/ssh/ssh_host_ed25519_key -o ${dest} ${
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mkSecretOnDisk name { inherit source; }
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}
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chown ${owner}:${group} ${dest}
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chmod ${permissions} ${dest}
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'';
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};
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```
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And from there we just need some [boring
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boilerplate](https://github.com/Xe/nixos-configs/blob/master/common/crypto/default.nix#L8-L38)
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to define a secret type. Then we declare the secret type and its invocation:
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```nix
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in {
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options.within.secrets = mkOption {
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type = types.attrsOf secret;
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description = "secret configuration";
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default = { };
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};
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config.systemd.services = let
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units = mapAttrs' (name: info: {
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name = "${name}-key";
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value = (mkService name info);
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}) cfg;
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in units;
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}
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```
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And we have ourself a NixOS module that allows us to:
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* Trivially declare new secrets
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* Make secrets in the Nix store useless without the key
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* Make every secret be transparently decrypted on startup
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* Avoid the use of GPG
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* Roll back secrets like any other configuration change
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Declaring new secrets works like this (as stolen from [the service definition
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for the website you are reading right now](https://github.com/Xe/nixos-configs/blob/master/common/services/xesite.nix#L35-L41)):
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```nix
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within.secrets.example = {
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source = ./secrets/example.env;
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dest = "/var/lib/example/.env";
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owner = "example";
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group = "nogroup";
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permissions = "0400";
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};
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```
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Barring some kind of cryptographic attack against age, this should allow the
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secrets to be stored securely. I am working on a way to make this more generic.
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This overall approach was inspired by [agenix](https://github.com/ryantm/agenix)
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but made more specific for my needs. I hope this approach will make it easy for
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me to manage these secrets in the future.
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