8.6 KiB
Usage
Flake
Self Host Blocks is available as a flake. To use it in your project, add the following flake input:
inputs.selfhostblocks.url = "github:ibizaman/selfhostblocks";
Then, in your nixosConfigurations
, import the module with:
imports = [
inputs.selfhostblocks.nixosModules.x86_64-linux.default
];
For now, Self Host Blocks has a hard dependency on sops-nix
. I am working on removing
that so you can use any secrets manager you
want. Until then, you also need to import the sops-nix
module:
imports = [
inputs.selfhostblocks.inputs.sops-nix.nixosModules.default
];
Self Host Blocks provides its own nixpkgs
input so both can be updated in lock step, ensuring
maximum compatibility. It is recommended to use the following nixpkgs
as input for your deployments:
inputs.selfhostblocks.inputs.nixpkgs
Advanced users can if they wish use a version of nixpkgs
of their choosing but then we cannot
guarantee Self Host Block won't use a non-existing option from nixpkgs
.
To avoid manually updating the nixpkgs
version, the GitHub repository for Self Host Blocks
tries to update the nixpkgs
input daily, verifying all tests pass before accepting this new
nixpkgs
version. The setup is explained in this blog post.
Example Deployment with Nixos-Rebuild
The following snippets show how to deploy Self Host Blocks using the standard deployment system nixos-rebuild
.
{
inputs = {
selfhostblocks.url = "github:ibizaman/selfhostblocks";
};
outputs = { self, selfhostblocks }: {
nixosConfigurations = {
machine = selfhostblocks.inputs.nixpkgs.lib.nixosSystem {
system = "x86_64-linux";
modules = [
selfhostblocks.nixosModules.${system}.default
];
# Machine specific configuration goes here.
};
};
};
}
The above snippet is very minimal as it assumes you have only one machine to deploy to, so nixpkgs
is defined exclusively by the selfhostblocks.inputs.nixpkgs
input. If some machines are not using
Self Host Blocks, you can do the following:
{
inputs = {
selfhostblocks.url = "github:ibizaman/selfhostblocks";
};
outputs = { self, selfhostblocks }: {
nixosConfigurations = {
machine1 = nixpkgs.lib.nixosSystem {
};
machine2 = selfhostblocks.inputs.nixpkgs.lib.nixosSystem {
system = "x86_64-linux";
modules = [
selfhostblocks.nixosModules.${system}.default
];
# Machine specific configuration goes here.
};
};
};
}
Example Deployment With Colmena
The following snippets show how to deploy Self Host Blocks using the deployment system Colmena.
{
inputs = {
nixpkgs.url = "github:nixos/nixpkgs/nixos-unstable";
selfhostblocks.url = "github:ibizaman/selfhostblocks";
};
outputs = { self, selfhostblocks }: {
colmena =
let
system = "x86_64-linux";
in {
meta = {
nixpkgs = import selfhostblocks.inputs.nixpkgs { inherit system; };
};
machine = { selfhostblocks, ... }: {
imports = [
selfhostblocks.nixosModules.${system}.default
];
# Machine specific configuration goes here.
};
};
};
}
The above snippet is very minimal as it assumes you have only one machine to deploy to, so nixpkgs
is defined exclusively by the selfhostblocks
input. It is more likely that you have multiple machines, in this case you can use the colmena.meta.nodeNixpkgs
option:
{
inputs = {
nixpkgs.url = "github:nixos/nixpkgs/nixos-unstable";
selfhostblocks.url = "github:ibizaman/selfhostblocks";
};
outputs = { self, selfhostblocks }: {
colmena = {
let
system = "x86_64-linux";
in {
meta =
nixpkgs = import nixpkgs { inherit system; };
nodeNixpkgs = {
machine2 = import selfhostblocks.inputs.nixpkgs { inherit system; };
};
};
machine1 = ...;
machine2 = { selfhostblocks, ... }: {
imports = [
selfhostblocks.nixosModules.${system}.default
];
# Machine specific configuration goes here.
};
};
};
}
In the above snippet, machine1
will use the nixpkgs
version from your inputs while machine2
will use the nixpkgs
version from selfhostblocks
.
Secrets with sops-nix
This section complements the official sops-nix guide.
Managing secrets is an important aspect of deploying. You cannot store your secrets in nix directly
because they get stored unencrypted and you don't want that. We need to use another system that
encrypts secrets when storing in the nix store and then decrypts them on the target host upon system
activation. sops-nix
is one of such system.
Sops-nix works by encrypting the secrets file with at least 2 keys. Your private key and a private key from the target host. This way, you can edit the secrets and the target host can decrypt the secrets. Separating the keys this way is good practice because it reduces the impact of having one being compromised.
One way to setup secrets management using sops-nix
:
-
Create your own private key that will be located in
keys.txt
. The public key will be printed on stdout.$ nix shell nixpkgs#age --command age-keygen -o keys.txt Public key: age1algdv9xwjre3tm7969eyremfw2ftx4h8qehmmjzksrv7f2qve9dqg8pug7
-
Get the target host's public key. We will use the key derived from the ssh key of the host.
$ nix shell nixpkgs#ssh-to-age --command \ sh -c 'ssh-keyscan -t ed25519 -4 <target_host> | ssh-to-age' # localhost:2222 SSH-2.0-OpenSSH_9.6 age13wgyyae8epyw894ugd0rjjljh0rm98aurvzmsapcv7d852g9r5lq0pqfx8
-
Create a
sops.yaml
file that explains how sops-nix should encrypt the - yet to be created -secrets.yaml
file. You can be creative here, but a basic snippet is:keys: - &me age1algdv9xwjre3tm7969eyremfw2ftx4h8qehmmjzksrv7f2qve9dqg8pug7 - &target age13wgyyae8epyw894ugd0rjjljh0rm98aurvzmsapcv7d852g9r5lq0pqfx8 creation_rules: - path_regex: secrets.yaml$ key_groups: - age: - *me - *target
-
Create a
secrets.yaml
file that will contain the encrypted secrets as a Yaml file:$ SOPS_AGE_KEY_FILE=keys.txt nix run --impure nixpkgs#sops -- \ secrets.yaml
This will open your preferred editor. An example of yaml file is the following (secrets are elided for brevity):
nextcloud: adminpass: 43bb4b... onlyoffice: jwt_secret: 3a10fce3...
The actual file on your filesystem will look like so, again with data elided:
nextcloud: adminpass: ENC[AES256_GCM,data:Tt99...GY=,tag:XlAqRYidkOMRZAPBsoeEMw==,type:str] onlyoffice: jwt_secret: ENC[AES256_GCM,data:f87a...Yg=,tag:Y1Vg2WqDnJbl1Xg2B6W1Hg==,type:str] sops: kms: [] gcp_kms: [] azure_kv: [] hc_vault: [] age: - recipient: age1algdv9xwjre3tm7969eyremfw2ftx4h8qehmmjzksrv7f2qve9dqg8pug7 enc: | -----BEGIN AGE ENCRYPTED FILE----- YWdl...6g== -----END AGE ENCRYPTED FILE----- - recipient: age13wgyyae8epyw894ugd0rjjljh0rm98aurvzmsapcv7d852g9r5lq0pqfx8 enc: | -----BEGIN AGE ENCRYPTED FILE----- YWdl...RA== -----END AGE ENCRYPTED FILE----- lastmodified: "2024-01-28T06:07:02Z" mac: ENC[AES256_GCM,data:lDJh...To=,tag:Opon9lMZBv5S7rRhkGFuQQ==,type:str] pgp: [] unencrypted_suffix: _unencrypted version: 3.8.1
To actually create random secrets, you can use:
$ nix run nixpkgs#openssl -- rand -hex 64
-
Use
sops-nix
module in nix:imports = [ selfhostblocks.inputs.sops-nix.nixosModules.default ];
-
Reference the secrets in nix:
shb.nextcloud.adminPassFile = config.sops.secrets."nextcloud/adminpass".path; sops.secrets."nextcloud/adminpass" = { sopsFile = ./secrets.yaml; mode = "0440"; owner = "nextcloud"; group = "nextcloud"; restartUnits = [ "phpfpm-nextcloud.service" ]; };