stuartellis / onboarding

Onboarding documentation and convenience scripts for cloning/building/pulling/pushing the Serpent OS tooling.

For a general overview of the goals of Serpent OS and how to get in touch, see our website.

Serpent OS tooling is being redesigned in Rust.

The legacy PoC tooling was written primarily in Dlang.

We use:

• git to manage development.
• cargo and rustc to build our Rust binaries.
• rustfmt to format our Rust code consistently.
• meson (with dub as a fallback) and ldc2 to build our legacy DLang binaries.
• dfmt to format our legacy DLang code consistently. Consult the dfmt README for how to build it with LDC. Our scripts assume that dfmt is available in $PATH.
• the python module codespell for spell checking. Install it from your distribution's package manager.
• the go-task Go application to maintain frequently executed job compositions without having to clutter a repository with Makefiles or the like.

For convenience, we maintain a check-prereqs.sh script, which will check for all necessary binaries, runtime libraries and development headers and report missing prerequisites.

Most Linux distributions ship recent versions of both cargo, rustc and rustfmt. Consult your distribution's documentation for more information on how to install the relevant packages.

The latest supported ldc version is 1.32.2.

The currently recommended way to install the Dlang toolchain is to use the official install script:

curl -fsS https://dlang.org/install.sh | bash -s ldc-1.32.2

NB: Remember to source ('activate') the appropriate environment initialisation script from your preferred shell's user config file.

One of our users kindly shared their experience updating an already installed LDC instance. Read more here

Our Rust tooling repository is structured with multiple workspaces, so only a single repo needs to be cloned, which makes development more convenient.

For our legacy DLang tooling, we use a flat repository structure where all Dlang meson-controlled subprojects are expected to be checked out concurrently.

This forces a "lockstep" development methodology, which means that whatever is currently checked out in each subproject is what any given binary will be built against.

This also implies that all subprojects will need to be kept in sync with the features that are being worked on (preferably using identical topic branch names).

The only place we use "full" git submodules is in moss-vendor.

Here, all relevant Serpent OS subprojects will be checked out under ~/repos/serpent-os/

# Initial setup
mkdir -pv ~/repos/serpent-os/
cd ~/repos/serpent-os/

curl https://raw.githubusercontent.com/serpent-os/onboarding/main/init.sh |bash

A system with at least 8 GiB of RAM is recommended and compressed swap (zram or zswap) might make the build experience smoother whilst a webbrowser is open.

In addition, the onboarding build scripts will attempt to tune the amount of boulder parallel build jobs to fit with the available memory on the system.

To get started packaging with the legacy pre-alpha quality serpent tooling, the following binaries need to be built in the order listed below:

• moss-container (our lightweight container tool)
• boulder (our system software build tool)

The ./update.sh script updates, builds and installs the serpent tooling to /usr in the order listed above. It also builds and installs the new Rust-based moss binary.

• Create new recipe: boulder new https://some.uri/to-a-package-version.tar.gz -> outputs new stone.yml recipe
• Edit new recipe: nano -w stone.yml
• Build new recipe: boulder build stone.yml -p local-x86_64 -> outputs package.stone + metadata (manifest.* build manifests) in current directory
• Copy new package.stone to the local binary moss repo and include it in index: cp package.stone /var/cache/boulder/repos/local-x86_64/ && moss index /var/cache/boulder/repos/local-x86_64/
• Add local repo to repos searched by moss: moss repo add local-x86_64 file:///var/cache/boulder/repos/local-x86_64/stone.index -p 10
• Install package from local collection: moss install package

The high level flow is that packagers start by creating a stone.yml build recipe using boulder new URI-to-tarball-they-wish-to-package. This outputs a bare bones stone.yml recipe that will need fleshing out with summary, description, patches, build steps etc.

To actually build a Serpent OS format .stone binary package, packagers invoke sudo boulder build stone.yml. This will parse the stone.yml build recipe and execute the various setup, build, install etc. steps specified in the recipe and discover + add relevant metadata, dependencies etc. to the finished somepackage.stone binary build artefact. The process will also produce a moss-readable binary format build manifest named manifest.$arch.bin plus a human readable manifest.jsonc file containing essentially the same metadata as the binary manifest, but only used for git diff purposes.

Binary moss .stone packages are kept in moss repositories, which each have a stone.index file containing the metadata from all the .stone packages in the repo. Thus, to be able to install a newly built package, it will need to be moved to a known moss repo, which then needs to have its stone.index file updated to include the metadata from the newly added .stone.

Once the moss repo index has been updated, moss will be able to install the package that was just added to the moss repo.

The following section details how to get started with this process.

To be able to actually use moss, its various databases need to be initialised inside a clean folder, which will function as a root directory for a systemd-nspawn container later on.

This can be accomplished by executing:

cd img-tests/
./create-sosroot.sh

which will install a suitable set of packages for use in a systemd-nspawn container.

Boot a systemd-nspawn container with the installed minimal Serpent OS system:

sudo systemd-nspawn --bind=/var/cache/boulder/ -D ./sosroot/ -b

To stop and exit the systemd-nspawn container, issue the following command from within the container:

poweroff

If the container locks up or stops responding, you might be able to use machinectl to stop it from outside the container:

sudo machinectl poweroff sosroot

Moss and Boulder now support profiles that include multiple moss repos with priorities (higher priority overrides lower priority). Things are still a bit rough around the edges, but the following instructions should get you going with packaging in a local collection and using the .stones you put there as dependencies for subsequent builds:

# create /var/cache/boulder/repos/local-x86_64
sudo mkdir -pv /var/cache/boulder/repos/local-x86_64
# ensure your user has write access to the local moss repo
sudo chown -Rc ${USER}:${USER} /var/cache/boulder/repos/local-x86_64
# dowload/prepare a set of stones there (can be empty initially),
# then create a moss stone.index file
moss -D sosroot/ index /var/cache/boulder/repos/local-x86_64/
# add the new collection to the list of known collections to moss (highest priority so far)
moss -D sosroot/ repo add local-x86_64 file:///var/cache/boulder/repos/local-x86_64/stone.index -p10
# Ask moss to list the available .stones (including now the ones in the local colleciton)
moss -D sosroot/ list available
# newest boulder ships with a profile configuration that enables using the
# local repo for dependencies, so no need to add it before building
sudo boulder build stone.yml -p local-x86_64

NB: Currently, whenever a new .stone is added to a local repo, the local repo index needs to be updated with moss index (...).

Please refer to the website for instructions on how to get in touch with the Serpent OS developers.

Please get in touch with the Serpent OS developers before contributing pull requests.

We're a friendly bunch and will likely welcome your contributions.

Serpent OS is licensed under the MPL-2.0 license. Legacy tooling is licensed under the Zlib license.