Helios is a distribution of illumos powering the Oxide Rack. The full distribution is built from several consolidations of software, driven from tools and documentation in this top-level repository.
Consolidation | Public? | Description |
---|---|---|
boot-image-tools | âś… Yes | Tool for assembling boot images for Oxide hardware |
garbage-compactor | âś… Yes | Build scripts for packages beyond the core OS |
helios-omicron-brand | âś… Yes | Zone brand for Omicron components |
helios-omnios-build | âś… Yes | Build scripts for packages beyond the core OS |
helios-omnios-extra | âś… Yes | Build scripts for packages beyond the core OS |
illumos-gate (stlouis branch) | âś… Yes | Core operating system (kernel, libc, etc) |
phbl | âś… Yes | Pico Host Boot Loader |
pinprick | âś… Yes | ROM image compression utility |
illumos/image-builder | âś… Yes | Tool for building bootable illumos disk images |
amd-firmware | ❌ No | AMD CPU firmware binary blobs (will be available in future) |
amd-host-image-builder | ❌ No | ROM image construction tools for AMD CPUs (will be available in future) |
chelsio-t6-roms | ❌ No | Chelsio T6 network interface card firmware blobs (will be available in future) |
pilot | ❌ No | A utility for low-level control of Oxide systems (will be available in future) |
NOTE: Not all consolidations are presently available to the public. We're
working on this, but for now you can set OXIDE_STAFF=no
in your environment
when you run gmake setup
to skip cloning and building software that is not
yet available.
NOTE: These instructions are for building your own operating system packages and installing them. If you're just trying to use Helios, you probably do not need to do this. See helios-engvm for information about pre-built Helios software.
The best way to get started is to be using a physical or virtual build machine running an up-to-date installation of Helios. There are some details on getting a virtual machine installed in the helios-engvm repository. There are also some details there about install media that you can use on a physical x86 system.
If you used the instructions from helios-engvm to create a virtual machine, you should already have all of the packages needed. If you used one of the ISO installers to set up a physical machine, or some other way of getting a Helios environment, you may need to install the pkg:/developer/illumos-tools package. You can check if you have this installed already with:
$ pkg list developer/illumos-tools
NAME (PUBLISHER) VERSION IFO
developer/illumos-tools 11-2.0 im-i
If missing from your system, it can be installed with pkg install
. It's also
a good idea to be running the latest Helios packages if you can. You can
update your system with:
# pkg update
Pay careful attention to the instructions printed at the end of every update.
You may be told that a boot environment was created and that you need to
reboot to activate it. You should do that with the reboot
command before
moving on.
Official Rust and Cargo binaries are available from the Rust project via the
same rustup tool that works on other systems. Use the
official instructions, but substitute bash
anywhere you see sh
; e.g., at
the time of writing, the (modified) official install instructions are:
$ curl --proto '=https' --tlsv1.2 -sSf https://sh.rustup.rs | bash
On your Helios machine, clone this repository and run the setup step:
$ git clone https://github.com/oxidecomputer/helios.git
Cloning into 'helios'...
$ cd helios
$ gmake setup
cd tools/helios-build && cargo build --quiet
...
Cloning into '/home/user/helios/projects/illumos'...
...
Setup complete! ./helios-build is now available.
NOTE: If you do not have access to private repositories in the oxidecomputer GitHub organisation, you can request that the setup step only use the public repositories; e.g.,
$ OXIDE_STAFF=no gmake setup
The Rust-based helios-build
tool will be built and several repositories will
then be cloned under projects/
. Note that, at least for now, the tool takes
a little while to build the first time.
While the tool will initially clone the expected project repositories,
subsequent manipulation (e.g., pulling updates, switching branches) is only
performed for some repositories. You can see which repositories the setup step
will update by looking at auto_update
in the
config/projects.toml
file. You should otherwise
expect to manage local clones as you would any other git repository; switching
branches, pulling updates, etc.
The operating system components at the core of Helios come from the stlouis branch of illumos-gate. The packages that ship on Helios systems are mostly stock illumos with some additions for Oxide hardware and a few minor packaging transformations.
To make it easier to build illumos, helios-build
provides several wrappers
that manage build configuration and invoke the illumos build tools. The
upstream illumos documentation has a guide, Building
illumos, which covers most of what
the Helios tools are doing on your behalf if you are curious.
While making changes to illumos, you can perform a "quick" build. This disables the shadow compilers and some of the checks that we would otherwise require for a final integration.
$ ./helios-build build-illumos -q
Dec 04 22:04:49.214 INFO file /home/user/helios/projects/illumos/illumos-quick.sh does not exist
Dec 04 22:04:49.215 INFO writing /home/user/helios/projects/illumos/illumos-quick.sh ...
Dec 04 22:04:49.215 INFO ok!
Dec 04 22:04:49.216 INFO exec: ["/sbin/sh", "-c", "cd /home/user/helios/projects/illumos && ./usr/src/tools/scripts/nightly /home/user/helios/projects/illumos/illumos-quick.sh"]
...
Depending on how many CPUs you have on your build machine, and the performance of your local storage, this can take some time. The full build log is quite large, and can be seen via, e.g.,
$ tail -F projects/illumos/log/nightly.log
Once your build has completed successfully, there will be a package repository
at projects/illumos/packages/i386
. These packages can then be transformed
and installed in various ways.
To install your newly built packages on the build machine:
$ ./helios-build onu -t my-be-name
Jan 29 09:33:44.603 INFO creating temporary repository...
...
Jan 29 09:35:53.050 INFO O| beadm activate my-be-name
Jan 29 09:35:53.911 INFO O| Activated successfully
Jan 29 09:35:53.921 INFO onu complete! you must now reboot
This will transform and install the illumos packages you just built and create
a new Boot Environment with the name you pass with -t
(e.g., my-be-name
above). The new boot environment can be seen with beadm list
, and has been
activated by onu
so that you can reboot into it. See
beadm(8) for more information about boot
environments.
When rebooting, it is a good idea to be on the console so you can see any boot messages and interact with the boot loader.
helios console login: root
Password:
Last login: Mon Jan 29 09:34:20 on console
The illumos Project stlouis-0-g27e9202a98 January 2024
root@genesis:~# reboot
updating /platform/i86pc/amd64/boot_archive (CPIO)
syncing file systems... done
rebooting...
You can see that your updated packages are now running:
$ pkg list -Hv system/kernel
pkg://on-nightly/system/kernel@0.5.11-2.0.999999:20240129T090642Z i--
Critically, the system/kernel
package shown here comes from the on-nightly
publisher (your local files) and has a quick build version (2.0.999999
).
If you have a build machine and a separate set of test machine(s), you may wish
to use the package repository server (pkg.depotd
) on your build machine. You
can reconfigure the test system to prefer to install packages from your build
machine over the network without needing to copy files around.
First, transform the packages from your most recent build and start the package server:
$ ./helios-build onu -D
Jan 29 09:39:46.885 INFO creating temporary repository...
Jan 29 09:39:46.886 INFO repository /home/user/helios/tmp/onu/repo.redist exists, removing first
...
Jan 29 09:41:00.428 INFO starting pkg.depotd on packages at: "/home/user/helios/tmp/onu/repo.redist"
Jan 29 09:41:00.428 INFO access log file is "/home/user/helios/tmp/depot/log/access"
Jan 29 09:41:00.428 INFO listening on port 7891
Jan 29 09:41:00.428 INFO ^C to quit
[29/Jan/2024:09:41:01] INDEX Search Available
[29/Jan/2024:09:41:01] ENGINE Listening for SIGTERM.
[29/Jan/2024:09:41:01] ENGINE Listening for SIGHUP.
[29/Jan/2024:09:41:01] ENGINE Listening for SIGUSR1.
[29/Jan/2024:09:41:01] ENGINE Bus STARTING
[29/Jan/2024:09:41:01] ENGINE Serving on http://0.0.0.0:7891
[29/Jan/2024:09:41:01] ENGINE Bus STARTED
The server is now running, and will remain running until you press Control-C or
terminate it in some other way. You will need to know a DNS name or IP address
(e.g., via ipadm show-addr
) on which your build machine can be contacted.
Now, on the target machine, confirm that you can contact the build machine:
$ pkgrepo info -s http://genesis:7891
PUBLISHER PACKAGES STATUS UPDATED
on-nightly 549 online 2024-01-29T09:40:50.716102Z
Examine your existing package publisher configuration. On a stock Helios system, it should look like this:
# pkg publisher
PUBLISHER TYPE STATUS P LOCATION
helios-dev origin online F https://pkg.oxide.computer/helios/2/dev/
Just one publisher is configured, using the central repository. We want to add a second publisher and make it the preferred source for packages. We also want to relax the "sticky" rule; i.e., that packages should only be updated from the publisher from which they were first installed.
# pkg set-publisher -r -O http://genesis:7891 --search-first on-nightly
# pkg set-publisher -r --non-sticky helios-dev
# pkg publisher
PUBLISHER TYPE STATUS P LOCATION
on-nightly origin online F http://genesis:7891/
helios-dev (non-sticky) origin online F https://pkg.oxide.computer/helios/2/dev/
For now, depending on what you're doing on the test system, it may be necessary
to uninstall the entire
meta-package before proceeding. This is especially
true if you have zones based on the lipkg
brand. You can do this via pkg uninstall entire
. The stock onu
tool from illumos does this automatically.
Perform a dry-run update to confirm that we are going to get updated packages from the quick build on your build machine:
# pkg update -nv
Packages to update: 325
Estimated space available: 20.67 GB
Estimated space to be consumed: 564.95 MB
Create boot environment: Yes
Activate boot environment: Yes
Create backup boot environment: No
Rebuild boot archive: Yes
Changed packages:
helios-dev -> on-nightly
SUNWcs
0.5.11-2.0.22430 -> 0.5.11-2.0.999999
SUNWcsd
0.5.11-2.0.22430 -> 0.5.11-2.0.999999
...
Note that the version is changing from a stock Helios version (which is the
commit number on the master branch of illumos) to 2.0.999999
, the quick build
version. A new boot environment will be created, and a reboot will be
required.
Run the operation again without the -n
flag to update:
# pkg update -v
...
DOWNLOAD PKGS FILES XFER (MB) SPEED
Completed 325/325 5311/5311 107.1/107.1 4.9M/s
PHASE ITEMS
Removing old actions 1213/1213
Installing new actions 892/892
Updating modified actions 5921/5921
Updating package state database Done
Updating package cache 325/325
Updating image state Done
Creating fast lookup database Done
Reading search index Done
Building new search index 582/582
Updating package cache 2/2
A clone of helios exists and has been updated and activated.
On the next boot the Boot Environment helios-1 will be
mounted on '/'. Reboot when ready to switch to this updated BE.
*** Reboot required ***
New BE: helios-1
Updating package cache 2/2
Assuming the update was successful, you should be able to reboot into your update software!
# reboot
updating /platform/i86pc/amd64/boot_archive (CPIO)
After reboot, note that the publisher configuration is persistent:
Loading unix...
Loading /platform/i86pc/amd64/boot_archive...
Loading /platform/i86pc/amd64/boot_archive.hash...
Booting...
Oxide Helios Version stlouis-0-g27e9202a98 64-bit (onu)
Hostname: helios
helios console login: root
Password:
The illumos Project stlouis-0-g27e9202a98 January 2024
# uname -v
stlouis-0-g27e9202a98
# pkg publisher
PUBLISHER TYPE STATUS P LOCATION
on-nightly origin online F http://genesis:7891/
helios-dev (non-sticky) origin online F https://pkg.oxide.computer/helios/2/dev/
In future, you should be able to do a new build, restart the package server,
and then pkg update -v
again on the test machine.
If you just want to transform the packages from a quick build without
installing them, you can do so with the -P
flag:
$ ./helios-build onu -P
Jan 29 09:45:36.040 INFO creating temporary repository...
Jan 29 09:45:36.040 INFO repository /home/user/helios/tmp/onu/repo.redist exists, removing first
...
Jan 29 09:46:14.901 INFO O| Republish: pkg:/text/locale@0.5.11,5.11-2.0.999999:20240129T090648Z ... Done
Jan 29 09:46:15.602 INFO exec: ["/usr/bin/pkgrepo", "refresh", "-s", "/home/user/helios/tmp/onu/repo.redist"], pwd: None
Jan 29 09:46:15.907 INFO O| Initiating repository refresh.
Jan 29 09:46:24.978 INFO transformed packages available for onu at: "/home/user/helios/tmp/onu/repo.redist"
This may be useful if you just want to inspect the contents of the built repository; e.g.,
$ pkgrepo info -s tmp/onu/repo.redist
PUBLISHER PACKAGES STATUS UPDATED
on-nightly 549 online 2024-01-29T09:46:15.448096Z
$ pkgrepo list -s tmp/onu/repo.redist
PUBLISHER NAME O VERSION
on-nightly SUNWcs 0.5.11-2.0.999999:20240129T090617Z
on-nightly SUNWcsd 0.5.11-2.0.999999:20240129T090618Z
on-nightly audio/audio-utilities 0.5.11-2.0.999999:20240129T090618Z
on-nightly benchmark/filebench o 0.5.11-2.0.999999:20240129T090618Z
...
$ pkg contents -t file -s tmp/onu/repo.redist '*microcode*'
PATH
platform/i86pc/ucode/AuthenticAMD/1020-00
platform/i86pc/ucode/AuthenticAMD/1022-00
platform/i86pc/ucode/AuthenticAMD/1041-00
platform/i86pc/ucode/AuthenticAMD/1043-00
platform/i86pc/ucode/AuthenticAMD/1062-00
platform/i86pc/ucode/AuthenticAMD/1080-00
platform/i86pc/ucode/AuthenticAMD/1081-00
platform/i86pc/ucode/AuthenticAMD/10A0-00
platform/i86pc/ucode/AuthenticAMD/2031-00
...
You can also preserve the package files for later analysis such as the comparison of the output of multiple builds, or transport them to remote systems for installation.
When making changes to the system it is generally best to start with a pristine built workspace, as you would have left from the quick build in the previous section.
Once your build has completed, you may wish to make a change to a particular
source file and rebuild a component. There are many components in the illumos
repository, but we can choose a simple one as an example here. To build a
particular component, we must first use bldenv
to enter the build
environment:
$ ./helios-build bldenv -q
Jan 29 09:50:22.895 INFO file /home/user/helios/projects/illumos/illumos-quick.sh exists, with correct contents
Jan 29 09:50:22.895 INFO ok!
Build type is non-DEBUG
RELEASE is
VERSION is stlouis-0-g27e9202a98
RELEASE_DATE is January 2024
The top-level 'setup' target is available to build headers and tools.
Using /bin/bash as shell.
$ pwd
/home/user/helios/projects/illumos/usr/src
A new interactive shell has been started, with PATH
and other variables set
correctly, and you can now change to a component directory and build it:
$ cd cmd/id
$ dmake -S -m serial install
...
This will build and install the updated id
command into the proto area:
$ ls -l $ROOT/usr/bin/id
-r-xr-xr-x 1 user staff 17428 Jan 29 09:51 /home/user/helios/projects/illumos/proto/root_i386-nd/usr/bin/id
This kind of targetted incremental edit-and-recompile is a good way to make changes with a short cycle time and have some expectation that they will compile.
Once you have changes you want to test, there are various things you can do next.
You can always do a new built of the entire OS. This is the only process that is (as much as anything can be) guaranteed to produce correct results. If, while doing something more incremental, you are experiencing an issue you cannot explain, a full build is always a good thing to try first.
$ ./helios-build build-illumos -q
This will rebuild all of illumos and produce packages you can then install in the usual way, as described in previous sections.
If you have updated some of the binaries in the proto area (e.g., by
running dmake install
in a kernel module or a command directory) you may
just be able to regenerate the packages and install them without doing
a full build.
Within bldenv
, regenerate the packages:
$ cd $SRC/pkg
$ dmake install
...
Publishing system-zones-internal to redist repository
Publishing system-test-zfstest to redist repository
Initiating repository refresh.
Once you have updated packages you can use them to start a package repository server or install locally, as described in the previous sections.
At the end of the day, the operating system is just files in a file system. The packaging tools and other abstractions often create a kind of mystique which separates the engineer from this concrete reality -- but you are an adult and it is your computer! Other things you can do include:
-
Just running the modified binary on the build system, or using
scp
orrsync
to copy it to the test system and run it there. Sometimes this works! If the binary requires changes to libraries or the kernel, it might not work. -
Creating a new boot environment and adjusting the files in it. Boot environments are separate ZFS file systems that can be modified, snapshotted, cloned, and booted. They can be created with
beadm create
and mounted for modification withbeadm mount
. The boot loader allows you to select a different boot environment, and you can activate a specific boot environment permanently or just for one boot usingbeadm activate
. See thebeadm(1M)
manual page for more information. -
Creating a wholly new disk image or ramdisk and booting that in a virtual machine or via PXE. There are some Helios-specific tools for creating images that can be made to include packages from a quick build, or even just arbitrary additional files, by modifying image templates. These tools are in turn based on the upstream illumos/image-builder.
If you want advice on how to do something not completely explained here, or just to streamline your workflow, please don't hesitate to reach out!
As part of building OS images for Gimlets, an image archive is produced that includes the boot ROM and the root file system ramdisk image. It also includes some metadata in a JSON file, using the same format as the omicron1 brand (see IMAGE ARCHIVES in omicron1(7)).
The contents of the file represents a committed interface between Helios and the parts of Omicron which need to download and install OS images on physical systems in the Oxide rack. The relevant contents for Omicron usage will always include at least:
Filename | Description |
---|---|
oxide.json |
Metadata header file, with at least a v=1 key and a t=os key to identify it as an OS image. |
image/rom |
The host boot ROM image. (32MiB) |
image/zfs.img |
The host root file system ramdisk image. (arbitrary size) |
In addition to the committed files listed above, some additional files may be
present for engineering or diagnostic purposes; e.g., a unix.z
compressed
kernel, and a cpio.z
compressed boot archive, for use with nanobl-rs; or
an array of extra ROM files with suffixes that represent different diagnostic
capabilities. Additional files are not committed and may change at any time in
the future. Software that interprets image archives should ignore any
unrecognised files.
Copyright 2024 Oxide Computer Company
Unless otherwise noted, all components are licenced under the Mozilla Public License Version 2.0.