1a5acddca2
regexp.MatchString() only returns an error if the pattern can't be parsed. In this case, the pattern is a constant string literal, so unless there's a programming mistake, the pattern should always be parsable and there should never be an error. What really needs to be checked is whether the 'containerName' matched the pattern or not. That's indicated by the bool return value 'matched'. https://github.com/containers/toolbox/pull/639 |
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.github/ISSUE_TEMPLATE | ||
completion/bash | ||
data | ||
doc | ||
images/fedora | ||
playbooks | ||
profile.d | ||
src | ||
test/system | ||
.gitignore | ||
.zuul.yaml | ||
CODE-OF-CONDUCT.md | ||
CONTRIBUTING.md | ||
COPYING | ||
gen-docs-list | ||
meson.build | ||
meson_options.txt | ||
NEWS | ||
README.md | ||
SECURITY.md | ||
toolbox |
Toolbox is a tool for Linux operating systems, which allows the use of containerized command line environments. It is built on top of Podman and other standard container technologies from OCI.
The toolbox container is a fully mutable container; when you see
yum install ansible
for example, that's something you can do inside your
toolbox container, without affecting the base operating system.
This is particularly useful on OSTree based operating systems like Fedora CoreOS and Silverblue. The intention of these systems is to discourage installation of software on the host, and instead install software as (or in) containers.
However, this tool doesn't require using an OSTree based system — it works equally well if you're running e.g. existing Fedora Workstation or Server, and that's a useful way to incrementally adopt containerization.
The toolbox environment is based on an OCI
image. On Fedora this is the fedora-toolbox
image. This image is used to
create a toolbox container that seamlessly integrates with the rest of the
operating system.
Usage
Create your toolbox container:
[user@hostname ~]$ toolbox create
Created container: fedora-toolbox-33
Enter with: toolbox enter
[user@hostname ~]$
This will create a container called fedora-toolbox-<version-id>
.
Enter the toolbox:
[user@hostname ~]$ toolbox enter
⬢[user@toolbox ~]$
Remove a toolbox container:
[user@hostname ~]$ toolbox rm fedora-toolbox-33
[user@hostname ~]$
Dependencies and Installation
Toolbox requires at least Podman 1.4.0 to work, and uses the Meson build system.
The following dependencies are required to build it:
- meson
- go-md2man
- systemd
The following dependencies enable various optional features:
- bash-completion
It can be built and installed as any other typical Meson-based project:
[user@hostname toolbox]$ meson -Dprofile_dir=/etc/profile.d builddir
[user@hostname toolbox]$ ninja -C builddir
[user@hostname toolbox]$ sudo ninja -C builddir install
Toolbox is written in Go. Consult the src/go.mod file for a full list of all the Go dependencies.
By default, Toolbox uses Go modules and all the required Go packages are automatically downloaded as part of the build. There's no need to worry about the Go dependencies, unless the build environment doesn't have network access or any such peculiarities.
Goals and Use Cases
High Level Goals
- Provide a CLI convenience interface to run containers (via
podman
) easily - Support for Developer and Debugging/Management use cases
- Support for multiple distros
- toolbox package in multiple distros
- toolbox containers for multiple distros
Non-Goals - Anti Use Cases
- Supporting multiple container runtimes.
toolbox
will usepodman
exclusively - Adding significant features on top of
podman
- Significant feature requests should be driven into
podman
upstream
- Significant feature requests should be driven into
- To run containers that aren't tightly integrated with the host
- i.e. extremely sandboxed containers become specific to the user quickly
Developer Use Cases
- I’m a developer hacking on source code and building/testing code
- Most cases: user doesn't need root, rootless containers work fine
- Some cases: user needs root for testing
- Desktop Development:
- developers need things like dbus, display, etc, to be forwarded into the toolbox
- Headless Development:
- toolbox works properly in headless environments (no display, etc)
- Need development tools like gdb, strace, etc to work
Debugging/System management Use Cases
- Inspecting Host Processes/Kernel
- Typically need root access
- Need bpftrace, strace on host processes to work
- Ideally even do things like helping get kernel-debuginfo data for the host kernel
- Managing system services
- systemctl restart foo.service
- journalctl
- Managing updates to the host
- rpm-ostree
- dnf/yum (classic systems)
Specific environments
- Fedora Silverblue
- Silverblue comes with a subset of packages and discourages host software changes
- Users need a toolbox container as a working environment
- Future: use toolbox container by default when a user opens a shell
- Silverblue comes with a subset of packages and discourages host software changes
- Fedora CoreOS
- Similar to silverblue, but non-graphical and smaller package set
- RHEL CoreOS
- Similar to Fedora CoreOS. Based on RHEL content and the underlying OS for OpenShift
- Need to use default authfile on pull
- Need to ensure compatibility with the rhel7/support-tools container
- currently not a toolbox image, opportunity for collaboration
- Alignment with
oc debug node/
(OpenShift)oc debug node
opens a shell on a kubernetes node- Value in having a consistent environment for both
toolbox
in debugging mode andoc debug node
Distro support
By default, Toolbox creates the container using an
OCI image called
<ID>-toolbox:<VERSION-ID>
, where <ID>
and <VERSION-ID>
are taken from the
host's /usr/lib/os-release
. For example, the default image on a Fedora 33
host would be fedora-toolbox:33
.
This default can be overridden by the --image
option in toolbox create
,
but operating system distributors should provide an adequately configured
default image to ensure a smooth user experience.
Image requirements
Toolbox customizes newly created containers in a certain way. This requires certain tools and paths to be present and have certain characteristics inside the OCI image.
Tools:
getent(1)
id(1)
ln(1)
mkdir(1)
: for hosts where/home
is a symbolic link to/var/home
passwd(1)
readlink(1)
rm(1)
rmdir(1)
: for hosts where/home
is a symbolic link to/var/home
sleep(1)
test(1)
touch(1)
unlink(1)
useradd(8)
usermod(8)
Paths:
/etc/host.conf
: optional, if present not a bind mount/etc/hosts
: optional, if present not a bind mount/etc/krb5.conf.d
: directory, not a bind mount/etc/localtime
: optional, if present not a bind mount/etc/resolv.conf
: optional, if present not a bind mount/etc/timezone
: optional, if present not a bind mount
Toolbox enables sudo(8)
access inside containers. The following is necessary
for that to work:
-
The image should have
sudo(8)
enabled for users belonging to either thesudo
orwheel
groups, and the group itself should exist. File an issue if you really need support for a different group. However, it's preferable to keep this list as short as possible. -
The image should allow empty passwords for
sudo(8)
. This can be achieved by either adding thenullok
option to thePAM(8)
configuration, or by add theNOPASSWD
tag to thesudoers(5)
configuration.
Since Toolbox only works with OCI images that fulfill certain requirements,
it will refuse images that aren't tagged with
com.github.containers.toolbox="true"
and
com.github.debarshiray.toolbox="true"
labels. These labels are meant to be
used by the maintainer of the image to indicate that they have read this
document and tested that the image works with Toolbox. You can use the
following snippet in a Dockerfile for this:
LABEL com.github.containers.toolbox="true" \
com.github.debarshiray.toolbox="true"