This page describes the west workspace concept introduced in Basics in more detail.
West creates and controls a Git branch named
manifest-rev in each
project. This branch points to the revision that the manifest file
specified for the project at the time west update was last run.
Other workspace management commands may use
manifest-rev as a reference
point for the upstream revision as of this latest update. Among other
manifest-rev branch allows the manifest file to use SHAs
as project revisions.
manifest-rev is a normal Git branch, west will recreate and/or
reset it on the next update. For this reason, it is dangerous
to check it out or otherwise modify it yourself. For instance, any commits
you manually add to this branch may be lost the next time you run
update. Instead, check out a local branch with another name, and either
rebase it on top of a new
manifest-rev, or merge
West does not create a
manifest-rev branch in the manifest repository,
since west does not manage the manifest repository’s branches or revisions.
refs/west/* Git refs¶
West also reserves all Git refs that begin with
refs/west/ (such as
refs/west/foo) for itself in local project repositories. Unlike
manifest-rev, these refs are not regular branches. West’s behavior here is
an implementation detail; users should not rely on these refs’ existence or
You can use west to fetch from private repositories. There is nothing west-specific about this.
west update command essentially runs
git fetch YOUR_PROJECT_URL
when a project’s
manifest-rev branch must be updated to a newly fetched
commit. It’s up to your environment to make sure the fetch succeeds.
You can either enter the password manually or use any of the credential helpers built in to Git. Since Git has credential storage built in, there is no need for a west-specific feature.
The following sections cover common cases for running
west update without
having to enter your password, as well as how to troubleshoot issues.
Fetching via HTTPS¶
On Windows when fetching from GitHub, recent versions of Git prompt you for your GitHub password in a graphical window once, then store it for future use (in a default installation). Passwordless fetching from GitHub should therefore work “out of the box” on Windows after you have done it once.
In general, you can store your credentials on disk using the “store” git credential helper. See the git-credential-store manual page for details.
To use this helper for all the repositories in your workspace, run:
west forall -c "git config credential.helper store"
To use this helper on just the projects
west forall -c "git config credential.helper store" foo bar
To use this helper by default on your computer, run:
git config --global credential.helper store
On GitHub, you can set up a personal access token to use in place of your account password. (This may be required if your account has two-factor authentication enabled, and may be preferable to storing your account password in plain text even if two-factor authentication is disabed.)
If you don’t want to store any credentials on the file system, you can store them in memory temporarily using git-credential-cache instead.
Projects can be located anywhere inside the workspace, but they may not “escape” it.
In other words, project repositories need not be located in subdirectories of the manifest repository or as immediate subdirectories of the topdir. However, projects must have paths inside the workspace.
You may replace a project’s repository directory within the workspace with a symbolic link to elsewhere on your computer, but west will not do this for you.
The following are example source code topologies supported by west.
T1: star topology, zephyr is the manifest repository
T2: star topology, a Zephyr application is the manifest repository
T3: forest topology, freestanding manifest repository
T1: Star topology, zephyr is the manifest repository¶
The zephyr repository acts as the central repository and specifies its Modules (External projects) in its
Analogy with existing mechanisms: Git submodules with zephyr as the super-project
This is the default. See Workspace concepts for how mainline Zephyr is an example of this topology.
T2: Star topology, application is the manifest repository¶
Useful for those focused on a single application
A repository containing a Zephyr application acts as the central repository and names other projects required to build it in its
west.yml. This includes the zephyr repository and any modules.
Analogy with existing mechanisms: Git submodules with the application as the super-project, zephyr and other projects as submodules
A workspace using this topology looks like this:
west-workspace/ │ ├── application/ # .git/ │ │ ├── CMakeLists.txt │ │ ├── prj.conf │ never modified by west │ ├── src/ │ │ │ └── main.c │ │ └── west.yml # main manifest with optional import(s) and override(s) │ │ ├── modules/ │ └── lib/ │ └── tinycbor/ # .git/ project from either the main manifest or some import. │ └── zephyr/ # .git/ project └── west.yml # This can be partially imported with lower precedence or ignored. # Only the 'manifest-rev' version can be imported.
Here is an example
application/west.yml which uses
Manifest Imports, available since west 0.7, to import Zephyr v2.5.0
and its modules into the application manifest file:
# Example T2 west.yml, using manifest imports. manifest: remotes: - name: zephyrproject-rtos url-base: https://github.com/zephyrproject-rtos projects: - name: zephyr remote: zephyrproject-rtos revision: v2.5.0 import: true self: path: application
You can still selectively “override” individual Zephyr modules if you use
import: in this way; see Example 1.3: Downstream of a Zephyr release, with module fork for an example.
Another way to do the same thing is to copy/paste
application/west.yml, adding an entry for the zephyr
project itself, like this:
# Equivalent to the above, but with manually maintained Zephyr modules. manifest: remotes: - name: zephyrproject-rtos url-base: https://github.com/zephyrproject-rtos defaults: remote: zephyrproject-rtos projects: - name: zephyr revision: v2.5.0 west-commands: scripts/west-commands.yml - name: net-tools revision: some-sha-goes-here path: tools/net-tools # ... other Zephyr modules go here ... self: path: application
The main advantage to using
import is not having to track the revisions of
imported projects separately. In the above example, using
Zephyr’s module versions are automatically determined from the
zephyr/west.yml revision, instead of having to be copy/pasted (and
maintained) on their own.
T3: Forest topology¶
Useful for those supporting multiple independent applications or downstream distributions with no “central” repository
A dedicated manifest repository which contains no Zephyr source code, and specifies a list of projects all at the same “level”
Analogy with existing mechanisms: Google repo-based source distribution
A workspace using this topology looks like this:
west-workspace/ ├── app1/ # .git/ project │ ├── CMakeLists.txt │ ├── prj.conf │ └── src/ │ └── main.c ├── app2/ # .git/ project │ ├── CMakeLists.txt │ ├── prj.conf │ └── src/ │ └── main.c ├── manifest-repo/ # .git/ never modified by west │ └── west.yml # main manifest with optional import(s) and override(s) ├── modules/ │ └── lib/ │ └── tinycbor/ # .git/ project from either the main manifest or │ # from some import │ └── zephyr/ # .git/ project └── west.yml # This can be partially imported with lower precedence or ignored. # Only the 'manifest-rev' version can be imported.
Here is an example T3
manifest-repo/west.yml which uses
Manifest Imports, available since west 0.7, to import Zephyr
v2.5.0 and its modules, then add the
manifest: remotes: - name: zephyrproject-rtos url-base: https://github.com/zephyrproject-rtos - name: your-git-server url-base: https://git.example.com/your-company defaults: remote: your-git-server projects: - name: zephyr remote: zephyrproject-rtos revision: v2.5.0 import: true - name: app1 revision: SOME_SHA_OR_BRANCH_OR_TAG - name: app2 revision: ANOTHER_SHA_OR_BRANCH_OR_TAG self: path: manifest-repo
You can also do this “by hand” by copy/pasting
as shown above for the T2 topology, with the same caveats.