This repository hosts various 'vhost-user' device backends in their own crates. See their individual README.md files for specific information about those crates.
To be included here device backends must:
- be based on a published VIRTIO specification
- fulfil basic functionality requirements (in conjunction with a implemented driver)
- meet the rust-vmm dev requirements
Here is the list of device backends that we support:
The vhost-device workspace also provides a template to help new developers understand how to write their own vhost-user backend.
Implementing a proper VirtIO device requires co-ordination between the specification, drivers and backend implementations. As these can all be in flux during development it was decided introducing a staging workspace which would allow developers to work within the main rust-vmm project while clearly marking the backends as not production ready.
To be included in the staging workspace there must at least be:
- A public proposal to extend the VIRTIO specification
- A public implementation of a device driver
- Documentation pointing to the above
More information may be found in its README file.
Here is the list of device backends in staging:
Like the wider rust-vmm project we expect new features to come with comprehensive code coverage. However as a multi-binary repository there are cases where avoiding a drop in coverage can be hard and an exception to the approach is allowable. These are:
- adding a new binary target (aim at least 60% overall coverage)
- expanding the main function (a small drop is acceptable)
However any new feature added to an existing binary should not cause a drop in coverage. The general aim should be to always improve coverage.
The binaries built by this repository can be run with any VMM which can act as a vhost-user frontend. Typically they have been tested with QEMU although the rust-vmm project does provide a vhost-user frontend crate for rust based VMMs.
While it's possible to implement all parts of the backend inside the vhost-device workspace consideration should be given to separating the VirtQueue handling and response logic to a crate in vm-virtio devices. This way a monolithic rust-vmm VMM implementation can reuse the core logic to service the virtio requests directly in the application.
The GPIO crate needs a local installation of libgpiod library to be available. If your distro ships libgpiod >= v2.0, then you should be fine.
Otherwise, you will need to build libgpiod yourself:
git clone --depth 1 --branch v2.0.x https://git.kernel.org/pub/scm/libs/libgpiod/libgpiod.git/
cd libgpiod
./autogen.sh --prefix="$PWD/install/"
make install
In order to inform tools about the build location, you can now set:
export PKG_CONFIG_PATH="<PATH-TO-LIBGPIOD>/install/lib/pkgconfig/"
To prevent setting this in every terminal session, you can also configure cargo to set it automatically.
Supporting Xen requires special handling while mapping the guest memory. The
vm-memory crate implements xen memory mapping support via a separate feature
xen, and this crate uses the same feature name to enable Xen support.
It was decided by the rust-vmm maintainers to keep the interface simple and
build the crate for either standard Unix memory mapping or Xen, and not both.
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