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vmm-reference

vmm-reference is for experimental purposes and should NOT be used in production. ❗

Design

The purpose of the reference VMM is twofold:

  1. To validate the rust-vmm crates that compose it and demonstrate their functionality in a use-case-agnostic, end-to-end VMM.
  2. To serve as a starting point in the creation of tailor-made VMMs that users build according to their needs. Users can fork the reference VMM, mix and match its components and UI to create a functional VMM with a minimal attack surface and resource footprint, custom-made to suit their isolation requirements.

The reference VMM consists of rust-vmm crates and minimal glue code that sticks them together. The end result is a binary, roughly split between a simple CLI and a vmm crate, which ingests all the available rust-vmm building blocks compiled with all their available features. As crate development progresses, in the future, we may have feature X in crate A mutually incompatible with feature Y in crate B - therefore the reference VMM, which depends on both crates A and B, will no longer support features X and Y simultaneously. If and when this situation occurs, multiple binaries for the reference VMM will be supplied.

The vmm crate allows for pluggable UIs via a VMMConfig structure. A basic command line parser demonstrates how a frontend can be stitched to the VMM.

For more details, see DESIGN.md.

Usage

The reference VMM can be used out of the box as a hello-world example of a fully functional VMM built with rust-vmm crates.

To start a basic VM with one vCPU and 256 MiB memory, you can use the following command:

vmm-reference                      \
    --kernel path=/path/to/vmlinux \
    [--block <blkdev_config> - TBD]
    [--net <netdev_config> - TBD]

The default configuration can be updated through the command line.

The crate's Cargo.toml controls which VMM functionalities are available. By default, all rust-vmm crates are listed as dependencies and therefore included. Users can play freely with the building blocks by modifying the TOML, and the prepackaged CLI can quickly validate the altered configurations. Advanced users can, of course, plug in their own front-end.

CLI reference

  • memory - guest memory configurations
    • size_mib - u32, guest memory size in MiB (decimal)
      • default: 256 MiB
  • kernel - guest kernel configurations
    • path - String, path to the guest kernel image
    • cmdline - String, kernel command line
      • default: "console=ttyS0 i8042.nokbd reboot=t panic=1 pci=off"
    • kernel_load_addr - u64, start address for high memory (decimal)
      • default: 0x100000
  • vcpus - vCPU configurations
    • num - u8, number of vCPUs (decimal)
      • default: 1
  • block - block device configuration
    • path - String, path to the root filesystem
  • net - network device configuration
    • tap - String, tap name, only the API support is added for now, an actual network device configuration is done in the following PR under review.

Note: For now, only the path to the root block device can be configured via command line. The block device will implicitly be read-write and with cache flush command supported. Passing the block argument is optional, if you want to skip it, make sure you pass to the path argument of the kernel configuration, a suitable image (for example a Busybox one). We plan on extending the API to be able to configure more block devices and more parameters for those (not just the path). We also want to offer the same support in the near future for network and vsock devices.

Example: Override the kernel command line

vmm-reference \
    --kernel path=/path/to/kernel/image,cmdline="reboot=t panic=1 pci=off"

Example: VM with 2 vCPUs and 1 GiB memory

vmm-reference                           \
    --memory size_mib=1024          \
    --vcpu num=2                        \
    --kernel path=/path/to/kernel/image

Testing

The reference VMM is, first and foremost, a vehicle for end-to-end testing of rust-vmm crates. Each crate must contain individual functional and performance tests that exercise as wide a range of use cases as possible; the reference VMM is not meant to reiterate on that, but to validate all the pieces put together. The Rust unit tests are testing modules in isolation and private interfaces, while the two Rust integration tests (one for each supported kernel image format, i.e. ELF and bzImage) exercise the only public function of the Vmm object, run(). The Python integration tests make use of the VMM in varied configurations that aren’t overly complex and illustrate realistic use cases (e.g. one test runs a VMM with a virtio block device, one test will run a VMM with PCI, etc.).

To be able to successfully run all the tests in this repo, pre-created resources are stored in S3. The resources are downloaded locally inside the resources directory. This is handled transparently by the test cases. Note: The resources once downloaded are cached, so they are not downloaded on every run.

Running Tests

Recommended way is to run the tests inside a container using the rustvmm/dev docker image as below. (Note: You may need to run docker as sudo.)

docker run --device=/dev/kvm -it \
    --security-opt seccomp=unconfined \
    --volume $(pwd):/vmm-reference rustvmm/dev:v11

Inside the container, to run the tests, first cd vmm-reference and then follow the instructions as follows.

vmm-reference is a workspace, so to run all the Rust tests, the following command should be used:

cargo test --workspace

There is no single command yet for running all the Python integration tests in one shot. To run the tests from a single file, you can use:

pytest <path_to_the_file>

For example:

pytest tests/test_run_reference_vmm.py

A single Python test can be run as well, as shown below:

pytest <path_to_the_file>::<test_name>

For example:

pytest tests/test_run_reference_vmm.py::test_reference_vmm_with_disk

License

This project is licensed under either of:

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  • Rust 88.2%
  • Python 6.0%
  • Shell 5.8%