Crates.io | vm-device |
lib.rs | vm-device |
version | 0.1.0 |
source | src |
created_at | 2021-12-20 10:30:47.111074 |
updated_at | 2021-12-20 10:30:47.111074 |
description | management for virtual devices and resources |
homepage | |
repository | https://github.com/rust-vmm/vm-device |
max_upload_size | |
id | 500664 |
size | 82,767 |
The vm-device
crate provides:
The virtual device model is built around four traits, DevicePio
and
MutDevicePio
for
Programmed I/O
(PIO), and DeviceMmio
and MutDeviceMmio
for
Memory-mapped I/O
(MMIO). The traits define the same methods for handling read and write
operations. The difference is that DevicePio
and DeviceMmio
only require
immutable self borrows, whereas MutDevicePio
and MutDeviceMmio
require
mutable borrows.
The device manager abstraction is implemented by the IoManager
struct. It
defines two buses, one for PIO and one for MMIO. For each bus, with the help of
the PioManager
and MmioManager
traits, the manager provides methods for
device registration, as well as for dispatching read and write requests.
The manager will determine which device is responsible for handling the I/O
request based on the accessed address range, and will route the request to that
device.
PioManager
and MmioManager
traits are useful as interfaces for a couple of
reasons. First, to allow for alternative implementations when the provided
IoManager
is not sufficient. Second, to allow other crates depend on the
traits without depending on the actual implementation.
The interaction between a guest kernel, a host kernel and a VMM using
IoManager
is depicted at the diagram below. A driver in the guest kernel
issues an I/O request. That request gets turned by the host kernel’s hypervisor
(KVM) into a trigger for the VMM to handle. The trigger is either a vCPU exit or
an eventfd notification. The VMM extracts address information and determines the
target bus. Then it dispatches a new request to the IoManager
, which checks
that there’s a virtual device registered on the bus for the requested address,
and finally sends the request to that device.
A device is usually attached to a particular bus and thus needs to implement a trait of only one type. For example, serial port on x86 is a PIO device, while VirtIO devices use MMIO. It’s also possible for a device to implement both. Once the type of I/O is determined, the next step is to choose between mutable and immutable trait variant. If read or write method needs to mutate the device’s internal state, then the mutable variant must be used.
Before dispatching any I/O requests to the new device, it needs to be registered
with an IoManager
instance within the specified address range on the bus.
Creating a new IoManager
is easy by calling IoManager::new()
without any
configuration. Internally the manager stores devices as trait objects wrapped
in Arc
’s, therefore if the device implements MutDevicePio
or
MutDeviceMmio
, then it must be wrapped in a Mutex
. The crate contains
automatic implementation of DevicePio for Mutex<T> where T: MutDevicePio
and DeviceMmio for Mutex<T> where T: MutDeviceMmio
but only for the Mutex
type in the standard library. For any other Mutex
type from 3rd party crates
the blanket implementation must be done by the user.
From now on the IoManager will be routing I/O requests for the registered
address range to the device. The requests are dispatched by the client code, for
example when handling VM exits, using IoManager
's methods pio_read
,
pio_write
, mmio_read
and mmio_write
.
use std::sync::{Arc, Mutex};
use vm_device::bus::{PioAddress, PioAddressOffset, PioRange};
use vm_device::device_manager::{IoManager, PioManager};
use vm_device::MutDevicePio;
struct LogDevice {}
impl MutDevicePio for LogDevice {
fn pio_read(&mut self, base: PioAddress, offset: PioAddressOffset, _data: &mut [u8]) {
println!("mut pio_read: base {:?}, offset {}", base, offset);
}
fn pio_write(&mut self, base: PioAddress, offset: PioAddressOffset, data: &[u8]) {
println!(
"mut pio_write: base {:?}, offset {}, data {:?}",
base, offset, data
);
}
}
fn main() {
let mut manager = IoManager::new();
let device = LogDevice {};
let bus_range = PioRange::new(PioAddress(0), 10).unwrap();
manager
.register_pio(bus_range, Arc::new(Mutex::new(device)))
.unwrap();
manager.pio_write(PioAddress(0), &vec![b'o', b'k']).unwrap();
}
The vm-device
is tested using unit tests and integration tests.
It leverages rust-vmm-ci
for continuous testing. All tests are ran in the rustvmm/dev
container.
This project is licensed under either of: