sysinfo is a crate used to get a system's information.
It currently supports the following OSes (alphabetically sorted):
- Android
- FreeBSD
- iOS
- Linux
- macOS
- Raspberry Pi
- Windows
You can still use sysinfo on non-supported OSes, it'll simply do nothing and always return
empty values. You can check in your program directly if an OS is supported by checking the
[IS_SUPPORTED_SYSTEM] constant.
The minimum-supported version of rustc is 1.69.
If you want to migrate from an older version, don't hesitate to take a look at the CHANGELOG and at the migration guide.
Which is why, it's much better to keep the same instance of [System] around instead of
recreating it multiple times.
You have an example into the examples folder. You can run it with cargo run --example simple.
Otherwise, here is a little code sample:
use sysinfo::{
Components, Disks, Networks, System,
};
// Please note that we use "new_all" to ensure that all list of
// components, network interfaces, disks and users are already
// filled!
let mut sys = System::new_all();
// First we update all information of our `System` struct.
sys.refresh_all();
println!("=> system:");
// RAM and swap information:
println!("total memory: {} bytes", sys.total_memory());
println!("used memory : {} bytes", sys.used_memory());
println!("total swap : {} bytes", sys.total_swap());
println!("used swap : {} bytes", sys.used_swap());
// Display system information:
println!("System name: {:?}", System::name());
println!("System kernel version: {:?}", System::kernel_version());
println!("System OS version: {:?}", System::os_version());
println!("System host name: {:?}", System::host_name());
// Number of CPUs:
println!("NB CPUs: {}", sys.cpus().len());
// Display processes ID, name na disk usage:
for (pid, process) in sys.processes() {
println!("[{pid}] {} {:?}", process.name(), process.disk_usage());
}
// We display all disks' information:
println!("=> disks:");
let disks = Disks::new_with_refreshed_list();
for disk in &disks {
println!("{disk:?}");
}
// Network interfaces name, data received and data transmitted:
let networks = Networks::new_with_refreshed_list();
println!("=> networks:");
for (interface_name, data) in &networks {
println!("{interface_name}: {}/{} B", data.received(), data.transmitted());
}
// Components temperature:
let components = Components::new_with_refreshed_list();
println!("=> components:");
for component in &components {
println!("{component:?}");
}Please remember that to have some up-to-date information, you need to call the equivalent
refresh method. For example, for the CPU usage:
use sysinfo::System;
let mut sys = System::new();
loop {
sys.refresh_cpu(); // Refreshing CPU information.
for cpu in sys.cpus() {
print!("{}% ", cpu.cpu_usage());
}
// Sleeping to let time for the system to run for long
// enough to have useful information.
std::thread::sleep(sysinfo::MINIMUM_CPU_UPDATE_INTERVAL);
}By default, sysinfo uses multiple threads. However, this can increase the memory usage on some
platforms (macOS for example). The behavior can be disabled by setting default-features = false
in Cargo.toml (which disables the multithread cargo feature).
Most of the time, you don't want all information provided by sysinfo but just a subset of it.
In this case, it's recommended to use refresh_specifics(...) methods with only what you need
to have much better performance.
Another issues frequently encountered: unless you know what you're doing, it's almost all the
time better to instantiate the System struct once and use this one instance through your
program. The reason is because a lot of information needs a previous measure to be computed
(the CPU usage for example). Another example why it's much better: in case you want to list
all running processes, sysinfo needs to allocate all memory for the Process struct list,
which takes quite some time on the first run.
If your program needs to use a lot of file descriptors, you'd better use:
sysinfo::set_open_files_limit(0);as sysinfo keeps a number of file descriptors open to have better performance on some
targets when refreshing processes.
It'll be difficult to build on Raspberry Pi. A good way-around is to cross-build, then send the executable to your Raspberry Pi.
First install the arm toolchain, for example on Ubuntu:
> sudo apt-get install gcc-multilib-arm-linux-gnueabihfThen configure cargo to use the corresponding toolchain:
cat << EOF > ~/.cargo/config
[target.armv7-unknown-linux-gnueabihf]
linker = "arm-linux-gnueabihf-gcc"
EOFFinally, cross compile:
rustup target add armv7-unknown-linux-gnueabihf
cargo build --target=armv7-unknown-linux-gnueabihfVirtual Linux systems, such as those run through Docker and Windows Subsystem for Linux (WSL), do
not receive host hardware information via /sys/class/hwmon or /sys/class/thermal. As such,
querying for components may return no results (or unexpected results) when using this library on
virtual systems.
Apple has restrictions as to which APIs can be linked into binaries that are distributed through the app store.
By default, sysinfo is not compatible with these restrictions. You can use the apple-app-store
feature flag to disable the Apple prohibited features. This also enables the apple-sandbox feature.
In the case of applications using the sandbox outside of the app store, the apple-sandbox feature
can be used alone to avoid causing policy violations at runtime.
I wrote a blog post you can find here which explains how sysinfo extracts information
on the different systems.
It's possible to use this crate directly from C. Take a look at the Makefile and at the
examples/simple.c file.
To build the C example, just run:
> make
> ./simple
# If needed:
> LD_LIBRARY_PATH=target/debug/ ./simpleYou can run the benchmarks locally with rust nightly by doing:
> cargo benchIf you appreciate my work and want to support me, you can do it with github sponsors or with patreon.