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proxmox-backup/src/tools/daemon.rs

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Rust
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//! Helpers for daemons/services.
use std::ffi::CString;
use std::future::Future;
use std::io::{Read, Write};
use std::os::raw::{c_char, c_uchar, c_int};
use std::os::unix::io::{AsRawFd, FromRawFd, IntoRawFd, RawFd};
use std::os::unix::ffi::OsStrExt;
use std::panic::UnwindSafe;
use std::pin::Pin;
use std::task::{Context, Poll};
use std::path::PathBuf;
use anyhow::{bail, format_err, Error};
use futures::future::{self, Either};
use proxmox::tools::io::{ReadExt, WriteExt};
use crate::server;
use crate::tools::{fd_change_cloexec, self};
#[link(name = "systemd")]
extern "C" {
fn sd_journal_stream_fd(identifier: *const c_uchar, priority: c_int, level_prefix: c_int) -> c_int;
}
// Unfortunately FnBox is nightly-only and Box<FnOnce> is unusable, so just use Box<Fn>...
pub type BoxedStoreFunc = Box<dyn FnMut() -> Result<String, Error> + UnwindSafe + Send>;
/// Helper trait to "store" something in the environment to be re-used after re-executing the
/// service on a reload.
pub trait Reloadable: Sized {
fn restore(var: &str) -> Result<Self, Error>;
fn get_store_func(&self) -> Result<BoxedStoreFunc, Error>;
}
/// Manages things to be stored and reloaded upon reexec.
/// Anything which should be restorable should be instantiated via this struct's `restore` method,
#[derive(Default)]
pub struct Reloader {
pre_exec: Vec<PreExecEntry>,
self_exe: PathBuf,
}
// Currently we only need environment variables for storage, but in theory we could also add
// variants which need temporary files or pipes...
struct PreExecEntry {
name: &'static str, // Feel free to change to String if necessary...
store_fn: BoxedStoreFunc,
}
impl Reloader {
pub fn new() -> Result<Self, Error> {
Ok(Self {
pre_exec: Vec::new(),
// Get the path to our executable as PathBuf
self_exe: std::fs::read_link("/proc/self/exe")?,
})
}
/// Restore an object from an environment variable of the given name, or, if none exists, uses
/// the function provided in the `or_create` parameter to instantiate the new "first" instance.
///
/// Values created via this method will be remembered for later re-execution.
pub async fn restore<T, F, U>(&mut self, name: &'static str, or_create: F) -> Result<T, Error>
where
T: Reloadable,
F: FnOnce() -> U,
U: Future<Output = Result<T, Error>>,
{
let res = match std::env::var(name) {
Ok(varstr) => T::restore(&varstr)?,
Err(std::env::VarError::NotPresent) => or_create().await?,
Err(_) => bail!("variable {} has invalid value", name),
};
self.pre_exec.push(PreExecEntry {
name,
store_fn: res.get_store_func()?,
});
Ok(res)
}
fn pre_exec(self) -> Result<(), Error> {
for mut item in self.pre_exec {
std::env::set_var(item.name, (item.store_fn)()?);
}
Ok(())
}
pub fn fork_restart(self) -> Result<(), Error> {
// Get our parameters as Vec<CString>
let args = std::env::args_os();
let mut new_args = Vec::with_capacity(args.len());
for arg in args {
new_args.push(CString::new(arg.as_bytes())?);
}
// Synchronisation pipe:
let (pold, pnew) = super::socketpair()?;
// Start ourselves in the background:
use nix::unistd::{fork, ForkResult};
match unsafe { fork() } {
Ok(ForkResult::Child) => {
// Double fork so systemd can supervise us without nagging...
match unsafe { fork() } {
Ok(ForkResult::Child) => {
std::mem::drop(pold);
// At this point we call pre-exec helpers. We must be certain that if they fail for
// whatever reason we can still call `_exit()`, so use catch_unwind.
match std::panic::catch_unwind(move || {
let mut pnew = unsafe {
std::fs::File::from_raw_fd(pnew.into_raw_fd())
};
let pid = nix::unistd::Pid::this();
if let Err(e) = unsafe { pnew.write_host_value(pid.as_raw()) } {
log::error!("failed to send new server PID to parent: {}", e);
unsafe {
libc::_exit(-1);
}
}
let mut ok = [0u8];
if let Err(e) = pnew.read_exact(&mut ok) {
log::error!("parent vanished before notifying systemd: {}", e);
unsafe {
libc::_exit(-1);
}
}
assert_eq!(ok[0], 1, "reload handshake should have sent a 1 byte");
std::mem::drop(pnew);
// Try to reopen STDOUT/STDERR journald streams to get correct PID in logs
let ident = CString::new(self.self_exe.file_name().unwrap().as_bytes()).unwrap();
let ident = ident.as_bytes();
let fd = unsafe { sd_journal_stream_fd(ident.as_ptr(), libc::LOG_INFO, 1) };
if fd >= 0 && fd != 1 {
let fd = proxmox::tools::fd::Fd(fd); // add drop handler
nix::unistd::dup2(fd.as_raw_fd(), 1)?;
} else {
log::error!("failed to update STDOUT journal redirection ({})", fd);
}
let fd = unsafe { sd_journal_stream_fd(ident.as_ptr(), libc::LOG_ERR, 1) };
if fd >= 0 && fd != 2 {
let fd = proxmox::tools::fd::Fd(fd); // add drop handler
nix::unistd::dup2(fd.as_raw_fd(), 2)?;
} else {
log::error!("failed to update STDERR journal redirection ({})", fd);
}
self.do_reexec(new_args)
})
{
Ok(Ok(())) => eprintln!("do_reexec returned!"),
Ok(Err(err)) => eprintln!("do_reexec failed: {}", err),
Err(_) => eprintln!("panic in re-exec"),
}
}
Ok(ForkResult::Parent { child }) => {
std::mem::drop((pold, pnew));
log::debug!("forked off a new server (second pid: {})", child);
}
Err(e) => log::error!("fork() failed, restart delayed: {}", e),
}
// No matter how we managed to get here, this is the time where we bail out quickly:
unsafe {
libc::_exit(-1)
}
}
Ok(ForkResult::Parent { child }) => {
log::debug!("forked off a new server (first pid: {}), waiting for 2nd pid", child);
std::mem::drop(pnew);
let mut pold = unsafe {
std::fs::File::from_raw_fd(pold.into_raw_fd())
};
let child = nix::unistd::Pid::from_raw(match unsafe { pold.read_le_value() } {
Ok(v) => v,
Err(e) => {
log::error!("failed to receive pid of double-forked child process: {}", e);
// systemd will complain but won't kill the service...
return Ok(());
}
});
if let Err(e) = systemd_notify(SystemdNotify::MainPid(child)) {
log::error!("failed to notify systemd about the new main pid: {}", e);
}
// notify child that it is now the new main process:
if let Err(e) = pold.write_all(&[1u8]) {
log::error!("child vanished during reload: {}", e);
}
Ok(())
}
Err(e) => {
log::error!("fork() failed, restart delayed: {}", e);
Ok(())
}
}
}
fn do_reexec(self, args: Vec<CString>) -> Result<(), Error> {
let exe = CString::new(self.self_exe.as_os_str().as_bytes())?;
self.pre_exec()?;
nix::unistd::setsid()?;
let args: Vec<&std::ffi::CStr> = args.iter().map(|s| s.as_ref()).collect();
nix::unistd::execvp(&exe, &args)?;
panic!("exec misbehaved");
}
}
// For now all we need to do is store and reuse a tcp listening socket:
impl Reloadable for tokio::net::TcpListener {
// NOTE: The socket must not be closed when the store-function is called:
// FIXME: We could become "independent" of the TcpListener and its reference to the file
// descriptor by `dup()`ing it (and check if the listener still exists via kcmp()?)
fn get_store_func(&self) -> Result<BoxedStoreFunc, Error> {
let mut fd_opt = Some(tools::Fd(
nix::fcntl::fcntl(self.as_raw_fd(), nix::fcntl::FcntlArg::F_DUPFD_CLOEXEC(0))?
));
Ok(Box::new(move || {
let fd = fd_opt.take().unwrap();
fd_change_cloexec(fd.as_raw_fd(), false)?;
Ok(fd.into_raw_fd().to_string())
}))
}
fn restore(var: &str) -> Result<Self, Error> {
let fd = var.parse::<u32>()
.map_err(|e| format_err!("invalid file descriptor: {}", e))?
as RawFd;
fd_change_cloexec(fd, true)?;
Ok(Self::from_std(
unsafe { std::net::TcpListener::from_raw_fd(fd) },
)?)
}
}
pub struct NotifyReady;
impl Future for NotifyReady {
type Output = Result<(), Error>;
fn poll(self: Pin<&mut Self>, _cx: &mut Context) -> Poll<Result<(), Error>> {
systemd_notify(SystemdNotify::Ready)?;
Poll::Ready(Ok(()))
}
}
/// This creates a future representing a daemon which reloads itself when receiving a SIGHUP.
/// If this is started regularly, a listening socket is created. In this case, the file descriptor
/// number will be remembered in `PROXMOX_BACKUP_LISTEN_FD`.
/// If the variable already exists, its contents will instead be used to restore the listening
/// socket. The finished listening socket is then passed to the `create_service` function which
/// can be used to setup the TLS and the HTTP daemon.
pub async fn create_daemon<F, S>(
address: std::net::SocketAddr,
create_service: F,
service_name: &str,
) -> Result<(), Error>
where
F: FnOnce(tokio::net::TcpListener, NotifyReady) -> Result<S, Error>,
S: Future<Output = ()> + Unpin,
{
let mut reloader = Reloader::new()?;
let listener: tokio::net::TcpListener = reloader.restore(
"PROXMOX_BACKUP_LISTEN_FD",
move || async move { Ok(tokio::net::TcpListener::bind(&address).await?) },
).await?;
let server_future = create_service(listener, NotifyReady)?;
let shutdown_future = server::shutdown_future();
let finish_future = match future::select(server_future, shutdown_future).await {
Either::Left((_, _)) => {
crate::tools::request_shutdown(); // make sure we are in shutdown mode
None
}
Either::Right((_, server_future)) => Some(server_future),
};
let mut reloader = Some(reloader);
if server::is_reload_request() {
log::info!("daemon reload...");
if let Err(e) = systemd_notify(SystemdNotify::Reloading) {
log::error!("failed to notify systemd about the state change: {}", e);
}
wait_service_is_state(service_name, "reloading").await?;
if let Err(e) = reloader.take().unwrap().fork_restart() {
log::error!("error during reload: {}", e);
let _ = systemd_notify(SystemdNotify::Status("error during reload".to_string()));
}
} else {
log::info!("daemon shutting down...");
}
if let Some(future) = finish_future {
future.await;
}
// FIXME: this is a hack, replace with sd_notify_barrier when available
if server::is_reload_request() {
wait_service_is_not_state(service_name, "reloading").await?;
}
log::info!("daemon shut down...");
Ok(())
}
// hack, do not use if unsure!
async fn get_service_state(service: &str) -> Result<String, Error> {
let text = match tokio::process::Command::new("systemctl")
.args(&["is-active", service])
.output()
.await
{
Ok(output) => match String::from_utf8(output.stdout) {
Ok(text) => text,
Err(err) => bail!("output of 'systemctl is-active' not valid UTF-8 - {}", err),
},
Err(err) => bail!("executing 'systemctl is-active' failed - {}", err),
};
Ok(text.trim().trim_start().to_string())
}
async fn wait_service_is_state(service: &str, state: &str) -> Result<(), Error> {
tokio::time::sleep(std::time::Duration::new(1, 0)).await;
while get_service_state(service).await? != state {
tokio::time::sleep(std::time::Duration::new(5, 0)).await;
}
Ok(())
}
async fn wait_service_is_not_state(service: &str, state: &str) -> Result<(), Error> {
tokio::time::sleep(std::time::Duration::new(1, 0)).await;
while get_service_state(service).await? == state {
tokio::time::sleep(std::time::Duration::new(5, 0)).await;
}
Ok(())
}
#[link(name = "systemd")]
extern "C" {
fn sd_notify(unset_environment: c_int, state: *const c_char) -> c_int;
}
pub enum SystemdNotify {
Ready,
Reloading,
Stopping,
Status(String),
MainPid(nix::unistd::Pid),
}
pub fn systemd_notify(state: SystemdNotify) -> Result<(), Error> {
let message = match state {
SystemdNotify::Ready => CString::new("READY=1"),
SystemdNotify::Reloading => CString::new("RELOADING=1"),
SystemdNotify::Stopping => CString::new("STOPPING=1"),
SystemdNotify::Status(msg) => CString::new(format!("STATUS={}", msg)),
SystemdNotify::MainPid(pid) => CString::new(format!("MAINPID={}", pid)),
}?;
let rc = unsafe { sd_notify(0, message.as_ptr()) };
if rc < 0 {
bail!(
"systemd_notify failed: {}",
std::io::Error::from_raw_os_error(-rc),
);
}
Ok(())
}
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