vendor/nix/src/sys/timerfd.rs - toolchain/rustc - Git at Google

 //! Timer API via file descriptors.
 //!
 //! Timer FD is a Linux-only API to create timers and get expiration
 //! notifications through file descriptors.
 //!
 //! For more documentation, please read [timerfd_create(2)](https://man7.org/linux/man-pages/man2/timerfd_create.2.html).
 //!
 //! # Examples
 //!
 //! Create a new one-shot timer that expires after 1 second.
 //! ```
 //! # use std::os::unix::io::AsRawFd;
 //! # use nix::sys::timerfd::{TimerFd, ClockId, TimerFlags, TimerSetTimeFlags,
 //! #    Expiration};
 //! # use nix::sys::time::{TimeSpec, TimeValLike};
 //! # use nix::unistd::read;
 //! #
 //! // We create a new monotonic timer.
 //! let timer = TimerFd::new(ClockId::CLOCK_MONOTONIC, TimerFlags::empty())
 //!     .unwrap();
 //!
 //! // We set a new one-shot timer in 1 seconds.
 //! timer.set(
 //!     Expiration::OneShot(TimeSpec::seconds(1)),
 //!     TimerSetTimeFlags::empty()
 //! ).unwrap();
 //!
 //! // We wait for the timer to expire.
 //! timer.wait().unwrap();
 //! ```
 use crate::sys::time::timer::TimerSpec;
 pub use crate::sys::time::timer::{Expiration, TimerSetTimeFlags};
 use crate::unistd::read;
 use crate::{errno::Errno, Result};
 use libc::c_int;
 use std::os::unix::io::{AsRawFd, FromRawFd, RawFd};

 /// A timerfd instance. This is also a file descriptor, you can feed it to
 /// other interfaces consuming file descriptors, epoll for example.
 #[derive(Debug)]
 pub struct TimerFd {
     fd: RawFd,
 }

 impl AsRawFd for TimerFd {
     fn as_raw_fd(&self) -> RawFd {
         self.fd
     }
 }

 impl FromRawFd for TimerFd {
     unsafe fn from_raw_fd(fd: RawFd) -> Self {
         TimerFd { fd }
     }
 }

 libc_enum! {
     /// The type of the clock used to mark the progress of the timer. For more
     /// details on each kind of clock, please refer to [timerfd_create(2)](https://man7.org/linux/man-pages/man2/timerfd_create.2.html).
     #[repr(i32)]
     #[non_exhaustive]
     pub enum ClockId {
         /// A settable system-wide real-time clock.
         CLOCK_REALTIME,
         /// A non-settable monotonically increasing clock.
         ///
         /// Does not change after system startup.
         /// Does not measure time while the system is suspended.
         CLOCK_MONOTONIC,
         /// Like `CLOCK_MONOTONIC`, except that `CLOCK_BOOTTIME` includes the time
         /// that the system was suspended.
         CLOCK_BOOTTIME,
         /// Like `CLOCK_REALTIME`, but will wake the system if it is suspended.
         CLOCK_REALTIME_ALARM,
         /// Like `CLOCK_BOOTTIME`, but will wake the system if it is suspended.
         CLOCK_BOOTTIME_ALARM,
     }
 }

 libc_bitflags! {
     /// Additional flags to change the behaviour of the file descriptor at the
     /// time of creation.
     pub struct TimerFlags: c_int {
         /// Set the `O_NONBLOCK` flag on the open file description referred to by the new file descriptor.
         TFD_NONBLOCK;
         /// Set the `FD_CLOEXEC` flag on the file descriptor.
         TFD_CLOEXEC;
     }
 }

 impl TimerFd {
     /// Creates a new timer based on the clock defined by `clockid`. The
     /// underlying fd can be assigned specific flags with `flags` (CLOEXEC,
     /// NONBLOCK). The underlying fd will be closed on drop.
     #[doc(alias("timerfd_create"))]
     pub fn new(clockid: ClockId, flags: TimerFlags) -> Result<Self> {
         Errno::result(unsafe {
             libc::timerfd_create(clockid as i32, flags.bits())
         })
         .map(|fd| Self { fd })
     }

     /// Sets a new alarm on the timer.
     ///
     /// # Types of alarm
     ///
     /// There are 3 types of alarms you can set:
     ///
     ///   - one shot: the alarm will trigger once after the specified amount of
     /// time.
     ///     Example: I want an alarm to go off in 60s and then disable itself.
     ///
     ///   - interval: the alarm will trigger every specified interval of time.
     ///     Example: I want an alarm to go off every 60s. The alarm will first
     ///     go off 60s after I set it and every 60s after that. The alarm will
     ///     not disable itself.
     ///
     ///   - interval delayed: the alarm will trigger after a certain amount of
     ///     time and then trigger at a specified interval.
     ///     Example: I want an alarm to go off every 60s but only start in 1h.
     ///     The alarm will first trigger 1h after I set it and then every 60s
     ///     after that. The alarm will not disable itself.
     ///
     /// # Relative vs absolute alarm
     ///
     /// If you do not set any `TimerSetTimeFlags`, then the `TimeSpec` you pass
     /// to the `Expiration` you want is relative. If however you want an alarm
     /// to go off at a certain point in time, you can set `TFD_TIMER_ABSTIME`.
     /// Then the one shot TimeSpec and the delay TimeSpec of the delayed
     /// interval are going to be interpreted as absolute.
     ///
     /// # Disabling alarms
     ///
     /// Note: Only one alarm can be set for any given timer. Setting a new alarm
     /// actually removes the previous one.
     ///
     /// Note: Setting a one shot alarm with a 0s TimeSpec disables the alarm
     /// altogether.
     #[doc(alias("timerfd_settime"))]
     pub fn set(
         &self,
         expiration: Expiration,
         flags: TimerSetTimeFlags,
     ) -> Result<()> {
         let timerspec: TimerSpec = expiration.into();
         Errno::result(unsafe {
             libc::timerfd_settime(
                 self.fd,
                 flags.bits(),
                 timerspec.as_ref(),
                 std::ptr::null_mut(),
             )
         })
         .map(drop)
     }

     /// Get the parameters for the alarm currently set, if any.
     #[doc(alias("timerfd_gettime"))]
     pub fn get(&self) -> Result<Option<Expiration>> {
         let mut timerspec = TimerSpec::none();
         Errno::result(unsafe {
             libc::timerfd_gettime(self.fd, timerspec.as_mut())
         })
         .map(|_| {
             if timerspec.as_ref().it_interval.tv_sec == 0
                 && timerspec.as_ref().it_interval.tv_nsec == 0
                 && timerspec.as_ref().it_value.tv_sec == 0
                 && timerspec.as_ref().it_value.tv_nsec == 0
             {
                 None
             } else {
                 Some(timerspec.into())
             }
         })
     }

     /// Remove the alarm if any is set.
     #[doc(alias("timerfd_settime"))]
     pub fn unset(&self) -> Result<()> {
         Errno::result(unsafe {
             libc::timerfd_settime(
                 self.fd,
                 TimerSetTimeFlags::empty().bits(),
                 TimerSpec::none().as_ref(),
                 std::ptr::null_mut(),
             )
         })
         .map(drop)
     }

     /// Wait for the configured alarm to expire.
     ///
     /// Note: If the alarm is unset, then you will wait forever.
     pub fn wait(&self) -> Result<()> {
         while let Err(e) = read(self.fd, &mut [0u8; 8]) {
             if e != Errno::EINTR {
                 return Err(e);
             }
         }

         Ok(())
     }
 }

 impl Drop for TimerFd {
     fn drop(&mut self) {
         if !std::thread::panicking() {
             let result = Errno::result(unsafe { libc::close(self.fd) });
             if let Err(Errno::EBADF) = result {
                 panic!("close of TimerFd encountered EBADF");
             }
         }
     }
 }
	//! Timer API via file descriptors.
	//!
	//! Timer FD is a Linux-only API to create timers and get expiration
	//! notifications through file descriptors.
	//!
	//! For more documentation, please read [timerfd_create(2)](https://man7.org/linux/man-pages/man2/timerfd_create.2.html).
	//!
	//! # Examples
	//!
	//! Create a new one-shot timer that expires after 1 second.
	//! ```
	//! # use std::os::unix::io::AsRawFd;
	//! # use nix::sys::timerfd::{TimerFd, ClockId, TimerFlags, TimerSetTimeFlags,
	//! # Expiration};
	//! # use nix::sys::time::{TimeSpec, TimeValLike};
	//! # use nix::unistd::read;
	//! #
	//! // We create a new monotonic timer.
	//! let timer = TimerFd::new(ClockId::CLOCK_MONOTONIC, TimerFlags::empty())
	//! .unwrap();
	//!
	//! // We set a new one-shot timer in 1 seconds.
	//! timer.set(
	//! Expiration::OneShot(TimeSpec::seconds(1)),
	//! TimerSetTimeFlags::empty()
	//! ).unwrap();
	//!
	//! // We wait for the timer to expire.
	//! timer.wait().unwrap();
	//! ```
	use crate::sys::time::timer::TimerSpec;
	pub use crate::sys::time::timer::{Expiration, TimerSetTimeFlags};
	use crate::unistd::read;
	use crate::{errno::Errno, Result};
	use libc::c_int;
	use std::os::unix::io::{AsRawFd, FromRawFd, RawFd};

	/// A timerfd instance. This is also a file descriptor, you can feed it to
	/// other interfaces consuming file descriptors, epoll for example.
	#[derive(Debug)]
	pub struct TimerFd {
	fd: RawFd,
	}

	impl AsRawFd for TimerFd {
	fn as_raw_fd(&self) -> RawFd {
	self.fd
	}
	}

	impl FromRawFd for TimerFd {
	unsafe fn from_raw_fd(fd: RawFd) -> Self {
	TimerFd { fd }
	}
	}

	libc_enum! {
	/// The type of the clock used to mark the progress of the timer. For more
	/// details on each kind of clock, please refer to [timerfd_create(2)](https://man7.org/linux/man-pages/man2/timerfd_create.2.html).
	#[repr(i32)]
	#[non_exhaustive]
	pub enum ClockId {
	/// A settable system-wide real-time clock.
	CLOCK_REALTIME,
	/// A non-settable monotonically increasing clock.
	///
	/// Does not change after system startup.
	/// Does not measure time while the system is suspended.
	CLOCK_MONOTONIC,
	/// Like `CLOCK_MONOTONIC`, except that `CLOCK_BOOTTIME` includes the time
	/// that the system was suspended.
	CLOCK_BOOTTIME,
	/// Like `CLOCK_REALTIME`, but will wake the system if it is suspended.
	CLOCK_REALTIME_ALARM,
	/// Like `CLOCK_BOOTTIME`, but will wake the system if it is suspended.
	CLOCK_BOOTTIME_ALARM,
	}
	}

	libc_bitflags! {
	/// Additional flags to change the behaviour of the file descriptor at the
	/// time of creation.
	pub struct TimerFlags: c_int {
	/// Set the `O_NONBLOCK` flag on the open file description referred to by the new file descriptor.
	TFD_NONBLOCK;
	/// Set the `FD_CLOEXEC` flag on the file descriptor.
	TFD_CLOEXEC;
	}
	}

	impl TimerFd {
	/// Creates a new timer based on the clock defined by `clockid`. The
	/// underlying fd can be assigned specific flags with `flags` (CLOEXEC,
	/// NONBLOCK). The underlying fd will be closed on drop.
	#[doc(alias("timerfd_create"))]
	pub fn new(clockid: ClockId, flags: TimerFlags) -> Result<Self> {
	Errno::result(unsafe {
	libc::timerfd_create(clockid as i32, flags.bits())
	})
	.map(\|fd\| Self { fd })
	}

	/// Sets a new alarm on the timer.
	///
	/// # Types of alarm
	///
	/// There are 3 types of alarms you can set:
	///
	/// - one shot: the alarm will trigger once after the specified amount of
	/// time.
	/// Example: I want an alarm to go off in 60s and then disable itself.
	///
	/// - interval: the alarm will trigger every specified interval of time.
	/// Example: I want an alarm to go off every 60s. The alarm will first
	/// go off 60s after I set it and every 60s after that. The alarm will
	/// not disable itself.
	///
	/// - interval delayed: the alarm will trigger after a certain amount of
	/// time and then trigger at a specified interval.
	/// Example: I want an alarm to go off every 60s but only start in 1h.
	/// The alarm will first trigger 1h after I set it and then every 60s
	/// after that. The alarm will not disable itself.
	///
	/// # Relative vs absolute alarm
	///
	/// If you do not set any `TimerSetTimeFlags`, then the `TimeSpec` you pass
	/// to the `Expiration` you want is relative. If however you want an alarm
	/// to go off at a certain point in time, you can set `TFD_TIMER_ABSTIME`.
	/// Then the one shot TimeSpec and the delay TimeSpec of the delayed
	/// interval are going to be interpreted as absolute.
	///
	/// # Disabling alarms
	///
	/// Note: Only one alarm can be set for any given timer. Setting a new alarm
	/// actually removes the previous one.
	///
	/// Note: Setting a one shot alarm with a 0s TimeSpec disables the alarm
	/// altogether.
	#[doc(alias("timerfd_settime"))]
	pub fn set(
	&self,
	expiration: Expiration,
	flags: TimerSetTimeFlags,
	) -> Result<()> {
	let timerspec: TimerSpec = expiration.into();
	Errno::result(unsafe {
	libc::timerfd_settime(
	self.fd,
	flags.bits(),
	timerspec.as_ref(),
	std::ptr::null_mut(),
	)
	})
	.map(drop)
	}

	/// Get the parameters for the alarm currently set, if any.
	#[doc(alias("timerfd_gettime"))]
	pub fn get(&self) -> Result<Option<Expiration>> {
	let mut timerspec = TimerSpec::none();
	Errno::result(unsafe {
	libc::timerfd_gettime(self.fd, timerspec.as_mut())
	})
	.map(\|_\| {
	if timerspec.as_ref().it_interval.tv_sec == 0
	&& timerspec.as_ref().it_interval.tv_nsec == 0
	&& timerspec.as_ref().it_value.tv_sec == 0
	&& timerspec.as_ref().it_value.tv_nsec == 0
	{
	None
	} else {
	Some(timerspec.into())
	}
	})
	}

	/// Remove the alarm if any is set.
	#[doc(alias("timerfd_settime"))]
	pub fn unset(&self) -> Result<()> {
	Errno::result(unsafe {
	libc::timerfd_settime(
	self.fd,
	TimerSetTimeFlags::empty().bits(),
	TimerSpec::none().as_ref(),
	std::ptr::null_mut(),
	)
	})
	.map(drop)
	}

	/// Wait for the configured alarm to expire.
	///
	/// Note: If the alarm is unset, then you will wait forever.
	pub fn wait(&self) -> Result<()> {
	while let Err(e) = read(self.fd, &mut [0u8; 8]) {
	if e != Errno::EINTR {
	return Err(e);
	}
	}

	Ok(())
	}
	}

	impl Drop for TimerFd {
	fn drop(&mut self) {
	if !std::thread::panicking() {
	let result = Errno::result(unsafe { libc::close(self.fd) });
	if let Err(Errno::EBADF) = result {
	panic!("close of TimerFd encountered EBADF");
	}
	}
	}
	}