rust/kernel/task.rs - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0

 //! Tasks (threads and processes).
 //!
 //! C header: [`include/linux/sched.h`](srctree/include/linux/sched.h).

 use crate::{bindings, types::Opaque};
 use core::{marker::PhantomData, ops::Deref, ptr};

 /// Returns the currently running task.
 #[macro_export]
 macro_rules! current {
     () => {
         // SAFETY: Deref + addr-of below create a temporary `TaskRef` that cannot outlive the
         // caller.
         unsafe { &*$crate::task::Task::current() }
     };
 }

 /// Wraps the kernel's `struct task_struct`.
 ///
 /// # Invariants
 ///
 /// All instances are valid tasks created by the C portion of the kernel.
 ///
 /// Instances of this type are always ref-counted, that is, a call to `get_task_struct` ensures
 /// that the allocation remains valid at least until the matching call to `put_task_struct`.
 ///
 /// # Examples
 ///
 /// The following is an example of getting the PID of the current thread with zero additional cost
 /// when compared to the C version:
 ///
 /// ```
 /// let pid = current!().pid();
 /// ```
 ///
 /// Getting the PID of the current process, also zero additional cost:
 ///
 /// ```
 /// let pid = current!().group_leader().pid();
 /// ```
 ///
 /// Getting the current task and storing it in some struct. The reference count is automatically
 /// incremented when creating `State` and decremented when it is dropped:
 ///
 /// ```
 /// use kernel::{task::Task, types::ARef};
 ///
 /// struct State {
 ///     creator: ARef<Task>,
 ///     index: u32,
 /// }
 ///
 /// impl State {
 ///     fn new() -> Self {
 ///         Self {
 ///             creator: current!().into(),
 ///             index: 0,
 ///         }
 ///     }
 /// }
 /// ```
 #[repr(transparent)]
 pub struct Task(pub(crate) Opaque<bindings::task_struct>);

 // SAFETY: By design, the only way to access a `Task` is via the `current` function or via an
 // `ARef<Task>` obtained through the `AlwaysRefCounted` impl. This means that the only situation in
 // which a `Task` can be accessed mutably is when the refcount drops to zero and the destructor
 // runs. It is safe for that to happen on any thread, so it is ok for this type to be `Send`.
 unsafe impl Send for Task {}

 // SAFETY: It's OK to access `Task` through shared references from other threads because we're
 // either accessing properties that don't change (e.g., `pid`, `group_leader`) or that are properly
 // synchronised by C code (e.g., `signal_pending`).
 unsafe impl Sync for Task {}

 /// The type of process identifiers (PIDs).
 type Pid = bindings::pid_t;

 impl Task {
     /// Returns a task reference for the currently executing task/thread.
     ///
     /// The recommended way to get the current task/thread is to use the
     /// [`current`] macro because it is safe.
     ///
     /// # Safety
     ///
     /// Callers must ensure that the returned object doesn't outlive the current task/thread.
     pub unsafe fn current() -> impl Deref<Target = Task> {
         struct TaskRef<'a> {
             task: &'a Task,
             _not_send: PhantomData<*mut ()>,
         }

         impl Deref for TaskRef<'_> {
             type Target = Task;

             fn deref(&self) -> &Self::Target {
                 self.task
             }
         }

         // SAFETY: Just an FFI call with no additional safety requirements.
         let ptr = unsafe { bindings::get_current() };

         TaskRef {
             // SAFETY: If the current thread is still running, the current task is valid. Given
             // that `TaskRef` is not `Send`, we know it cannot be transferred to another thread
             // (where it could potentially outlive the caller).
             task: unsafe { &*ptr.cast() },
             _not_send: PhantomData,
         }
     }

     /// Returns the group leader of the given task.
     pub fn group_leader(&self) -> &Task {
         // SAFETY: By the type invariant, we know that `self.0` is a valid task. Valid tasks always
         // have a valid group_leader.
         let ptr = unsafe { *ptr::addr_of!((*self.0.get()).group_leader) };

         // SAFETY: The lifetime of the returned task reference is tied to the lifetime of `self`,
         // and given that a task has a reference to its group leader, we know it must be valid for
         // the lifetime of the returned task reference.
         unsafe { &*ptr.cast() }
     }

     /// Returns the PID of the given task.
     pub fn pid(&self) -> Pid {
         // SAFETY: By the type invariant, we know that `self.0` is a valid task. Valid tasks always
         // have a valid pid.
         unsafe { *ptr::addr_of!((*self.0.get()).pid) }
     }

     /// Determines whether the given task has pending signals.
     pub fn signal_pending(&self) -> bool {
         // SAFETY: By the type invariant, we know that `self.0` is valid.
         unsafe { bindings::signal_pending(self.0.get()) != 0 }
     }

     /// Wakes up the task.
     pub fn wake_up(&self) {
         // SAFETY: By the type invariant, we know that `self.0.get()` is non-null and valid.
         // And `wake_up_process` is safe to be called for any valid task, even if the task is
         // running.
         unsafe { bindings::wake_up_process(self.0.get()) };
     }
 }

 // SAFETY: The type invariants guarantee that `Task` is always ref-counted.
 unsafe impl crate::types::AlwaysRefCounted for Task {
     fn inc_ref(&self) {
         // SAFETY: The existence of a shared reference means that the refcount is nonzero.
         unsafe { bindings::get_task_struct(self.0.get()) };
     }

     unsafe fn dec_ref(obj: ptr::NonNull<Self>) {
         // SAFETY: The safety requirements guarantee that the refcount is nonzero.
         unsafe { bindings::put_task_struct(obj.cast().as_ptr()) }
     }
 }
	// SPDX-License-Identifier: GPL-2.0

	//! Tasks (threads and processes).
	//!
	//! C header: [`include/linux/sched.h`](srctree/include/linux/sched.h).

	use crate::{bindings, types::Opaque};
	use core::{marker::PhantomData, ops::Deref, ptr};

	/// Returns the currently running task.
	#[macro_export]
	macro_rules! current {
	() => {
	// SAFETY: Deref + addr-of below create a temporary `TaskRef` that cannot outlive the
	// caller.
	unsafe { &*$crate::task::Task::current() }
	};
	}

	/// Wraps the kernel's `struct task_struct`.
	///
	/// # Invariants
	///
	/// All instances are valid tasks created by the C portion of the kernel.
	///
	/// Instances of this type are always ref-counted, that is, a call to `get_task_struct` ensures
	/// that the allocation remains valid at least until the matching call to `put_task_struct`.
	///
	/// # Examples
	///
	/// The following is an example of getting the PID of the current thread with zero additional cost
	/// when compared to the C version:
	///
	/// ```
	/// let pid = current!().pid();
	/// ```
	///
	/// Getting the PID of the current process, also zero additional cost:
	///
	/// ```
	/// let pid = current!().group_leader().pid();
	/// ```
	///
	/// Getting the current task and storing it in some struct. The reference count is automatically
	/// incremented when creating `State` and decremented when it is dropped:
	///
	/// ```
	/// use kernel::{task::Task, types::ARef};
	///
	/// struct State {
	/// creator: ARef<Task>,
	/// index: u32,
	/// }
	///
	/// impl State {
	/// fn new() -> Self {
	/// Self {
	/// creator: current!().into(),
	/// index: 0,
	/// }
	/// }
	/// }
	/// ```
	#[repr(transparent)]
	pub struct Task(pub(crate) Opaque<bindings::task_struct>);

	// SAFETY: By design, the only way to access a `Task` is via the `current` function or via an
	// `ARef<Task>` obtained through the `AlwaysRefCounted` impl. This means that the only situation in
	// which a `Task` can be accessed mutably is when the refcount drops to zero and the destructor
	// runs. It is safe for that to happen on any thread, so it is ok for this type to be `Send`.
	unsafe impl Send for Task {}

	// SAFETY: It's OK to access `Task` through shared references from other threads because we're
	// either accessing properties that don't change (e.g., `pid`, `group_leader`) or that are properly
	// synchronised by C code (e.g., `signal_pending`).
	unsafe impl Sync for Task {}

	/// The type of process identifiers (PIDs).
	type Pid = bindings::pid_t;

	impl Task {
	/// Returns a task reference for the currently executing task/thread.
	///
	/// The recommended way to get the current task/thread is to use the
	/// [`current`] macro because it is safe.
	///
	/// # Safety
	///
	/// Callers must ensure that the returned object doesn't outlive the current task/thread.
	pub unsafe fn current() -> impl Deref<Target = Task> {
	struct TaskRef<'a> {
	task: &'a Task,
	_not_send: PhantomData<*mut ()>,
	}

	impl Deref for TaskRef<'_> {
	type Target = Task;

	fn deref(&self) -> &Self::Target {
	self.task
	}
	}

	// SAFETY: Just an FFI call with no additional safety requirements.
	let ptr = unsafe { bindings::get_current() };

	TaskRef {
	// SAFETY: If the current thread is still running, the current task is valid. Given
	// that `TaskRef` is not `Send`, we know it cannot be transferred to another thread
	// (where it could potentially outlive the caller).
	task: unsafe { &*ptr.cast() },
	_not_send: PhantomData,
	}
	}

	/// Returns the group leader of the given task.
	pub fn group_leader(&self) -> &Task {
	// SAFETY: By the type invariant, we know that `self.0` is a valid task. Valid tasks always
	// have a valid group_leader.
	let ptr = unsafe { ptr::addr_of!((self.0.get()).group_leader) };

	// SAFETY: The lifetime of the returned task reference is tied to the lifetime of `self`,
	// and given that a task has a reference to its group leader, we know it must be valid for
	// the lifetime of the returned task reference.
	unsafe { &*ptr.cast() }
	}

	/// Returns the PID of the given task.
	pub fn pid(&self) -> Pid {
	// SAFETY: By the type invariant, we know that `self.0` is a valid task. Valid tasks always
	// have a valid pid.
	unsafe { ptr::addr_of!((self.0.get()).pid) }
	}

	/// Determines whether the given task has pending signals.
	pub fn signal_pending(&self) -> bool {
	// SAFETY: By the type invariant, we know that `self.0` is valid.
	unsafe { bindings::signal_pending(self.0.get()) != 0 }
	}

	/// Wakes up the task.
	pub fn wake_up(&self) {
	// SAFETY: By the type invariant, we know that `self.0.get()` is non-null and valid.
	// And `wake_up_process` is safe to be called for any valid task, even if the task is
	// running.
	unsafe { bindings::wake_up_process(self.0.get()) };
	}
	}

	// SAFETY: The type invariants guarantee that `Task` is always ref-counted.
	unsafe impl crate::types::AlwaysRefCounted for Task {
	fn inc_ref(&self) {
	// SAFETY: The existence of a shared reference means that the refcount is nonzero.
	unsafe { bindings::get_task_struct(self.0.get()) };
	}

	unsafe fn dec_ref(obj: ptr::NonNull<Self>) {
	// SAFETY: The safety requirements guarantee that the refcount is nonzero.
	unsafe { bindings::put_task_struct(obj.cast().as_ptr()) }
	}
	}