1 files changed, 222 insertions, 19 deletions

diff --git a/rust/kernel/task.rs b/rust/kernel/task.rs
index 5bce090a3869..7a76be583126 100644
--- a/rust/kernel/task.rs
+++ b/rust/kernel/task.rs
@@ -4,9 +4,13 @@
 //!
 //! C header: [`include/linux/sched.h`](srctree/include/linux/sched.h).
 
+use crate::{
+    bindings,
+    pid_namespace::PidNamespace,
+    types::{ARef, NotThreadSafe, Opaque},
+};
 use crate::ffi::{c_int, c_long, c_uint};
-use crate::types::Opaque;
-use core::{marker::PhantomData, ops::Deref, ptr};
+use core::{cmp::{Eq, PartialEq},ops::Deref, ptr};
 
 /// A sentinel value used for infinite timeouts.
 pub const MAX_SCHEDULE_TIMEOUT: c_long = c_long::MAX;
@@ -29,6 +33,16 @@ macro_rules! current {
     };
 }
 
+/// Returns the currently running task's pid namespace.
+#[macro_export]
+macro_rules! current_pid_ns {
+    () => {
+        // SAFETY: Deref + addr-of below create a temporary `PidNamespaceRef` that cannot outlive
+        // the caller.
+        unsafe { &*$crate::task::Task::current_pid_ns() }
+    };
+}
+
 /// Wraps the kernel's `struct task_struct`.
 ///
 /// # Invariants
@@ -90,7 +104,22 @@ unsafe impl Sync for Task {}
 /// The type of process identifiers (PIDs).
 type Pid = bindings::pid_t;
 
+/// The type of user identifiers (UIDs).
+#[derive(Copy, Clone)]
+pub struct Kuid {
+    kuid: bindings::kuid_t,
+}
+
 impl Task {
+    /// Returns a raw pointer to the current task.
+    ///
+    /// It is up to the user to use the pointer correctly.
+    #[inline]
+    pub fn current_raw() -> *mut bindings::task_struct {
+        // SAFETY: Getting the current pointer is always safe.
+        unsafe { bindings::get_current() }
+    }
+
     /// Returns a task reference for the currently executing task/thread.
     ///
     /// The recommended way to get the current task/thread is to use the
@@ -102,7 +131,7 @@ impl Task {
     pub unsafe fn current() -> impl Deref<Target = Task> {
         struct TaskRef<'a> {
             task: &'a Task,
-            _not_send: PhantomData<*mut ()>,
+            _not_send: NotThreadSafe,
         }
 
         impl Deref for TaskRef<'_> {
@@ -113,23 +142,118 @@ impl Task {
             }
         }
 
-        // SAFETY: Just an FFI call with no additional safety requirements.
-        let ptr = unsafe { bindings::get_current() };
-
+        let current = Task::current_raw();
         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,
+            task: unsafe { &*current.cast() },
+            _not_send: NotThreadSafe,
+        }
+    }
+
+    /// Returns a PidNamespace reference for the currently executing task's/thread's pid namespace.
+    ///
+    /// This function can be used to create an unbounded lifetime by e.g., storing the returned
+    /// PidNamespace in a global variable which would be a bug. So the recommended way to get the
+    /// current task's/thread's pid namespace is to use the [`current_pid_ns`] macro because it is
+    /// safe.
+    ///
+    /// # Safety
+    ///
+    /// Callers must ensure that the returned object doesn't outlive the current task/thread.
+    pub unsafe fn current_pid_ns() -> impl Deref<Target = PidNamespace> {
+        struct PidNamespaceRef<'a> {
+            task: &'a PidNamespace,
+            _not_send: NotThreadSafe,
+        }
+
+        impl Deref for PidNamespaceRef<'_> {
+            type Target = PidNamespace;
+
+            fn deref(&self) -> &Self::Target {
+                self.task
+            }
+        }
+
+        // The lifetime of `PidNamespace` is bound to `Task` and `struct pid`.
+        //
+        // The `PidNamespace` of a `Task` doesn't ever change once the `Task` is alive. A
+        // `unshare(CLONE_NEWPID)` or `setns(fd_pidns/pidfd, CLONE_NEWPID)` will not have an effect
+        // on the calling `Task`'s pid namespace. It will only effect the pid namespace of children
+        // created by the calling `Task`. This invariant guarantees that after having acquired a
+        // reference to a `Task`'s pid namespace it will remain unchanged.
+        //
+        // When a task has exited and been reaped `release_task()` will be called. This will set
+        // the `PidNamespace` of the task to `NULL`. So retrieving the `PidNamespace` of a task
+        // that is dead will return `NULL`. Note, that neither holding the RCU lock nor holding a
+        // referencing count to
+        // the `Task` will prevent `release_task()` being called.
+        //
+        // In order to retrieve the `PidNamespace` of a `Task` the `task_active_pid_ns()` function
+        // can be used. There are two cases to consider:
+        //
+        // (1) retrieving the `PidNamespace` of the `current` task
+        // (2) retrieving the `PidNamespace` of a non-`current` task
+        //
+        // From system call context retrieving the `PidNamespace` for case (1) is always safe and
+        // requires neither RCU locking nor a reference count to be held. Retrieving the
+        // `PidNamespace` after `release_task()` for current will return `NULL` but no codepath
+        // like that is exposed to Rust.
+        //
+        // Retrieving the `PidNamespace` from system call context for (2) requires RCU protection.
+        // Accessing `PidNamespace` outside of RCU protection requires a reference count that
+        // must've been acquired while holding the RCU lock. Note that accessing a non-`current`
+        // task means `NULL` can be returned as the non-`current` task could have already passed
+        // through `release_task()`.
+        //
+        // To retrieve (1) the `current_pid_ns!()` macro should be used which ensure that the
+        // returned `PidNamespace` cannot outlive the calling scope. The associated
+        // `current_pid_ns()` function should not be called directly as it could be abused to
+        // created an unbounded lifetime for `PidNamespace`. The `current_pid_ns!()` macro allows
+        // Rust to handle the common case of accessing `current`'s `PidNamespace` without RCU
+        // protection and without having to acquire a reference count.
+        //
+        // For (2) the `task_get_pid_ns()` method must be used. This will always acquire a
+        // reference on `PidNamespace` and will return an `Option` to force the caller to
+        // explicitly handle the case where `PidNamespace` is `None`, something that tends to be
+        // forgotten when doing the equivalent operation in `C`. Missing RCU primitives make it
+        // difficult to perform operations that are otherwise safe without holding a reference
+        // count as long as RCU protection is guaranteed. But it is not important currently. But we
+        // do want it in the future.
+        //
+        // Note for (2) the required RCU protection around calling `task_active_pid_ns()`
+        // synchronizes against putting the last reference of the associated `struct pid` of
+        // `task->thread_pid`. The `struct pid` stored in that field is used to retrieve the
+        // `PidNamespace` of the caller. When `release_task()` is called `task->thread_pid` will be
+        // `NULL`ed and `put_pid()` on said `struct pid` will be delayed in `free_pid()` via
+        // `call_rcu()` allowing everyone with an RCU protected access to the `struct pid` acquired
+        // from `task->thread_pid` to finish.
+        //
+        // SAFETY: The current task's pid namespace is valid as long as the current task is running.
+        let pidns = unsafe { bindings::task_active_pid_ns(Task::current_raw()) };
+        PidNamespaceRef {
+            // SAFETY: If the current thread is still running, the current task and its associated
+            // pid namespace are valid. `PidNamespaceRef` is not `Send`, so we know it cannot be
+            // transferred to another thread (where it could potentially outlive the current
+            // `Task`). The caller needs to ensure that the PidNamespaceRef doesn't outlive the
+            // current task/thread.
+            task: unsafe { PidNamespace::from_ptr(pidns) },
+            _not_send: NotThreadSafe,
         }
     }
 
+    /// Returns a raw pointer to the task.
+    #[inline]
+    pub fn as_ptr(&self) -> *mut bindings::task_struct {
+        self.0.get()
+    }
+
     /// 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 group leader of a task never changes after initialization, so reading this
+        // field is not a data race.
+        let ptr = unsafe { *ptr::addr_of!((*self.as_ptr()).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
@@ -139,23 +263,62 @@ impl Task {
 
     /// 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) }
+        // SAFETY: The pid of a task never changes after initialization, so reading this field is
+        // not a data race.
+        unsafe { *ptr::addr_of!((*self.as_ptr()).pid) }
+    }
+
+    /// Returns the UID of the given task.
+    pub fn uid(&self) -> Kuid {
+        // SAFETY: It's always safe to call `task_uid` on a valid task.
+        Kuid::from_raw(unsafe { bindings::task_uid(self.as_ptr()) })
+    }
+
+    /// Returns the effective UID of the given task.
+    pub fn euid(&self) -> Kuid {
+        // SAFETY: It's always safe to call `task_euid` on a valid task.
+        Kuid::from_raw(unsafe { bindings::task_euid(self.as_ptr()) })
     }
 
     /// Determines whether the given task has pending signals.
     pub fn signal_pending(&self) -> bool {
+        // SAFETY: It's always safe to call `signal_pending` on a valid task.
+        unsafe { bindings::signal_pending(self.as_ptr()) != 0 }
+    }
+
+    /// Returns task's pid namespace with elevated reference count
+    pub fn get_pid_ns(&self) -> Option<ARef<PidNamespace>> {
         // SAFETY: By the type invariant, we know that `self.0` is valid.
-        unsafe { bindings::signal_pending(self.0.get()) != 0 }
+        let ptr = unsafe { bindings::task_get_pid_ns(self.as_ptr()) };
+        if ptr.is_null() {
+            None
+        } else {
+            // SAFETY: `ptr` is valid by the safety requirements of this function. And we own a
+            // reference count via `task_get_pid_ns()`.
+            // CAST: `Self` is a `repr(transparent)` wrapper around `bindings::pid_namespace`.
+            Some(unsafe { ARef::from_raw(ptr::NonNull::new_unchecked(ptr.cast::<PidNamespace>())) })
+        }
+    }
+
+    /// Returns the given task's pid in the provided pid namespace.
+    #[doc(alias = "task_tgid_nr_ns")]
+    pub fn tgid_nr_ns(&self, pidns: Option<&PidNamespace>) -> Pid {
+        let pidns = match pidns {
+            Some(pidns) => pidns.as_ptr(),
+            None => core::ptr::null_mut(),
+        };
+        // SAFETY: By the type invariant, we know that `self.0` is valid. We received a valid
+        // PidNamespace that we can use as a pointer or we received an empty PidNamespace and
+        // thus pass a null pointer. The underlying C function is safe to be used with NULL
+        // pointers.
+        unsafe { bindings::task_tgid_nr_ns(self.as_ptr(), pidns) }
     }
 
     /// 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
+        // SAFETY: It's always safe to call `signal_pending` on a valid task, even if the task
         // running.
-        unsafe { bindings::wake_up_process(self.0.get()) };
+        unsafe { bindings::wake_up_process(self.as_ptr()) };
     }
 }
 
@@ -163,7 +326,7 @@ impl Task {
 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 { bindings::get_task_struct(self.as_ptr()) };
     }
 
     unsafe fn dec_ref(obj: ptr::NonNull<Self>) {
@@ -171,3 +334,43 @@ unsafe impl crate::types::AlwaysRefCounted for Task {
         unsafe { bindings::put_task_struct(obj.cast().as_ptr()) }
     }
 }
+
+impl Kuid {
+    /// Get the current euid.
+    #[inline]
+    pub fn current_euid() -> Kuid {
+        // SAFETY: Just an FFI call.
+        Self::from_raw(unsafe { bindings::current_euid() })
+    }
+
+    /// Create a `Kuid` given the raw C type.
+    #[inline]
+    pub fn from_raw(kuid: bindings::kuid_t) -> Self {
+        Self { kuid }
+    }
+
+    /// Turn this kuid into the raw C type.
+    #[inline]
+    pub fn into_raw(self) -> bindings::kuid_t {
+        self.kuid
+    }
+
+    /// Converts this kernel UID into a userspace UID.
+    ///
+    /// Uses the namespace of the current task.
+    #[inline]
+    pub fn into_uid_in_current_ns(self) -> bindings::uid_t {
+        // SAFETY: Just an FFI call.
+        unsafe { bindings::from_kuid(bindings::current_user_ns(), self.kuid) }
+    }
+}
+
+impl PartialEq for Kuid {
+    #[inline]
+    fn eq(&self, other: &Kuid) -> bool {
+        // SAFETY: Just an FFI call.
+        unsafe { bindings::uid_eq(self.kuid, other.kuid) }
+    }
+}
+
+impl Eq for Kuid {}