Merge tag 'rust-6.17' of git://git.kernel.org/pub/scm/linux/kernel/git/ojeda/linux

Pull Rust updates from Miguel Ojeda:
 "Toolchain and infrastructure:

   - Enable a set of Clippy lints: 'ptr_as_ptr', 'ptr_cast_constness',
     'as_ptr_cast_mut', 'as_underscore', 'cast_lossless' and
     'ref_as_ptr'

     These are intended to avoid type casts with the 'as' operator,
     which are quite powerful, into restricted variants that are less
     powerful and thus should help to avoid mistakes

   - Remove the 'author' key now that most instances were moved to the
     plural one in the previous cycle

  'kernel' crate:

   - New 'bug' module: add 'warn_on!' macro which reuses the existing
     'BUG'/'WARN' infrastructure, i.e. it respects the usual sysctls and
     kernel parameters:

         warn_on!(value == 42);

     To avoid duplicating the assembly code, the same strategy is
     followed as for the static branch code in order to share the
     assembly between both C and Rust

     This required a few rearrangements on C arch headers -- the
     existing C macros should still generate the same outputs, thus no
     functional change expected there

   - 'workqueue' module: add delayed work items, including a
     'DelayedWork' struct, a 'impl_has_delayed_work!' macro and an
     'enqueue_delayed' method, e.g.:

         /// Enqueue the struct for execution on the system workqueue,
         /// where its value will be printed 42 jiffies later.
         fn print_later(value: Arc<MyStruct>) {
             let _ = workqueue::system().enqueue_delayed(value, 42);
         }

   - New 'bits' module: add support for 'bit' and 'genmask' functions,
     with runtime- and compile-time variants, e.g.:

         static_assert!(0b00010000 == bit_u8(4));
         static_assert!(0b00011110 == genmask_u8(1..=4));

         assert!(checked_bit_u32(u32::BITS).is_none());

   - 'uaccess' module: add 'UserSliceReader::strcpy_into_buf', which
     reads NUL-terminated strings from userspace into a '&CStr'

     Introduce 'UserPtr' newtype, similar in purpose to '__user' in C,
     to minimize mistakes handling userspace pointers, including mixing
     them up with integers and leaking them via the 'Debug' trait. Add
     it to the prelude, too

   - Start preparations for the replacement of our custom 'CStr' type
     with the analogous type in the 'core' standard library. This will
     take place across several cycles to make it easier. For this one,
     it includes a new 'fmt' module, using upstream method names and
     some other cleanups

     Replace 'fmt!' with a re-export, which helps Clippy lint properly,
     and clean up the found 'uninlined-format-args' instances

   - 'dma' module:

      - Clarify wording and be consistent in 'coherent' nomenclature

      - Convert the 'read!()' and 'write!()' macros to return a 'Result'

      - Add 'as_slice()', 'write()' methods in 'CoherentAllocation'

      - Expose 'count()' and 'size()' in 'CoherentAllocation' and add
        the corresponding type invariants

      - Implement 'CoherentAllocation::dma_handle_with_offset()'

   - 'time' module:

      - Make 'Instant' generic over clock source. This allows the
        compiler to assert that arithmetic expressions involving the
        'Instant' use 'Instants' based on the same clock source

      - Make 'HrTimer' generic over the timer mode. 'HrTimer' timers
        take a 'Duration' or an 'Instant' when setting the expiry time,
        depending on the timer mode. With this change, the compiler can
        check the type matches the timer mode

      - Add an abstraction for 'fsleep'. 'fsleep' is a flexible sleep
        function that will select an appropriate sleep method depending
        on the requested sleep time

      - Avoid 64-bit divisions on 32-bit hardware when calculating
        timestamps

      - Seal the 'HrTimerMode' trait. This prevents users of the
        'HrTimerMode' from implementing the trait on their own types

      - Pass the correct timer mode ID to 'hrtimer_start_range_ns()'

   - 'list' module: remove 'OFFSET' constants, allowing to remove
     pointer arithmetic; now 'impl_list_item!' invokes
     'impl_has_list_links!' or 'impl_has_list_links_self_ptr!'. Other
     simplifications too

   - 'types' module: remove 'ForeignOwnable::PointedTo' in favor of a
     constant, which avoids exposing the type of the opaque pointer, and
     require 'into_foreign' to return non-null

     Remove the 'Either<L, R>' type as well. It is unused, and we want
     to encourage the use of custom enums for concrete use cases

   - 'sync' module: implement 'Borrow' and 'BorrowMut' for 'Arc' types
     to allow them to be used in generic APIs

   - 'alloc' module: implement 'Borrow' and 'BorrowMut' for 'Box<T, A>';
     and 'Borrow', 'BorrowMut' and 'Default' for 'Vec<T, A>'

   - 'Opaque' type: add 'cast_from' method to perform a restricted cast
     that cannot change the inner type and use it in callers of
     'container_of!'. Rename 'raw_get' to 'cast_into' to match it

   - 'rbtree' module: add 'is_empty' method

   - 'sync' module: new 'aref' submodule to hold 'AlwaysRefCounted' and
     'ARef', which are moved from the too general 'types' module which
     we want to reduce or eventually remove. Also fix a safety comment
     in 'static_lock_class'

  'pin-init' crate:

   - Add 'impl<T, E> [Pin]Init<T, E> for Result<T, E>', so results are
     now (pin-)initializers

   - Add 'Zeroable::init_zeroed()' that delegates to 'init_zeroed()'

   - New 'zeroed()', a safe version of 'mem::zeroed()' and also provide
     it via 'Zeroable::zeroed()'

   - Implement 'Zeroable' for 'Option<&T>', 'Option<&mut T>' and for
     'Option<[unsafe] [extern "abi"] fn(...args...) -> ret>' for
     '"Rust"' and '"C"' ABIs and up to 20 arguments

   - Changed blanket impls of 'Init' and 'PinInit' from 'impl<T, E>
     [Pin]Init<T, E> for T' to 'impl<T> [Pin]Init<T> for T'

   - Renamed 'zeroed()' to 'init_zeroed()'

   - Upstream dev news: improve CI more to deny warnings, use
     '--all-targets'. Check the synchronization status of the two
     '-next' branches in upstream and the kernel

  MAINTAINERS:

   - Add Vlastimil Babka, Liam R. Howlett, Uladzislau Rezki and Lorenzo
     Stoakes as reviewers (thanks everyone)

  And a few other cleanups and improvements"

* tag 'rust-6.17' of git://git.kernel.org/pub/scm/linux/kernel/git/ojeda/linux: (76 commits)
  rust: Add warn_on macro
  arm64/bug: Add ARCH_WARN_ASM macro for BUG/WARN asm code sharing with Rust
  riscv/bug: Add ARCH_WARN_ASM macro for BUG/WARN asm code sharing with Rust
  x86/bug: Add ARCH_WARN_ASM macro for BUG/WARN asm code sharing with Rust
  rust: kernel: move ARef and AlwaysRefCounted to sync::aref
  rust: sync: fix safety comment for `static_lock_class`
  rust: types: remove `Either<L, R>`
  rust: kernel: use `core::ffi::CStr` method names
  rust: str: add `CStr` methods matching `core::ffi::CStr`
  rust: str: remove unnecessary qualification
  rust: use `kernel::{fmt,prelude::fmt!}`
  rust: kernel: add `fmt` module
  rust: kernel: remove `fmt!`, fix clippy::uninlined-format-args
  scripts: rust: emit path candidates in panic message
  scripts: rust: replace length checks with match
  rust: list: remove nonexistent generic parameter in link
  rust: bits: add support for bits/genmask macros
  rust: list: remove OFFSET constants
  rust: list: add `impl_list_item!` examples
  rust: list: use fully qualified path
  ...

1 files changed, 154 insertions, 79 deletions

diff --git a/rust/kernel/time.rs b/rust/kernel/time.rs
index a8089a98da9e..64c8dcf548d6 100644
--- a/rust/kernel/time.rs
+++ b/rust/kernel/time.rs
@@ -24,6 +24,9 @@
 //! C header: [`include/linux/jiffies.h`](srctree/include/linux/jiffies.h).
 //! C header: [`include/linux/ktime.h`](srctree/include/linux/ktime.h).
 
+use core::marker::PhantomData;
+
+pub mod delay;
 pub mod hrtimer;
 
 /// The number of nanoseconds per microsecond.
@@ -49,26 +52,141 @@ pub fn msecs_to_jiffies(msecs: Msecs) -> Jiffies {
     unsafe { bindings::__msecs_to_jiffies(msecs) }
 }
 
+/// Trait for clock sources.
+///
+/// Selection of the clock source depends on the use case. In some cases the usage of a
+/// particular clock is mandatory, e.g. in network protocols, filesystems. In other
+/// cases the user of the clock has to decide which clock is best suited for the
+/// purpose. In most scenarios clock [`Monotonic`] is the best choice as it
+/// provides a accurate monotonic notion of time (leap second smearing ignored).
+pub trait ClockSource {
+    /// The kernel clock ID associated with this clock source.
+    ///
+    /// This constant corresponds to the C side `clockid_t` value.
+    const ID: bindings::clockid_t;
+
+    /// Get the current time from the clock source.
+    ///
+    /// The function must return a value in the range from 0 to `KTIME_MAX`.
+    fn ktime_get() -> bindings::ktime_t;
+}
+
+/// A monotonically increasing clock.
+///
+/// A nonsettable system-wide clock that represents monotonic time since as
+/// described by POSIX, "some unspecified point in the past". On Linux, that
+/// point corresponds to the number of seconds that the system has been
+/// running since it was booted.
+///
+/// The CLOCK_MONOTONIC clock is not affected by discontinuous jumps in the
+/// CLOCK_REAL (e.g., if the system administrator manually changes the
+/// clock), but is affected by frequency adjustments. This clock does not
+/// count time that the system is suspended.
+pub struct Monotonic;
+
+impl ClockSource for Monotonic {
+    const ID: bindings::clockid_t = bindings::CLOCK_MONOTONIC as bindings::clockid_t;
+
+    fn ktime_get() -> bindings::ktime_t {
+        // SAFETY: It is always safe to call `ktime_get()` outside of NMI context.
+        unsafe { bindings::ktime_get() }
+    }
+}
+
+/// A settable system-wide clock that measures real (i.e., wall-clock) time.
+///
+/// Setting this clock requires appropriate privileges. This clock is
+/// affected by discontinuous jumps in the system time (e.g., if the system
+/// administrator manually changes the clock), and by frequency adjustments
+/// performed by NTP and similar applications via adjtime(3), adjtimex(2),
+/// clock_adjtime(2), and ntp_adjtime(3). This clock normally counts the
+/// number of seconds since 1970-01-01 00:00:00 Coordinated Universal Time
+/// (UTC) except that it ignores leap seconds; near a leap second it may be
+/// adjusted by leap second smearing to stay roughly in sync with UTC. Leap
+/// second smearing applies frequency adjustments to the clock to speed up
+/// or slow down the clock to account for the leap second without
+/// discontinuities in the clock. If leap second smearing is not applied,
+/// the clock will experience discontinuity around leap second adjustment.
+pub struct RealTime;
+
+impl ClockSource for RealTime {
+    const ID: bindings::clockid_t = bindings::CLOCK_REALTIME as bindings::clockid_t;
+
+    fn ktime_get() -> bindings::ktime_t {
+        // SAFETY: It is always safe to call `ktime_get_real()` outside of NMI context.
+        unsafe { bindings::ktime_get_real() }
+    }
+}
+
+/// A monotonic that ticks while system is suspended.
+///
+/// A nonsettable system-wide clock that is identical to CLOCK_MONOTONIC,
+/// except that it also includes any time that the system is suspended. This
+/// allows applications to get a suspend-aware monotonic clock without
+/// having to deal with the complications of CLOCK_REALTIME, which may have
+/// discontinuities if the time is changed using settimeofday(2) or similar.
+pub struct BootTime;
+
+impl ClockSource for BootTime {
+    const ID: bindings::clockid_t = bindings::CLOCK_BOOTTIME as bindings::clockid_t;
+
+    fn ktime_get() -> bindings::ktime_t {
+        // SAFETY: It is always safe to call `ktime_get_boottime()` outside of NMI context.
+        unsafe { bindings::ktime_get_boottime() }
+    }
+}
+
+/// International Atomic Time.
+///
+/// A system-wide clock derived from wall-clock time but counting leap seconds.
+///
+/// This clock is coupled to CLOCK_REALTIME and will be set when CLOCK_REALTIME is
+/// set, or when the offset to CLOCK_REALTIME is changed via adjtimex(2). This
+/// usually happens during boot and **should** not happen during normal operations.
+/// However, if NTP or another application adjusts CLOCK_REALTIME by leap second
+/// smearing, this clock will not be precise during leap second smearing.
+///
+/// The acronym TAI refers to International Atomic Time.
+pub struct Tai;
+
+impl ClockSource for Tai {
+    const ID: bindings::clockid_t = bindings::CLOCK_TAI as bindings::clockid_t;
+
+    fn ktime_get() -> bindings::ktime_t {
+        // SAFETY: It is always safe to call `ktime_get_tai()` outside of NMI context.
+        unsafe { bindings::ktime_get_clocktai() }
+    }
+}
+
 /// A specific point in time.
 ///
 /// # Invariants
 ///
 /// The `inner` value is in the range from 0 to `KTIME_MAX`.
 #[repr(transparent)]
-#[derive(Copy, Clone, PartialEq, PartialOrd, Eq, Ord)]
-pub struct Instant {
+#[derive(PartialEq, PartialOrd, Eq, Ord)]
+pub struct Instant<C: ClockSource> {
     inner: bindings::ktime_t,
+    _c: PhantomData<C>,
+}
+
+impl<C: ClockSource> Clone for Instant<C> {
+    fn clone(&self) -> Self {
+        *self
+    }
 }
 
-impl Instant {
-    /// Get the current time using `CLOCK_MONOTONIC`.
+impl<C: ClockSource> Copy for Instant<C> {}
+
+impl<C: ClockSource> Instant<C> {
+    /// Get the current time from the clock source.
     #[inline]
     pub fn now() -> Self {
-        // INVARIANT: The `ktime_get()` function returns a value in the range
+        // INVARIANT: The `ClockSource::ktime_get()` function returns a value in the range
         // from 0 to `KTIME_MAX`.
         Self {
-            // SAFETY: It is always safe to call `ktime_get()` outside of NMI context.
-            inner: unsafe { bindings::ktime_get() },
+            inner: C::ktime_get(),
+            _c: PhantomData,
         }
     }
 
@@ -77,86 +195,25 @@ impl Instant {
     pub fn elapsed(&self) -> Delta {
         Self::now() - *self
     }
+
+    #[inline]
+    pub(crate) fn as_nanos(&self) -> i64 {
+        self.inner
+    }
 }
 
-impl core::ops::Sub for Instant {
+impl<C: ClockSource> core::ops::Sub for Instant<C> {
     type Output = Delta;
 
     // By the type invariant, it never overflows.
     #[inline]
-    fn sub(self, other: Instant) -> Delta {
+    fn sub(self, other: Instant<C>) -> Delta {
         Delta {
             nanos: self.inner - other.inner,
         }
     }
 }
 
-/// An identifier for a clock. Used when specifying clock sources.
-///
-///
-/// Selection of the clock depends on the use case. In some cases the usage of a
-/// particular clock is mandatory, e.g. in network protocols, filesystems.In other
-/// cases the user of the clock has to decide which clock is best suited for the
-/// purpose. In most scenarios clock [`ClockId::Monotonic`] is the best choice as it
-/// provides a accurate monotonic notion of time (leap second smearing ignored).
-#[derive(Clone, Copy, PartialEq, Eq, Debug)]
-#[repr(u32)]
-pub enum ClockId {
-    /// A settable system-wide clock that measures real (i.e., wall-clock) time.
-    ///
-    /// Setting this clock requires appropriate privileges. This clock is
-    /// affected by discontinuous jumps in the system time (e.g., if the system
-    /// administrator manually changes the clock), and by frequency adjustments
-    /// performed by NTP and similar applications via adjtime(3), adjtimex(2),
-    /// clock_adjtime(2), and ntp_adjtime(3). This clock normally counts the
-    /// number of seconds since 1970-01-01 00:00:00 Coordinated Universal Time
-    /// (UTC) except that it ignores leap seconds; near a leap second it may be
-    /// adjusted by leap second smearing to stay roughly in sync with UTC. Leap
-    /// second smearing applies frequency adjustments to the clock to speed up
-    /// or slow down the clock to account for the leap second without
-    /// discontinuities in the clock. If leap second smearing is not applied,
-    /// the clock will experience discontinuity around leap second adjustment.
-    RealTime = bindings::CLOCK_REALTIME,
-    /// A monotonically increasing clock.
-    ///
-    /// A nonsettable system-wide clock that represents monotonic time since—as
-    /// described by POSIX—"some unspecified point in the past". On Linux, that
-    /// point corresponds to the number of seconds that the system has been
-    /// running since it was booted.
-    ///
-    /// The CLOCK_MONOTONIC clock is not affected by discontinuous jumps in the
-    /// CLOCK_REAL (e.g., if the system administrator manually changes the
-    /// clock), but is affected by frequency adjustments. This clock does not
-    /// count time that the system is suspended.
-    Monotonic = bindings::CLOCK_MONOTONIC,
-    /// A monotonic that ticks while system is suspended.
-    ///
-    /// A nonsettable system-wide clock that is identical to CLOCK_MONOTONIC,
-    /// except that it also includes any time that the system is suspended. This
-    /// allows applications to get a suspend-aware monotonic clock without
-    /// having to deal with the complications of CLOCK_REALTIME, which may have
-    /// discontinuities if the time is changed using settimeofday(2) or similar.
-    BootTime = bindings::CLOCK_BOOTTIME,
-    /// International Atomic Time.
-    ///
-    /// A system-wide clock derived from wall-clock time but counting leap seconds.
-    ///
-    /// This clock is coupled to CLOCK_REALTIME and will be set when CLOCK_REALTIME is
-    /// set, or when the offset to CLOCK_REALTIME is changed via adjtimex(2). This
-    /// usually happens during boot and **should** not happen during normal operations.
-    /// However, if NTP or another application adjusts CLOCK_REALTIME by leap second
-    /// smearing, this clock will not be precise during leap second smearing.
-    ///
-    /// The acronym TAI refers to International Atomic Time.
-    TAI = bindings::CLOCK_TAI,
-}
-
-impl ClockId {
-    fn into_c(self) -> bindings::clockid_t {
-        self as bindings::clockid_t
-    }
-}
-
 /// A span of time.
 ///
 /// This struct represents a span of time, with its value stored as nanoseconds.
@@ -228,13 +285,31 @@ impl Delta {
     /// Return the smallest number of microseconds greater than or equal
     /// to the value in the [`Delta`].
     #[inline]
-    pub const fn as_micros_ceil(self) -> i64 {
-        self.as_nanos().saturating_add(NSEC_PER_USEC - 1) / NSEC_PER_USEC
+    pub fn as_micros_ceil(self) -> i64 {
+        #[cfg(CONFIG_64BIT)]
+        {
+            self.as_nanos().saturating_add(NSEC_PER_USEC - 1) / NSEC_PER_USEC
+        }
+
+        #[cfg(not(CONFIG_64BIT))]
+        // SAFETY: It is always safe to call `ktime_to_us()` with any value.
+        unsafe {
+            bindings::ktime_to_us(self.as_nanos().saturating_add(NSEC_PER_USEC - 1))
+        }
     }
 
     /// Return the number of milliseconds in the [`Delta`].
     #[inline]
-    pub const fn as_millis(self) -> i64 {
-        self.as_nanos() / NSEC_PER_MSEC
+    pub fn as_millis(self) -> i64 {
+        #[cfg(CONFIG_64BIT)]
+        {
+            self.as_nanos() / NSEC_PER_MSEC
+        }
+
+        #[cfg(not(CONFIG_64BIT))]
+        // SAFETY: It is always safe to call `ktime_to_ms()` with any value.
+        unsafe {
+            bindings::ktime_to_ms(self.as_nanos())
+        }
     }
 }