// SPDX-License-Identifier: GPL-2.0 //! A reference-counted pointer. //! //! This module implements a way for users to create reference-counted objects and pointers to //! them. Such a pointer automatically increments and decrements the count, and drops the //! underlying object when it reaches zero. It is also safe to use concurrently from multiple //! threads. //! //! It is different from the standard library's [`Arc`] in a few ways: //! 1. It is backed by the kernel's `refcount_t` type. //! 2. It does not support weak references, which allows it to be half the size. //! 3. It saturates the reference count instead of aborting when it goes over a threshold. //! 4. It does not provide a `get_mut` method, so the ref counted object is pinned. //! //! [`Arc`]: https://doc.rust-lang.org/std/sync/struct.Arc.html use crate::{ alloc::{box_ext::BoxExt, AllocError, Flags}, error::{self, Error}, init::{self, InPlaceInit, Init, PinInit}, try_init, types::{ForeignOwnable, Opaque}, }; use alloc::boxed::Box; use core::{ alloc::Layout, fmt, marker::{PhantomData, Unsize}, mem::{ManuallyDrop, MaybeUninit}, ops::{Deref, DerefMut}, pin::Pin, ptr::NonNull, }; use macros::pin_data; mod std_vendor; /// A reference-counted pointer to an instance of `T`. /// /// The reference count is incremented when new instances of [`Arc`] are created, and decremented /// when they are dropped. When the count reaches zero, the underlying `T` is also dropped. /// /// # Invariants /// /// The reference count on an instance of [`Arc`] is always non-zero. /// The object pointed to by [`Arc`] is always pinned. /// /// # Examples /// /// ``` /// use kernel::sync::Arc; /// /// struct Example { /// a: u32, /// b: u32, /// } /// /// // Create a refcounted instance of `Example`. /// let obj = Arc::new(Example { a: 10, b: 20 }, GFP_KERNEL)?; /// /// // Get a new pointer to `obj` and increment the refcount. /// let cloned = obj.clone(); /// /// // Assert that both `obj` and `cloned` point to the same underlying object. /// assert!(core::ptr::eq(&*obj, &*cloned)); /// /// // Destroy `obj` and decrement its refcount. /// drop(obj); /// /// // Check that the values are still accessible through `cloned`. /// assert_eq!(cloned.a, 10); /// assert_eq!(cloned.b, 20); /// /// // The refcount drops to zero when `cloned` goes out of scope, and the memory is freed. /// # Ok::<(), Error>(()) /// ``` /// /// Using `Arc` as the type of `self`: /// /// ``` /// use kernel::sync::Arc; /// /// struct Example { /// a: u32, /// b: u32, /// } /// /// impl Example { /// fn take_over(self: Arc) { /// // ... /// } /// /// fn use_reference(self: &Arc) { /// // ... /// } /// } /// /// let obj = Arc::new(Example { a: 10, b: 20 }, GFP_KERNEL)?; /// obj.use_reference(); /// obj.take_over(); /// # Ok::<(), Error>(()) /// ``` /// /// Coercion from `Arc` to `Arc`: /// /// ``` /// use kernel::sync::{Arc, ArcBorrow}; /// /// trait MyTrait { /// // Trait has a function whose `self` type is `Arc`. /// fn example1(self: Arc) {} /// /// // Trait has a function whose `self` type is `ArcBorrow<'_, Self>`. /// fn example2(self: ArcBorrow<'_, Self>) {} /// } /// /// struct Example; /// impl MyTrait for Example {} /// /// // `obj` has type `Arc`. /// let obj: Arc = Arc::new(Example, GFP_KERNEL)?; /// /// // `coerced` has type `Arc`. /// let coerced: Arc = obj; /// # Ok::<(), Error>(()) /// ``` pub struct Arc { ptr: NonNull>, _p: PhantomData>, } #[pin_data] #[repr(C)] struct ArcInner { refcount: Opaque, data: T, } impl ArcInner { /// Converts a pointer to the contents of an [`Arc`] into a pointer to the [`ArcInner`]. /// /// # Safety /// /// `ptr` must have been returned by a previous call to [`Arc::into_raw`], and the `Arc` must /// not yet have been destroyed. unsafe fn container_of(ptr: *const T) -> NonNull> { let refcount_layout = Layout::new::(); // SAFETY: The caller guarantees that the pointer is valid. let val_layout = Layout::for_value(unsafe { &*ptr }); // SAFETY: We're computing the layout of a real struct that existed when compiling this // binary, so its layout is not so large that it can trigger arithmetic overflow. let val_offset = unsafe { refcount_layout.extend(val_layout).unwrap_unchecked().1 }; // Pointer casts leave the metadata unchanged. This is okay because the metadata of `T` and // `ArcInner` is the same since `ArcInner` is a struct with `T` as its last field. // // This is documented at: // . let ptr = ptr as *const ArcInner; // SAFETY: The pointer is in-bounds of an allocation both before and after offsetting the // pointer, since it originates from a previous call to `Arc::into_raw` on an `Arc` that is // still valid. let ptr = unsafe { ptr.byte_sub(val_offset) }; // SAFETY: The pointer can't be null since you can't have an `ArcInner` value at the null // address. unsafe { NonNull::new_unchecked(ptr.cast_mut()) } } } // This is to allow [`Arc`] (and variants) to be used as the type of `self`. impl core::ops::Receiver for Arc {} // This is to allow coercion from `Arc` to `Arc` if `T` can be converted to the // dynamically-sized type (DST) `U`. impl, U: ?Sized> core::ops::CoerceUnsized> for Arc {} // This is to allow `Arc` to be dispatched on when `Arc` can be coerced into `Arc`. impl, U: ?Sized> core::ops::DispatchFromDyn> for Arc {} // SAFETY: It is safe to send `Arc` to another thread when the underlying `T` is `Sync` because // it effectively means sharing `&T` (which is safe because `T` is `Sync`); additionally, it needs // `T` to be `Send` because any thread that has an `Arc` may ultimately access `T` using a // mutable reference when the reference count reaches zero and `T` is dropped. unsafe impl Send for Arc {} // SAFETY: It is safe to send `&Arc` to another thread when the underlying `T` is `Sync` // because it effectively means sharing `&T` (which is safe because `T` is `Sync`); additionally, // it needs `T` to be `Send` because any thread that has a `&Arc` may clone it and get an // `Arc` on that thread, so the thread may ultimately access `T` using a mutable reference when // the reference count reaches zero and `T` is dropped. unsafe impl Sync for Arc {} impl Arc { /// Constructs a new reference counted instance of `T`. pub fn new(contents: T, flags: Flags) -> Result { // INVARIANT: The refcount is initialised to a non-zero value. let value = ArcInner { // SAFETY: There are no safety requirements for this FFI call. refcount: Opaque::new(unsafe { bindings::REFCOUNT_INIT(1) }), data: contents, }; let inner = as BoxExt<_>>::new(value, flags)?; // SAFETY: We just created `inner` with a reference count of 1, which is owned by the new // `Arc` object. Ok(unsafe { Self::from_inner(Box::leak(inner).into()) }) } /// Use the given initializer to in-place initialize a `T`. /// /// If `T: !Unpin` it will not be able to move afterwards. #[inline] pub fn pin_init(init: impl PinInit, flags: Flags) -> error::Result where Error: From, { UniqueArc::pin_init(init, flags).map(|u| u.into()) } /// Use the given initializer to in-place initialize a `T`. /// /// This is equivalent to [`Arc::pin_init`], since an [`Arc`] is always pinned. #[inline] pub fn init(init: impl Init, flags: Flags) -> error::Result where Error: From, { UniqueArc::init(init, flags).map(|u| u.into()) } } impl Arc { /// Constructs a new [`Arc`] from an existing [`ArcInner`]. /// /// # Safety /// /// The caller must ensure that `inner` points to a valid location and has a non-zero reference /// count, one of which will be owned by the new [`Arc`] instance. unsafe fn from_inner(inner: NonNull>) -> Self { // INVARIANT: By the safety requirements, the invariants hold. Arc { ptr: inner, _p: PhantomData, } } /// Convert the [`Arc`] into a raw pointer. /// /// The raw pointer has ownership of the refcount that this Arc object owned. pub fn into_raw(self) -> *const T { let ptr = self.ptr.as_ptr(); core::mem::forget(self); // SAFETY: The pointer is valid. unsafe { core::ptr::addr_of!((*ptr).data) } } /// Recreates an [`Arc`] instance previously deconstructed via [`Arc::into_raw`]. /// /// # Safety /// /// `ptr` must have been returned by a previous call to [`Arc::into_raw`]. Additionally, it /// must not be called more than once for each previous call to [`Arc::into_raw`]. pub unsafe fn from_raw(ptr: *const T) -> Self { // SAFETY: The caller promises that this pointer originates from a call to `into_raw` on an // `Arc` that is still valid. let ptr = unsafe { ArcInner::container_of(ptr) }; // SAFETY: By the safety requirements we know that `ptr` came from `Arc::into_raw`, so the // reference count held then will be owned by the new `Arc` object. unsafe { Self::from_inner(ptr) } } /// Returns an [`ArcBorrow`] from the given [`Arc`]. /// /// This is useful when the argument of a function call is an [`ArcBorrow`] (e.g., in a method /// receiver), but we have an [`Arc`] instead. Getting an [`ArcBorrow`] is free when optimised. #[inline] pub fn as_arc_borrow(&self) -> ArcBorrow<'_, T> { // SAFETY: The constraint that the lifetime of the shared reference must outlive that of // the returned `ArcBorrow` ensures that the object remains alive and that no mutable // reference can be created. unsafe { ArcBorrow::new(self.ptr) } } /// Compare whether two [`Arc`] pointers reference the same underlying object. pub fn ptr_eq(this: &Self, other: &Self) -> bool { core::ptr::eq(this.ptr.as_ptr(), other.ptr.as_ptr()) } /// Converts this [`Arc`] into a [`UniqueArc`], or destroys it if it is not unique. /// /// When this destroys the `Arc`, it does so while properly avoiding races. This means that /// this method will never call the destructor of the value. /// /// # Examples /// /// ``` /// use kernel::sync::{Arc, UniqueArc}; /// /// let arc = Arc::new(42, GFP_KERNEL)?; /// let unique_arc = arc.into_unique_or_drop(); /// /// // The above conversion should succeed since refcount of `arc` is 1. /// assert!(unique_arc.is_some()); /// /// assert_eq!(*(unique_arc.unwrap()), 42); /// /// # Ok::<(), Error>(()) /// ``` /// /// ``` /// use kernel::sync::{Arc, UniqueArc}; /// /// let arc = Arc::new(42, GFP_KERNEL)?; /// let another = arc.clone(); /// /// let unique_arc = arc.into_unique_or_drop(); /// /// // The above conversion should fail since refcount of `arc` is >1. /// assert!(unique_arc.is_none()); /// /// # Ok::<(), Error>(()) /// ``` pub fn into_unique_or_drop(self) -> Option>> { // We will manually manage the refcount in this method, so we disable the destructor. let me = ManuallyDrop::new(self); // SAFETY: We own a refcount, so the pointer is still valid. let refcount = unsafe { me.ptr.as_ref() }.refcount.get(); // If the refcount reaches a non-zero value, then we have destroyed this `Arc` and will // return without further touching the `Arc`. If the refcount reaches zero, then there are // no other arcs, and we can create a `UniqueArc`. // // SAFETY: We own a refcount, so the pointer is not dangling. let is_zero = unsafe { bindings::refcount_dec_and_test(refcount) }; if is_zero { // SAFETY: We have exclusive access to the arc, so we can perform unsynchronized // accesses to the refcount. unsafe { core::ptr::write(refcount, bindings::REFCOUNT_INIT(1)) }; // INVARIANT: We own the only refcount to this arc, so we may create a `UniqueArc`. We // must pin the `UniqueArc` because the values was previously in an `Arc`, and they pin // their values. Some(Pin::from(UniqueArc { inner: ManuallyDrop::into_inner(me), })) } else { None } } } impl ForeignOwnable for Arc { type Borrowed<'a> = ArcBorrow<'a, T>; fn into_foreign(self) -> *const core::ffi::c_void { ManuallyDrop::new(self).ptr.as_ptr() as _ } unsafe fn borrow<'a>(ptr: *const core::ffi::c_void) -> ArcBorrow<'a, T> { // SAFETY: By the safety requirement of this function, we know that `ptr` came from // a previous call to `Arc::into_foreign`. let inner = NonNull::new(ptr as *mut ArcInner).unwrap(); // SAFETY: The safety requirements of `from_foreign` ensure that the object remains alive // for the lifetime of the returned value. unsafe { ArcBorrow::new(inner) } } unsafe fn from_foreign(ptr: *const core::ffi::c_void) -> Self { // SAFETY: By the safety requirement of this function, we know that `ptr` came from // a previous call to `Arc::into_foreign`, which guarantees that `ptr` is valid and // holds a reference count increment that is transferrable to us. unsafe { Self::from_inner(NonNull::new(ptr as _).unwrap()) } } } impl Deref for Arc { type Target = T; fn deref(&self) -> &Self::Target { // SAFETY: By the type invariant, there is necessarily a reference to the object, so it is // safe to dereference it. unsafe { &self.ptr.as_ref().data } } } impl AsRef for Arc { fn as_ref(&self) -> &T { self.deref() } } impl Clone for Arc { fn clone(&self) -> Self { // INVARIANT: C `refcount_inc` saturates the refcount, so it cannot overflow to zero. // SAFETY: By the type invariant, there is necessarily a reference to the object, so it is // safe to increment the refcount. unsafe { bindings::refcount_inc(self.ptr.as_ref().refcount.get()) }; // SAFETY: We just incremented the refcount. This increment is now owned by the new `Arc`. unsafe { Self::from_inner(self.ptr) } } } impl Drop for Arc { fn drop(&mut self) { // SAFETY: By the type invariant, there is necessarily a reference to the object. We cannot // touch `refcount` after it's decremented to a non-zero value because another thread/CPU // may concurrently decrement it to zero and free it. It is ok to have a raw pointer to // freed/invalid memory as long as it is never dereferenced. let refcount = unsafe { self.ptr.as_ref() }.refcount.get(); // INVARIANT: If the refcount reaches zero, there are no other instances of `Arc`, and // this instance is being dropped, so the broken invariant is not observable. // SAFETY: Also by the type invariant, we are allowed to decrement the refcount. let is_zero = unsafe { bindings::refcount_dec_and_test(refcount) }; if is_zero { // The count reached zero, we must free the memory. // // SAFETY: The pointer was initialised from the result of `Box::leak`. unsafe { drop(Box::from_raw(self.ptr.as_ptr())) }; } } } impl From> for Arc { fn from(item: UniqueArc) -> Self { item.inner } } impl From>> for Arc { fn from(item: Pin>) -> Self { // SAFETY: The type invariants of `Arc` guarantee that the data is pinned. unsafe { Pin::into_inner_unchecked(item).inner } } } /// A borrowed reference to an [`Arc`] instance. /// /// For cases when one doesn't ever need to increment the refcount on the allocation, it is simpler /// to use just `&T`, which we can trivially get from an [`Arc`] instance. /// /// However, when one may need to increment the refcount, it is preferable to use an `ArcBorrow` /// over `&Arc` because the latter results in a double-indirection: a pointer (shared reference) /// to a pointer ([`Arc`]) to the object (`T`). An [`ArcBorrow`] eliminates this double /// indirection while still allowing one to increment the refcount and getting an [`Arc`] when/if /// needed. /// /// # Invariants /// /// There are no mutable references to the underlying [`Arc`], and it remains valid for the /// lifetime of the [`ArcBorrow`] instance. /// /// # Example /// /// ``` /// use kernel::sync::{Arc, ArcBorrow}; /// /// struct Example; /// /// fn do_something(e: ArcBorrow<'_, Example>) -> Arc { /// e.into() /// } /// /// let obj = Arc::new(Example, GFP_KERNEL)?; /// let cloned = do_something(obj.as_arc_borrow()); /// /// // Assert that both `obj` and `cloned` point to the same underlying object. /// assert!(core::ptr::eq(&*obj, &*cloned)); /// # Ok::<(), Error>(()) /// ``` /// /// Using `ArcBorrow` as the type of `self`: /// /// ``` /// use kernel::sync::{Arc, ArcBorrow}; /// /// struct Example { /// a: u32, /// b: u32, /// } /// /// impl Example { /// fn use_reference(self: ArcBorrow<'_, Self>) { /// // ... /// } /// } /// /// let obj = Arc::new(Example { a: 10, b: 20 }, GFP_KERNEL)?; /// obj.as_arc_borrow().use_reference(); /// # Ok::<(), Error>(()) /// ``` pub struct ArcBorrow<'a, T: ?Sized + 'a> { inner: NonNull>, _p: PhantomData<&'a ()>, } // This is to allow [`ArcBorrow`] (and variants) to be used as the type of `self`. impl core::ops::Receiver for ArcBorrow<'_, T> {} // This is to allow `ArcBorrow` to be dispatched on when `ArcBorrow` can be coerced into // `ArcBorrow`. impl, U: ?Sized> core::ops::DispatchFromDyn> for ArcBorrow<'_, T> { } impl Clone for ArcBorrow<'_, T> { fn clone(&self) -> Self { *self } } impl Copy for ArcBorrow<'_, T> {} impl ArcBorrow<'_, T> { /// Creates a new [`ArcBorrow`] instance. /// /// # Safety /// /// Callers must ensure the following for the lifetime of the returned [`ArcBorrow`] instance: /// 1. That `inner` remains valid; /// 2. That no mutable references to `inner` are created. unsafe fn new(inner: NonNull>) -> Self { // INVARIANT: The safety requirements guarantee the invariants. Self { inner, _p: PhantomData, } } /// Creates an [`ArcBorrow`] to an [`Arc`] that has previously been deconstructed with /// [`Arc::into_raw`]. /// /// # Safety /// /// * The provided pointer must originate from a call to [`Arc::into_raw`]. /// * For the duration of the lifetime annotated on this `ArcBorrow`, the reference count must /// not hit zero. /// * For the duration of the lifetime annotated on this `ArcBorrow`, there must not be a /// [`UniqueArc`] reference to this value. pub unsafe fn from_raw(ptr: *const T) -> Self { // SAFETY: The caller promises that this pointer originates from a call to `into_raw` on an // `Arc` that is still valid. let ptr = unsafe { ArcInner::container_of(ptr) }; // SAFETY: The caller promises that the value remains valid since the reference count must // not hit zero, and no mutable reference will be created since that would involve a // `UniqueArc`. unsafe { Self::new(ptr) } } } impl From> for Arc { fn from(b: ArcBorrow<'_, T>) -> Self { // SAFETY: The existence of `b` guarantees that the refcount is non-zero. `ManuallyDrop` // guarantees that `drop` isn't called, so it's ok that the temporary `Arc` doesn't own the // increment. ManuallyDrop::new(unsafe { Arc::from_inner(b.inner) }) .deref() .clone() } } impl Deref for ArcBorrow<'_, T> { type Target = T; fn deref(&self) -> &Self::Target { // SAFETY: By the type invariant, the underlying object is still alive with no mutable // references to it, so it is safe to create a shared reference. unsafe { &self.inner.as_ref().data } } } /// A refcounted object that is known to have a refcount of 1. /// /// It is mutable and can be converted to an [`Arc`] so that it can be shared. /// /// # Invariants /// /// `inner` always has a reference count of 1. /// /// # Examples /// /// In the following example, we make changes to the inner object before turning it into an /// `Arc` object (after which point, it cannot be mutated directly). Note that `x.into()` /// cannot fail. /// /// ``` /// use kernel::sync::{Arc, UniqueArc}; /// /// struct Example { /// a: u32, /// b: u32, /// } /// /// fn test() -> Result> { /// let mut x = UniqueArc::new(Example { a: 10, b: 20 }, GFP_KERNEL)?; /// x.a += 1; /// x.b += 1; /// Ok(x.into()) /// } /// /// # test().unwrap(); /// ``` /// /// In the following example we first allocate memory for a refcounted `Example` but we don't /// initialise it on allocation. We do initialise it later with a call to [`UniqueArc::write`], /// followed by a conversion to `Arc`. This is particularly useful when allocation happens /// in one context (e.g., sleepable) and initialisation in another (e.g., atomic): /// /// ``` /// use kernel::sync::{Arc, UniqueArc}; /// /// struct Example { /// a: u32, /// b: u32, /// } /// /// fn test() -> Result> { /// let x = UniqueArc::new_uninit(GFP_KERNEL)?; /// Ok(x.write(Example { a: 10, b: 20 }).into()) /// } /// /// # test().unwrap(); /// ``` /// /// In the last example below, the caller gets a pinned instance of `Example` while converting to /// `Arc`; this is useful in scenarios where one needs a pinned reference during /// initialisation, for example, when initialising fields that are wrapped in locks. /// /// ``` /// use kernel::sync::{Arc, UniqueArc}; /// /// struct Example { /// a: u32, /// b: u32, /// } /// /// fn test() -> Result> { /// let mut pinned = Pin::from(UniqueArc::new(Example { a: 10, b: 20 }, GFP_KERNEL)?); /// // We can modify `pinned` because it is `Unpin`. /// pinned.as_mut().a += 1; /// Ok(pinned.into()) /// } /// /// # test().unwrap(); /// ``` pub struct UniqueArc { inner: Arc, } impl UniqueArc { /// Tries to allocate a new [`UniqueArc`] instance. pub fn new(value: T, flags: Flags) -> Result { Ok(Self { // INVARIANT: The newly-created object has a refcount of 1. inner: Arc::new(value, flags)?, }) } /// Tries to allocate a new [`UniqueArc`] instance whose contents are not initialised yet. pub fn new_uninit(flags: Flags) -> Result>, AllocError> { // INVARIANT: The refcount is initialised to a non-zero value. let inner = Box::try_init::( try_init!(ArcInner { // SAFETY: There are no safety requirements for this FFI call. refcount: Opaque::new(unsafe { bindings::REFCOUNT_INIT(1) }), data <- init::uninit::(), }? AllocError), flags, )?; Ok(UniqueArc { // INVARIANT: The newly-created object has a refcount of 1. // SAFETY: The pointer from the `Box` is valid. inner: unsafe { Arc::from_inner(Box::leak(inner).into()) }, }) } } impl UniqueArc> { /// Converts a `UniqueArc>` into a `UniqueArc` by writing a value into it. pub fn write(mut self, value: T) -> UniqueArc { self.deref_mut().write(value); // SAFETY: We just wrote the value to be initialized. unsafe { self.assume_init() } } /// Unsafely assume that `self` is initialized. /// /// # Safety /// /// The caller guarantees that the value behind this pointer has been initialized. It is /// *immediate* UB to call this when the value is not initialized. pub unsafe fn assume_init(self) -> UniqueArc { let inner = ManuallyDrop::new(self).inner.ptr; UniqueArc { // SAFETY: The new `Arc` is taking over `ptr` from `self.inner` (which won't be // dropped). The types are compatible because `MaybeUninit` is compatible with `T`. inner: unsafe { Arc::from_inner(inner.cast()) }, } } /// Initialize `self` using the given initializer. pub fn init_with(mut self, init: impl Init) -> core::result::Result, E> { // SAFETY: The supplied pointer is valid for initialization. match unsafe { init.__init(self.as_mut_ptr()) } { // SAFETY: Initialization completed successfully. Ok(()) => Ok(unsafe { self.assume_init() }), Err(err) => Err(err), } } /// Pin-initialize `self` using the given pin-initializer. pub fn pin_init_with( mut self, init: impl PinInit, ) -> core::result::Result>, E> { // SAFETY: The supplied pointer is valid for initialization and we will later pin the value // to ensure it does not move. match unsafe { init.__pinned_init(self.as_mut_ptr()) } { // SAFETY: Initialization completed successfully. Ok(()) => Ok(unsafe { self.assume_init() }.into()), Err(err) => Err(err), } } } impl From> for Pin> { fn from(obj: UniqueArc) -> Self { // SAFETY: It is not possible to move/replace `T` inside a `Pin>` (unless `T` // is `Unpin`), so it is ok to convert it to `Pin>`. unsafe { Pin::new_unchecked(obj) } } } impl Deref for UniqueArc { type Target = T; fn deref(&self) -> &Self::Target { self.inner.deref() } } impl DerefMut for UniqueArc { fn deref_mut(&mut self) -> &mut Self::Target { // SAFETY: By the `Arc` type invariant, there is necessarily a reference to the object, so // it is safe to dereference it. Additionally, we know there is only one reference when // it's inside a `UniqueArc`, so it is safe to get a mutable reference. unsafe { &mut self.inner.ptr.as_mut().data } } } impl fmt::Display for UniqueArc { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { fmt::Display::fmt(self.deref(), f) } } impl fmt::Display for Arc { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { fmt::Display::fmt(self.deref(), f) } } impl fmt::Debug for UniqueArc { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { fmt::Debug::fmt(self.deref(), f) } } impl fmt::Debug for Arc { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { fmt::Debug::fmt(self.deref(), f) } }