// Copyright 2012-2014 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! Fork of Arc for Servo. This has the following advantages over std::sync::Arc: //! //! * We don't waste storage on the weak reference count. //! * We don't do extra RMU operations to handle the possibility of weak references. //! * We can experiment with arena allocation (todo). //! * We can add methods to support our custom use cases [1]. //! * We have support for dynamically-sized types (see from_header_and_iter). //! * We have support for thin arcs to unsized types (see ThinArc). //! * We have support for references to static data, which don't do any //! refcounting. //! //! [1]: https://bugzilla.mozilla.org/show_bug.cgi?id=1360883 // The semantics of `Arc` are already documented in the Rust docs, so we don't // duplicate those here. #![allow(missing_docs)] #[cfg(feature = "servo")] extern crate serde; extern crate stable_deref_trait; #[cfg(feature = "servo")] use serde::{Deserialize, Serialize}; use stable_deref_trait::{CloneStableDeref, StableDeref}; use std::alloc::{self, Layout}; use std::borrow; use std::cmp::Ordering; use std::fmt; use std::hash::{Hash, Hasher}; use std::marker::PhantomData; use std::mem::{self, align_of, size_of}; use std::ops::{Deref, DerefMut}; use std::os::raw::c_void; use std::process; use std::ptr; use std::sync::atomic; use std::sync::atomic::Ordering::{Acquire, Relaxed, Release}; use std::{isize, usize}; /// A soft limit on the amount of references that may be made to an `Arc`. /// /// Going above this limit will abort your program (although not /// necessarily) at _exactly_ `MAX_REFCOUNT + 1` references. const MAX_REFCOUNT: usize = (isize::MAX) as usize; /// Special refcount value that means the data is not reference counted, /// and that the `Arc` is really acting as a read-only static reference. const STATIC_REFCOUNT: usize = usize::MAX; /// An atomically reference counted shared pointer /// /// See the documentation for [`Arc`] in the standard library. Unlike the /// standard library `Arc`, this `Arc` does not support weak reference counting. /// /// See the discussion in https://github.com/rust-lang/rust/pull/60594 for the /// usage of PhantomData. /// /// [`Arc`]: https://doc.rust-lang.org/stable/std/sync/struct.Arc.html /// /// cbindgen:derive-eq=false /// cbindgen:derive-neq=false #[repr(C)] pub struct Arc { p: ptr::NonNull>, phantom: PhantomData, } /// An `Arc` that is known to be uniquely owned /// /// When `Arc`s are constructed, they are known to be /// uniquely owned. In such a case it is safe to mutate /// the contents of the `Arc`. Normally, one would just handle /// this by mutating the data on the stack before allocating the /// `Arc`, however it's possible the data is large or unsized /// and you need to heap-allocate it earlier in such a way /// that it can be freely converted into a regular `Arc` once you're /// done. /// /// `UniqueArc` exists for this purpose, when constructed it performs /// the same allocations necessary for an `Arc`, however it allows mutable access. /// Once the mutation is finished, you can call `.shareable()` and get a regular `Arc` /// out of it. /// /// Ignore the doctest below there's no way to skip building with refcount /// logging during doc tests (see rust-lang/rust#45599). /// /// ```rust,ignore /// # use servo_arc::UniqueArc; /// let data = [1, 2, 3, 4, 5]; /// let mut x = UniqueArc::new(data); /// x[4] = 7; // mutate! /// let y = x.shareable(); // y is an Arc /// ``` pub struct UniqueArc(Arc); impl UniqueArc { #[inline] /// Construct a new UniqueArc pub fn new(data: T) -> Self { UniqueArc(Arc::new(data)) } /// Construct an uninitialized arc #[inline] pub fn new_uninit() -> UniqueArc> { unsafe { let layout = Layout::new::>>(); let ptr = alloc::alloc(layout); let mut p = ptr::NonNull::new(ptr) .unwrap_or_else(|| alloc::handle_alloc_error(layout)) .cast::>>(); ptr::write(&mut p.as_mut().count, atomic::AtomicUsize::new(1)); #[cfg(feature = "track_alloc_size")] ptr::write(&mut p.as_mut().alloc_size, layout.size()); #[cfg(feature = "gecko_refcount_logging")] { NS_LogCtor(p.as_ptr() as *mut _, b"ServoArc\0".as_ptr() as *const _, 8) } UniqueArc(Arc { p, phantom: PhantomData, }) } } #[inline] /// Convert to a shareable Arc once we're done mutating it pub fn shareable(self) -> Arc { self.0 } } impl UniqueArc> { /// Convert to an initialized Arc. #[inline] pub unsafe fn assume_init(this: Self) -> UniqueArc { UniqueArc(Arc { p: mem::ManuallyDrop::new(this).0.p.cast(), phantom: PhantomData, }) } } impl Deref for UniqueArc { type Target = T; fn deref(&self) -> &T { &*self.0 } } impl DerefMut for UniqueArc { fn deref_mut(&mut self) -> &mut T { // We know this to be uniquely owned unsafe { &mut (*self.0.ptr()).data } } } unsafe impl Send for Arc {} unsafe impl Sync for Arc {} /// The object allocated by an Arc /// /// See https://github.com/mozilla/cbindgen/issues/937 for the derive-{eq,neq}=false. But we don't /// use those anyways so we can just disable them. /// cbindgen:derive-eq=false /// cbindgen:derive-neq=false #[repr(C)] struct ArcInner { count: atomic::AtomicUsize, // NOTE(emilio): This needs to be here so that HeaderSlice<> is deallocated properly if the // allocator relies on getting the right Layout. We don't need to track the right alignment, // since we know that statically. // // This member could be completely avoided once min_specialization feature is stable (by // implementing a trait for HeaderSlice that gives you the right layout). For now, servo-only // since Gecko doesn't need it (its allocator doesn't need the size for the alignments we care // about). See https://github.com/rust-lang/rust/issues/31844. #[cfg(feature = "track_alloc_size")] alloc_size: usize, data: T, } unsafe impl Send for ArcInner {} unsafe impl Sync for ArcInner {} /// Computes the offset of the data field within ArcInner. fn data_offset() -> usize { let size = size_of::>(); let align = align_of::(); // https://github.com/rust-lang/rust/blob/1.36.0/src/libcore/alloc.rs#L187-L207 size.wrapping_add(align).wrapping_sub(1) & !align.wrapping_sub(1) } impl Arc { /// Construct an `Arc` #[inline] pub fn new(data: T) -> Self { let layout = Layout::new::>(); let p = unsafe { let ptr = ptr::NonNull::new(alloc::alloc(layout)) .unwrap_or_else(|| alloc::handle_alloc_error(layout)) .cast::>(); ptr::write(ptr.as_ptr(), ArcInner { count: atomic::AtomicUsize::new(1), #[cfg(feature = "track_alloc_size")] alloc_size: layout.size(), data, }); ptr }; #[cfg(feature = "gecko_refcount_logging")] unsafe { // FIXME(emilio): Would be so amazing to have // std::intrinsics::type_name() around, so that we could also report // a real size. NS_LogCtor(p.as_ptr() as *mut _, b"ServoArc\0".as_ptr() as *const _, 8); } Arc { p, phantom: PhantomData, } } /// Construct an intentionally-leaked arc. #[inline] pub fn new_leaked(data: T) -> Self { let arc = Self::new(data); arc.mark_as_intentionally_leaked(); arc } /// Convert the Arc to a raw pointer, suitable for use across FFI /// /// Note: This returns a pointer to the data T, which is offset in the allocation. #[inline] pub fn into_raw(this: Self) -> *const T { let ptr = unsafe { &((*this.ptr()).data) as *const _ }; mem::forget(this); ptr } /// Reconstruct the Arc from a raw pointer obtained from into_raw() /// /// Note: This raw pointer will be offset in the allocation and must be preceded /// by the atomic count. #[inline] pub unsafe fn from_raw(ptr: *const T) -> Self { // To find the corresponding pointer to the `ArcInner` we need // to subtract the offset of the `data` field from the pointer. let ptr = (ptr as *const u8).sub(data_offset::()); Arc { p: ptr::NonNull::new_unchecked(ptr as *mut ArcInner), phantom: PhantomData, } } /// Like from_raw, but returns an addrefed arc instead. #[inline] pub unsafe fn from_raw_addrefed(ptr: *const T) -> Self { let arc = Self::from_raw(ptr); mem::forget(arc.clone()); arc } /// Create a new static Arc (one that won't reference count the object) /// and place it in the allocation provided by the specified `alloc` /// function. /// /// `alloc` must return a pointer into a static allocation suitable for /// storing data with the `Layout` passed into it. The pointer returned by /// `alloc` will not be freed. #[inline] pub unsafe fn new_static(alloc: F, data: T) -> Arc where F: FnOnce(Layout) -> *mut u8, { let layout = Layout::new::>(); let ptr = alloc(layout) as *mut ArcInner; let x = ArcInner { count: atomic::AtomicUsize::new(STATIC_REFCOUNT), #[cfg(feature = "track_alloc_size")] alloc_size: layout.size(), data, }; ptr::write(ptr, x); Arc { p: ptr::NonNull::new_unchecked(ptr), phantom: PhantomData, } } /// Produce a pointer to the data that can be converted back /// to an Arc. This is basically an `&Arc`, without the extra indirection. /// It has the benefits of an `&T` but also knows about the underlying refcount /// and can be converted into more `Arc`s if necessary. #[inline] pub fn borrow_arc<'a>(&'a self) -> ArcBorrow<'a, T> { ArcBorrow(&**self) } /// Returns the address on the heap of the Arc itself -- not the T within it -- for memory /// reporting. /// /// If this is a static reference, this returns null. pub fn heap_ptr(&self) -> *const c_void { if self.inner().count.load(Relaxed) == STATIC_REFCOUNT { ptr::null() } else { self.p.as_ptr() as *const ArcInner as *const c_void } } } impl Arc { #[inline] fn inner(&self) -> &ArcInner { // This unsafety is ok because while this arc is alive we're guaranteed // that the inner pointer is valid. Furthermore, we know that the // `ArcInner` structure itself is `Sync` because the inner data is // `Sync` as well, so we're ok loaning out an immutable pointer to these // contents. unsafe { &*self.ptr() } } #[inline(always)] fn record_drop(&self) { #[cfg(feature = "gecko_refcount_logging")] unsafe { NS_LogDtor(self.ptr() as *mut _, b"ServoArc\0".as_ptr() as *const _, 8); } } /// Marks this `Arc` as intentionally leaked for the purposes of refcount /// logging. /// /// It's a logic error to call this more than once, but it's not unsafe, as /// it'd just report negative leaks. #[inline(always)] pub fn mark_as_intentionally_leaked(&self) { self.record_drop(); } // Non-inlined part of `drop`. Just invokes the destructor and calls the // refcount logging machinery if enabled. #[inline(never)] unsafe fn drop_slow(&mut self) { self.record_drop(); let inner = self.ptr(); let layout = Layout::for_value(&*inner); #[cfg(feature = "track_alloc_size")] let layout = Layout::from_size_align_unchecked((*inner).alloc_size, layout.align()); std::ptr::drop_in_place(inner); alloc::dealloc(inner as *mut _, layout); } /// Test pointer equality between the two Arcs, i.e. they must be the _same_ /// allocation #[inline] pub fn ptr_eq(this: &Self, other: &Self) -> bool { this.ptr() as *const () == other.ptr() as *const () } fn ptr(&self) -> *mut ArcInner { self.p.as_ptr() } /// Returns a raw ptr to the underlying allocation. pub fn raw_ptr(&self) -> *const c_void { self.p.as_ptr() as *const _ } } #[cfg(feature = "gecko_refcount_logging")] extern "C" { fn NS_LogCtor( aPtr: *mut std::os::raw::c_void, aTypeName: *const std::os::raw::c_char, aSize: u32, ); fn NS_LogDtor( aPtr: *mut std::os::raw::c_void, aTypeName: *const std::os::raw::c_char, aSize: u32, ); } impl Clone for Arc { #[inline] fn clone(&self) -> Self { // NOTE(emilio): If you change anything here, make sure that the // implementation in layout/style/ServoStyleConstsInlines.h matches! // // Using a relaxed ordering to check for STATIC_REFCOUNT is safe, since // `count` never changes between STATIC_REFCOUNT and other values. if self.inner().count.load(Relaxed) != STATIC_REFCOUNT { // Using a relaxed ordering is alright here, as knowledge of the // original reference prevents other threads from erroneously deleting // the object. // // As explained in the [Boost documentation][1], Increasing the // reference counter can always be done with memory_order_relaxed: New // references to an object can only be formed from an existing // reference, and passing an existing reference from one thread to // another must already provide any required synchronization. // // [1]: (www.boost.org/doc/libs/1_55_0/doc/html/atomic/usage_examples.html) let old_size = self.inner().count.fetch_add(1, Relaxed); // However we need to guard against massive refcounts in case someone // is `mem::forget`ing Arcs. If we don't do this the count can overflow // and users will use-after free. We racily saturate to `isize::MAX` on // the assumption that there aren't ~2 billion threads incrementing // the reference count at once. This branch will never be taken in // any realistic program. // // We abort because such a program is incredibly degenerate, and we // don't care to support it. if old_size > MAX_REFCOUNT { process::abort(); } } unsafe { Arc { p: ptr::NonNull::new_unchecked(self.ptr()), phantom: PhantomData, } } } } impl Deref for Arc { type Target = T; #[inline] fn deref(&self) -> &T { &self.inner().data } } impl Arc { /// Makes a mutable reference to the `Arc`, cloning if necessary /// /// This is functionally equivalent to [`Arc::make_mut`][mm] from the standard library. /// /// If this `Arc` is uniquely owned, `make_mut()` will provide a mutable /// reference to the contents. If not, `make_mut()` will create a _new_ `Arc` /// with a copy of the contents, update `this` to point to it, and provide /// a mutable reference to its contents. /// /// This is useful for implementing copy-on-write schemes where you wish to /// avoid copying things if your `Arc` is not shared. /// /// [mm]: https://doc.rust-lang.org/stable/std/sync/struct.Arc.html#method.make_mut #[inline] pub fn make_mut(this: &mut Self) -> &mut T { if !this.is_unique() { // Another pointer exists; clone *this = Arc::new((**this).clone()); } unsafe { // This unsafety is ok because we're guaranteed that the pointer // returned is the *only* pointer that will ever be returned to T. Our // reference count is guaranteed to be 1 at this point, and we required // the Arc itself to be `mut`, so we're returning the only possible // reference to the inner data. &mut (*this.ptr()).data } } } impl Arc { /// Provides mutable access to the contents _if_ the `Arc` is uniquely owned. #[inline] pub fn get_mut(this: &mut Self) -> Option<&mut T> { if this.is_unique() { unsafe { // See make_mut() for documentation of the threadsafety here. Some(&mut (*this.ptr()).data) } } else { None } } /// Whether or not the `Arc` is a static reference. #[inline] pub fn is_static(&self) -> bool { // Using a relaxed ordering to check for STATIC_REFCOUNT is safe, since // `count` never changes between STATIC_REFCOUNT and other values. self.inner().count.load(Relaxed) == STATIC_REFCOUNT } /// Whether or not the `Arc` is uniquely owned (is the refcount 1?) and not /// a static reference. #[inline] pub fn is_unique(&self) -> bool { // See the extensive discussion in [1] for why this needs to be Acquire. // // [1] https://github.com/servo/servo/issues/21186 self.inner().count.load(Acquire) == 1 } } impl Drop for Arc { #[inline] fn drop(&mut self) { // NOTE(emilio): If you change anything here, make sure that the // implementation in layout/style/ServoStyleConstsInlines.h matches! if self.is_static() { return; } // Because `fetch_sub` is already atomic, we do not need to synchronize // with other threads unless we are going to delete the object. if self.inner().count.fetch_sub(1, Release) != 1 { return; } // FIXME(bholley): Use the updated comment when [2] is merged. // // This load is needed to prevent reordering of use of the data and // deletion of the data. Because it is marked `Release`, the decreasing // of the reference count synchronizes with this `Acquire` load. This // means that use of the data happens before decreasing the reference // count, which happens before this load, which happens before the // deletion of the data. // // As explained in the [Boost documentation][1], // // > It is important to enforce any possible access to the object in one // > thread (through an existing reference) to *happen before* deleting // > the object in a different thread. This is achieved by a "release" // > operation after dropping a reference (any access to the object // > through this reference must obviously happened before), and an // > "acquire" operation before deleting the object. // // [1]: (www.boost.org/doc/libs/1_55_0/doc/html/atomic/usage_examples.html) // [2]: https://github.com/rust-lang/rust/pull/41714 self.inner().count.load(Acquire); unsafe { self.drop_slow(); } } } impl PartialEq for Arc { fn eq(&self, other: &Arc) -> bool { Self::ptr_eq(self, other) || *(*self) == *(*other) } fn ne(&self, other: &Arc) -> bool { !Self::ptr_eq(self, other) && *(*self) != *(*other) } } impl PartialOrd for Arc { fn partial_cmp(&self, other: &Arc) -> Option { (**self).partial_cmp(&**other) } fn lt(&self, other: &Arc) -> bool { *(*self) < *(*other) } fn le(&self, other: &Arc) -> bool { *(*self) <= *(*other) } fn gt(&self, other: &Arc) -> bool { *(*self) > *(*other) } fn ge(&self, other: &Arc) -> bool { *(*self) >= *(*other) } } impl Ord for Arc { fn cmp(&self, other: &Arc) -> Ordering { (**self).cmp(&**other) } } impl Eq for Arc {} impl fmt::Display for Arc { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { fmt::Display::fmt(&**self, f) } } impl fmt::Debug for Arc { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { fmt::Debug::fmt(&**self, f) } } impl fmt::Pointer for Arc { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { fmt::Pointer::fmt(&self.ptr(), f) } } impl Default for Arc { fn default() -> Arc { Arc::new(Default::default()) } } impl Hash for Arc { fn hash(&self, state: &mut H) { (**self).hash(state) } } impl From for Arc { #[inline] fn from(t: T) -> Self { Arc::new(t) } } impl borrow::Borrow for Arc { #[inline] fn borrow(&self) -> &T { &**self } } impl AsRef for Arc { #[inline] fn as_ref(&self) -> &T { &**self } } unsafe impl StableDeref for Arc {} unsafe impl CloneStableDeref for Arc {} #[cfg(feature = "servo")] impl<'de, T: Deserialize<'de>> Deserialize<'de> for Arc { fn deserialize(deserializer: D) -> Result, D::Error> where D: ::serde::de::Deserializer<'de>, { T::deserialize(deserializer).map(Arc::new) } } #[cfg(feature = "servo")] impl Serialize for Arc { fn serialize(&self, serializer: S) -> Result where S: ::serde::ser::Serializer, { (**self).serialize(serializer) } } /// Structure to allow Arc-managing some fixed-sized data and a variably-sized /// slice in a single allocation. /// /// cbindgen:derive-eq=false /// cbindgen:derive-neq=false #[derive(Debug, Eq)] #[repr(C)] pub struct HeaderSlice { /// The fixed-sized data. pub header: H, /// The length of the slice at our end. len: usize, /// The dynamically-sized data. data: [T; 0], } impl PartialEq for HeaderSlice { fn eq(&self, other: &Self) -> bool { self.header == other.header && self.slice() == other.slice() } } impl Drop for HeaderSlice { fn drop(&mut self) { unsafe { let mut ptr = self.data_mut(); for _ in 0..self.len { std::ptr::drop_in_place(ptr); ptr = ptr.offset(1); } } } } impl HeaderSlice { /// Returns the dynamically sized slice in this HeaderSlice. #[inline(always)] pub fn slice(&self) -> &[T] { unsafe { std::slice::from_raw_parts(self.data(), self.len) } } #[inline(always)] fn data(&self) -> *const T { std::ptr::addr_of!(self.data) as *const _ } #[inline(always)] fn data_mut(&mut self) -> *mut T { std::ptr::addr_of_mut!(self.data) as *mut _ } /// Returns the dynamically sized slice in this HeaderSlice. #[inline(always)] pub fn slice_mut(&mut self) -> &mut [T] { unsafe { std::slice::from_raw_parts_mut(self.data_mut(), self.len) } } /// Returns the len of the slice. #[inline(always)] pub fn len(&self) -> usize { self.len } } impl Arc> { /// Creates an Arc for a HeaderSlice using the given header struct and /// iterator to generate the slice. /// /// `is_static` indicates whether to create a static Arc. /// /// `alloc` is used to get a pointer to the memory into which the /// dynamically sized ArcInner> value will be /// written. If `is_static` is true, then `alloc` must return a /// pointer into some static memory allocation. If it is false, /// then `alloc` must return an allocation that can be dellocated /// by calling Box::from_raw::>> on it. #[inline] pub fn from_header_and_iter_alloc( alloc: F, header: H, mut items: I, num_items: usize, is_static: bool, ) -> Self where F: FnOnce(Layout) -> *mut u8, I: Iterator, { assert_ne!(size_of::(), 0, "Need to think about ZST"); let layout = Layout::new::>>(); debug_assert!(layout.align() >= align_of::()); debug_assert!(layout.align() >= align_of::()); let array_layout = Layout::array::(num_items).expect("Overflow"); let (layout, _offset) = layout.extend(array_layout).expect("Overflow"); let p = unsafe { // Allocate the buffer. let buffer = alloc(layout); let mut p = ptr::NonNull::new(buffer) .unwrap_or_else(|| alloc::handle_alloc_error(layout)) .cast::>>(); // Write the data. // // Note that any panics here (i.e. from the iterator) are safe, since // we'll just leak the uninitialized memory. let count = if is_static { atomic::AtomicUsize::new(STATIC_REFCOUNT) } else { atomic::AtomicUsize::new(1) }; ptr::write(&mut p.as_mut().count, count); #[cfg(feature = "track_alloc_size")] ptr::write(&mut p.as_mut().alloc_size, layout.size()); ptr::write(&mut p.as_mut().data.header, header); ptr::write(&mut p.as_mut().data.len, num_items); if num_items != 0 { let mut current = std::ptr::addr_of_mut!(p.as_mut().data.data) as *mut T; for _ in 0..num_items { ptr::write( current, items .next() .expect("ExactSizeIterator over-reported length"), ); current = current.offset(1); } // We should have consumed the buffer exactly, maybe accounting // for some padding from the alignment. debug_assert!( (buffer.add(layout.size()) as usize - current as *mut u8 as usize) < layout.align() ); } assert!( items.next().is_none(), "ExactSizeIterator under-reported length" ); p }; #[cfg(feature = "gecko_refcount_logging")] unsafe { if !is_static { // FIXME(emilio): Would be so amazing to have // std::intrinsics::type_name() around. NS_LogCtor(p.as_ptr() as *mut _, b"ServoArc\0".as_ptr() as *const _, 8) } } // Return the fat Arc. assert_eq!( size_of::(), size_of::(), "The Arc should be thin" ); Arc { p, phantom: PhantomData, } } /// Creates an Arc for a HeaderSlice using the given header struct and iterator to generate the /// slice. Panics if num_items doesn't match the number of items. #[inline] pub fn from_header_and_iter_with_size(header: H, items: I, num_items: usize) -> Self where I: Iterator, { Arc::from_header_and_iter_alloc( |layout| unsafe { alloc::alloc(layout) }, header, items, num_items, /* is_static = */ false, ) } /// Creates an Arc for a HeaderSlice using the given header struct and /// iterator to generate the slice. The resulting Arc will be fat. #[inline] pub fn from_header_and_iter(header: H, items: I) -> Self where I: Iterator + ExactSizeIterator, { let len = items.len(); Self::from_header_and_iter_with_size(header, items, len) } } /// This is functionally equivalent to Arc<(H, [T])> /// /// When you create an `Arc` containing a dynamically sized type like a slice, the `Arc` is /// represented on the stack as a "fat pointer", where the length of the slice is stored alongside /// the `Arc`'s pointer. In some situations you may wish to have a thin pointer instead, perhaps /// for FFI compatibility or space efficiency. `ThinArc` solves this by storing the length in the /// allocation itself, via `HeaderSlice`. pub type ThinArc = Arc>; /// See `ArcUnion`. This is a version that works for `ThinArc`s. pub type ThinArcUnion = ArcUnion, HeaderSlice>; impl UniqueArc> { #[inline] pub fn from_header_and_iter(header: H, items: I) -> Self where I: Iterator + ExactSizeIterator, { Self(Arc::from_header_and_iter(header, items)) } #[inline] pub fn from_header_and_iter_with_size(header: H, items: I, num_items: usize) -> Self where I: Iterator, { Self(Arc::from_header_and_iter_with_size( header, items, num_items, )) } /// Returns a mutable reference to the header. pub fn header_mut(&mut self) -> &mut H { // We know this to be uniquely owned unsafe { &mut (*self.0.ptr()).data.header } } /// Returns a mutable reference to the slice. pub fn data_mut(&mut self) -> &mut [T] { // We know this to be uniquely owned unsafe { (*self.0.ptr()).data.slice_mut() } } } /// A "borrowed `Arc`". This is a pointer to /// a T that is known to have been allocated within an /// `Arc`. /// /// This is equivalent in guarantees to `&Arc`, however it is /// a bit more flexible. To obtain an `&Arc` you must have /// an `Arc` instance somewhere pinned down until we're done with it. /// It's also a direct pointer to `T`, so using this involves less pointer-chasing /// /// However, C++ code may hand us refcounted things as pointers to T directly, /// so we have to conjure up a temporary `Arc` on the stack each time. /// /// `ArcBorrow` lets us deal with borrows of known-refcounted objects /// without needing to worry about where the `Arc` is. #[derive(Debug, Eq, PartialEq)] pub struct ArcBorrow<'a, T: 'a>(&'a T); impl<'a, T> Copy for ArcBorrow<'a, T> {} impl<'a, T> Clone for ArcBorrow<'a, T> { #[inline] fn clone(&self) -> Self { *self } } impl<'a, T> ArcBorrow<'a, T> { /// Clone this as an `Arc`. This bumps the refcount. #[inline] pub fn clone_arc(&self) -> Arc { let arc = unsafe { Arc::from_raw(self.0) }; // addref it! mem::forget(arc.clone()); arc } /// For constructing from a reference known to be Arc-backed, /// e.g. if we obtain such a reference over FFI #[inline] pub unsafe fn from_ref(r: &'a T) -> Self { ArcBorrow(r) } /// Compare two `ArcBorrow`s via pointer equality. Will only return /// true if they come from the same allocation pub fn ptr_eq(this: &Self, other: &Self) -> bool { this.0 as *const T == other.0 as *const T } /// Temporarily converts |self| into a bonafide Arc and exposes it to the /// provided callback. The refcount is not modified. #[inline] pub fn with_arc(&self, f: F) -> U where F: FnOnce(&Arc) -> U, T: 'static, { // Synthesize transient Arc, which never touches the refcount. let transient = unsafe { mem::ManuallyDrop::new(Arc::from_raw(self.0)) }; // Expose the transient Arc to the callback, which may clone it if it wants. let result = f(&transient); // Forward the result. result } /// Similar to deref, but uses the lifetime |a| rather than the lifetime of /// self, which is incompatible with the signature of the Deref trait. #[inline] pub fn get(&self) -> &'a T { self.0 } } impl<'a, T> Deref for ArcBorrow<'a, T> { type Target = T; #[inline] fn deref(&self) -> &T { self.0 } } /// A tagged union that can represent `Arc` or `Arc` while only consuming a /// single word. The type is also `NonNull`, and thus can be stored in an Option /// without increasing size. /// /// This is functionally equivalent to /// `enum ArcUnion { First(Arc), Second(Arc)` but only takes up /// up a single word of stack space. /// /// This could probably be extended to support four types if necessary. pub struct ArcUnion { p: ptr::NonNull<()>, phantom_a: PhantomData, phantom_b: PhantomData, } unsafe impl Send for ArcUnion {} unsafe impl Sync for ArcUnion {} impl PartialEq for ArcUnion { fn eq(&self, other: &Self) -> bool { use crate::ArcUnionBorrow::*; match (self.borrow(), other.borrow()) { (First(x), First(y)) => x == y, (Second(x), Second(y)) => x == y, (_, _) => false, } } } impl Eq for ArcUnion {} /// This represents a borrow of an `ArcUnion`. #[derive(Debug)] pub enum ArcUnionBorrow<'a, A: 'a, B: 'a> { First(ArcBorrow<'a, A>), Second(ArcBorrow<'a, B>), } impl ArcUnion { unsafe fn new(ptr: *mut ()) -> Self { ArcUnion { p: ptr::NonNull::new_unchecked(ptr), phantom_a: PhantomData, phantom_b: PhantomData, } } /// Returns true if the two values are pointer-equal. #[inline] pub fn ptr_eq(this: &Self, other: &Self) -> bool { this.p == other.p } #[inline] pub fn ptr(&self) -> ptr::NonNull<()> { self.p } /// Returns an enum representing a borrow of either A or B. #[inline] pub fn borrow(&self) -> ArcUnionBorrow { if self.is_first() { let ptr = self.p.as_ptr() as *const ArcInner; let borrow = unsafe { ArcBorrow::from_ref(&(*ptr).data) }; ArcUnionBorrow::First(borrow) } else { let ptr = ((self.p.as_ptr() as usize) & !0x1) as *const ArcInner; let borrow = unsafe { ArcBorrow::from_ref(&(*ptr).data) }; ArcUnionBorrow::Second(borrow) } } /// Creates an `ArcUnion` from an instance of the first type. pub fn from_first(other: Arc) -> Self { let union = unsafe { Self::new(other.ptr() as *mut _) }; mem::forget(other); union } /// Creates an `ArcUnion` from an instance of the second type. pub fn from_second(other: Arc) -> Self { let union = unsafe { Self::new(((other.ptr() as usize) | 0x1) as *mut _) }; mem::forget(other); union } /// Returns true if this `ArcUnion` contains the first type. pub fn is_first(&self) -> bool { self.p.as_ptr() as usize & 0x1 == 0 } /// Returns true if this `ArcUnion` contains the second type. pub fn is_second(&self) -> bool { !self.is_first() } /// Returns a borrow of the first type if applicable, otherwise `None`. pub fn as_first(&self) -> Option> { match self.borrow() { ArcUnionBorrow::First(x) => Some(x), ArcUnionBorrow::Second(_) => None, } } /// Returns a borrow of the second type if applicable, otherwise None. pub fn as_second(&self) -> Option> { match self.borrow() { ArcUnionBorrow::First(_) => None, ArcUnionBorrow::Second(x) => Some(x), } } } impl Clone for ArcUnion { fn clone(&self) -> Self { match self.borrow() { ArcUnionBorrow::First(x) => ArcUnion::from_first(x.clone_arc()), ArcUnionBorrow::Second(x) => ArcUnion::from_second(x.clone_arc()), } } } impl Drop for ArcUnion { fn drop(&mut self) { match self.borrow() { ArcUnionBorrow::First(x) => unsafe { let _ = Arc::from_raw(&*x); }, ArcUnionBorrow::Second(x) => unsafe { let _ = Arc::from_raw(&*x); }, } } } impl fmt::Debug for ArcUnion { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { fmt::Debug::fmt(&self.borrow(), f) } } #[cfg(test)] mod tests { use super::{Arc, ThinArc}; use std::clone::Clone; use std::ops::Drop; use std::sync::atomic; use std::sync::atomic::Ordering::{Acquire, SeqCst}; #[derive(PartialEq)] struct Canary(*mut atomic::AtomicUsize); impl Drop for Canary { fn drop(&mut self) { unsafe { (*self.0).fetch_add(1, SeqCst); } } } #[test] fn empty_thin() { let x = Arc::from_header_and_iter(100u32, std::iter::empty::()); assert_eq!(x.header, 100); assert!(x.slice().is_empty()); } #[test] fn thin_assert_padding() { #[derive(Clone, Default)] #[repr(C)] struct Padded { i: u16, } // The header will have more alignment than `Padded` let items = vec![Padded { i: 0xdead }, Padded { i: 0xbeef }]; let a = ThinArc::from_header_and_iter(0i32, items.into_iter()); assert_eq!(a.len(), 2); assert_eq!(a.slice()[0].i, 0xdead); assert_eq!(a.slice()[1].i, 0xbeef); } #[test] fn slices_and_thin() { let mut canary = atomic::AtomicUsize::new(0); let c = Canary(&mut canary as *mut atomic::AtomicUsize); let v = vec![5, 6]; { let x = Arc::from_header_and_iter(c, v.into_iter()); let _ = x.clone(); let _ = x == x; } assert_eq!(canary.load(Acquire), 1); } }