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fuchsia / third_party / rust / 08351004125c4d49aa757f2c3ec2340f7469ea91 / . / src / librustc_data_structures / owning_ref / mod.rs
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#![warn(missing_docs)]
/*!
# An owning reference.
This crate provides the _owning reference_ types `OwningRef` and `OwningRefMut`
that enables it to bundle a reference together with the owner of the data it points to.
This allows moving and dropping of a `OwningRef` without needing to recreate the reference.
This can sometimes be useful because Rust borrowing rules normally prevent
moving a type that has been moved from. For example, this kind of code gets rejected:
```compile_fail,E0515
fn return_owned_and_referenced<'a>() -> (Vec<u8>, &'a [u8]) {
let v = vec![1, 2, 3, 4];
let s = &v[1..3];
(v, s)
}
```
Even though, from a memory-layout point of view, this can be entirely safe
if the new location of the vector still lives longer than the lifetime `'a`
of the reference because the backing allocation of the vector does not change.
This library enables this safe usage by keeping the owner and the reference
bundled together in a wrapper type that ensure that lifetime constraint:
```rust
# extern crate owning_ref;
# use owning_ref::OwningRef;
# fn main() {
fn return_owned_and_referenced() -> OwningRef<Vec<u8>, [u8]> {
let v = vec![1, 2, 3, 4];
let or = OwningRef::new(v);
let or = or.map(|v| &v[1..3]);
or
}
# }
```
It works by requiring owner types to dereference to stable memory locations
and preventing mutable access to root containers, which in practice requires heap allocation
as provided by `Box<T>`, `Rc<T>`, etc.
Also provided are typedefs for common owner type combinations,
which allow for less verbose type signatures.
For example, `BoxRef<T>` instead of `OwningRef<Box<T>, T>`.
The crate also provides the more advanced `OwningHandle` type,
which allows more freedom in bundling a dependent handle object
along with the data it depends on, at the cost of some unsafe needed in the API.
See the documentation around `OwningHandle` for more details.
# Examples
## Basics
```
extern crate owning_ref;
use owning_ref::BoxRef;
fn main() {
// Create an array owned by a Box.
let arr = Box::new([1, 2, 3, 4]) as Box<[i32]>;
// Transfer into a BoxRef.
let arr: BoxRef<[i32]> = BoxRef::new(arr);
assert_eq!(&*arr, &[1, 2, 3, 4]);
// We can slice the array without losing ownership or changing type.
let arr: BoxRef<[i32]> = arr.map(|arr| &arr[1..3]);
assert_eq!(&*arr, &[2, 3]);
// Also works for Arc, Rc, String and Vec!
}
```
## Caching a reference to a struct field
```
extern crate owning_ref;
use owning_ref::BoxRef;
fn main() {
struct Foo {
tag: u32,
x: u16,
y: u16,
z: u16,
}
let foo = Foo { tag: 1, x: 100, y: 200, z: 300 };
let or = BoxRef::new(Box::new(foo)).map(|foo| {
match foo.tag {
0 => &foo.x,
1 => &foo.y,
2 => &foo.z,
_ => panic!(),
}
});
assert_eq!(*or, 200);
}
```
## Caching a reference to an entry in a vector
```
extern crate owning_ref;
use owning_ref::VecRef;
fn main() {
let v = VecRef::new(vec![1, 2, 3, 4, 5]).map(|v| &v[3]);
assert_eq!(*v, 4);
}
```
## Caching a subslice of a String
```
extern crate owning_ref;
use owning_ref::StringRef;
fn main() {
let s = StringRef::new("hello world".to_owned())
.map(|s| s.split(' ').nth(1).unwrap());
assert_eq!(&*s, "world");
}
```
## Reference counted slices that share ownership of the backing storage
```
extern crate owning_ref;
use owning_ref::RcRef;
use std::rc::Rc;
fn main() {
let rc: RcRef<[i32]> = RcRef::new(Rc::new([1, 2, 3, 4]) as Rc<[i32]>);
assert_eq!(&*rc, &[1, 2, 3, 4]);
let rc_a: RcRef<[i32]> = rc.clone().map(|s| &s[0..2]);
let rc_b = rc.clone().map(|s| &s[1..3]);
let rc_c = rc.clone().map(|s| &s[2..4]);
assert_eq!(&*rc_a, &[1, 2]);
assert_eq!(&*rc_b, &[2, 3]);
assert_eq!(&*rc_c, &[3, 4]);
let rc_c_a = rc_c.clone().map(|s| &s[1]);
assert_eq!(&*rc_c_a, &4);
}
```
## Atomic reference counted slices that share ownership of the backing storage
```
extern crate owning_ref;
use owning_ref::ArcRef;
use std::sync::Arc;
fn main() {
use std::thread;
fn par_sum(rc: ArcRef<[i32]>) -> i32 {
if rc.len() == 0 {
return 0;
} else if rc.len() == 1 {
return rc[0];
}
let mid = rc.len() / 2;
let left = rc.clone().map(|s| &s[..mid]);
let right = rc.map(|s| &s[mid..]);
let left = thread::spawn(move || par_sum(left));
let right = thread::spawn(move || par_sum(right));
left.join().unwrap() + right.join().unwrap()
}
let rc: Arc<[i32]> = Arc::new([1, 2, 3, 4]);
let rc: ArcRef<[i32]> = rc.into();
assert_eq!(par_sum(rc), 10);
}
```
## References into RAII locks
```
extern crate owning_ref;
use owning_ref::RefRef;
use std::cell::{RefCell, Ref};
fn main() {
let refcell = RefCell::new((1, 2, 3, 4));
// Also works with Mutex and RwLock
let refref = {
let refref = RefRef::new(refcell.borrow()).map(|x| &x.3);
assert_eq!(*refref, 4);
// We move the RAII lock and the reference to one of
// the subfields in the data it guards here:
refref
};
assert_eq!(*refref, 4);
drop(refref);
assert_eq!(*refcell.borrow(), (1, 2, 3, 4));
}
```
## Mutable reference
When the owned container implements `DerefMut`, it is also possible to make
a _mutable owning reference_. (e.g., with `Box`, `RefMut`, `MutexGuard`)
```
extern crate owning_ref;
use owning_ref::RefMutRefMut;
use std::cell::{RefCell, RefMut};
fn main() {
let refcell = RefCell::new((1, 2, 3, 4));
let mut refmut_refmut = {
let mut refmut_refmut = RefMutRefMut::new(refcell.borrow_mut()).map_mut(|x| &mut x.3);
assert_eq!(*refmut_refmut, 4);
*refmut_refmut *= 2;
refmut_refmut
};
assert_eq!(*refmut_refmut, 8);
*refmut_refmut *= 2;
drop(refmut_refmut);
assert_eq!(*refcell.borrow(), (1, 2, 3, 16));
}
```
*/
use std::mem;
pub use stable_deref_trait::{StableDeref as StableAddress, CloneStableDeref as CloneStableAddress};
/// An owning reference.
///
/// This wraps an owner `O` and a reference `&T` pointing
/// at something reachable from `O::Target` while keeping
/// the ability to move `self` around.
///
/// The owner is usually a pointer that points at some base type.
///
/// For more details and examples, see the module and method docs.
pub struct OwningRef<O, T: ?Sized> {
owner: O,
reference: *const T,
}
/// An mutable owning reference.
///
/// This wraps an owner `O` and a reference `&mut T` pointing
/// at something reachable from `O::Target` while keeping
/// the ability to move `self` around.
///
/// The owner is usually a pointer that points at some base type.
///
/// For more details and examples, see the module and method docs.
pub struct OwningRefMut<O, T: ?Sized> {
owner: O,
reference: *mut T,
}
/// Helper trait for an erased concrete type an owner dereferences to.
/// This is used in form of a trait object for keeping
/// something around to (virtually) call the destructor.
pub trait Erased {}
impl<T> Erased for T {}
/// Helper trait for erasing the concrete type of what an owner dereferences to,
/// for example `Box<T> -> Box<Erased>`. This would be unneeded with
/// higher kinded types support in the language.
#[allow(unused_lifetimes)]
pub unsafe trait IntoErased<'a> {
/// Owner with the dereference type substituted to `Erased`.
type Erased;
/// Performs the type erasure.
fn into_erased(self) -> Self::Erased;
}
/// Helper trait for erasing the concrete type of what an owner dereferences to,
/// for example `Box<T> -> Box<Erased + Send>`. This would be unneeded with
/// higher kinded types support in the language.
#[allow(unused_lifetimes)]
pub unsafe trait IntoErasedSend<'a> {
/// Owner with the dereference type substituted to `Erased + Send`.
type Erased: Send;
/// Performs the type erasure.
fn into_erased_send(self) -> Self::Erased;
}
/// Helper trait for erasing the concrete type of what an owner dereferences to,
/// for example `Box<T> -> Box<Erased + Send + Sync>`. This would be unneeded with
/// higher kinded types support in the language.
#[allow(unused_lifetimes)]
pub unsafe trait IntoErasedSendSync<'a> {
/// Owner with the dereference type substituted to `Erased + Send + Sync`.
type Erased: Send + Sync;
/// Performs the type erasure.
fn into_erased_send_sync(self) -> Self::Erased;
}
/////////////////////////////////////////////////////////////////////////////
// OwningRef
/////////////////////////////////////////////////////////////////////////////
impl<O, T: ?Sized> OwningRef<O, T> {
/// Creates a new owning reference from a owner
/// initialized to the direct dereference of it.
///
/// # Example
/// ```
/// extern crate owning_ref;
/// use owning_ref::OwningRef;
///
/// fn main() {
/// let owning_ref = OwningRef::new(Box::new(42));
/// assert_eq!(*owning_ref, 42);
/// }
/// ```
pub fn new(o: O) -> Self
where O: StableAddress,
O: Deref<Target = T>,
{
OwningRef {
reference: &*o,
owner: o,
}
}
/// Like `new`, but doesn’t require `O` to implement the `StableAddress` trait.
/// Instead, the caller is responsible to make the same promises as implementing the trait.
///
/// This is useful for cases where coherence rules prevents implementing the trait
/// without adding a dependency to this crate in a third-party library.
pub unsafe fn new_assert_stable_address(o: O) -> Self
where O: Deref<Target = T>,
{
OwningRef {
reference: &*o,
owner: o,
}
}
/// Converts `self` into a new owning reference that points at something reachable
/// from the previous one.
///
/// This can be a reference to a field of `U`, something reachable from a field of
/// `U`, or even something unrelated with a `'static` lifetime.
///
/// # Example
/// ```
/// extern crate owning_ref;
/// use owning_ref::OwningRef;
///
/// fn main() {
/// let owning_ref = OwningRef::new(Box::new([1, 2, 3, 4]));
///
/// // create a owning reference that points at the
/// // third element of the array.
/// let owning_ref = owning_ref.map(|array| &array[2]);
/// assert_eq!(*owning_ref, 3);
/// }
/// ```
pub fn map<F, U: ?Sized>(self, f: F) -> OwningRef<O, U>
where O: StableAddress,
F: FnOnce(&T) -> &U
{
OwningRef {
reference: f(&self),
owner: self.owner,
}
}
/// Tries to convert `self` into a new owning reference that points
/// at something reachable from the previous one.
///
/// This can be a reference to a field of `U`, something reachable from a field of
/// `U`, or even something unrelated with a `'static` lifetime.
///
/// # Example
/// ```
/// extern crate owning_ref;
/// use owning_ref::OwningRef;
///
/// fn main() {
/// let owning_ref = OwningRef::new(Box::new([1, 2, 3, 4]));
///
/// // create a owning reference that points at the
/// // third element of the array.
/// let owning_ref = owning_ref.try_map(|array| {
/// if array[2] == 3 { Ok(&array[2]) } else { Err(()) }
/// });
/// assert_eq!(*owning_ref.unwrap(), 3);
/// }
/// ```
pub fn try_map<F, U: ?Sized, E>(self, f: F) -> Result<OwningRef<O, U>, E>
where O: StableAddress,
F: FnOnce(&T) -> Result<&U, E>
{
Ok(OwningRef {
reference: f(&self)?,
owner: self.owner,
})
}
/// Converts `self` into a new owning reference with a different owner type.
///
/// The new owner type needs to still contain the original owner in some way
/// so that the reference into it remains valid. This function is marked unsafe
/// because the user needs to manually uphold this guarantee.
pub unsafe fn map_owner<F, P>(self, f: F) -> OwningRef<P, T>
where O: StableAddress,
P: StableAddress,
F: FnOnce(O) -> P
{
OwningRef {
reference: self.reference,
owner: f(self.owner),
}
}
/// Converts `self` into a new owning reference where the owner is wrapped
/// in an additional `Box<O>`.
///
/// This can be used to safely erase the owner of any `OwningRef<O, T>`
/// to a `OwningRef<Box<Erased>, T>`.
pub fn map_owner_box(self) -> OwningRef<Box<O>, T> {
OwningRef {
reference: self.reference,
owner: Box::new(self.owner),
}
}
/// Erases the concrete base type of the owner with a trait object.
///
/// This allows mixing of owned references with different owner base types.
///
/// # Example
/// ```
/// extern crate owning_ref;
/// use owning_ref::{OwningRef, Erased};
///
/// fn main() {
/// // N.B., using the concrete types here for explicitness.
/// // For less verbose code type aliases like `BoxRef` are provided.
///
/// let owning_ref_a: OwningRef<Box<[i32; 4]>, [i32; 4]>
/// = OwningRef::new(Box::new([1, 2, 3, 4]));
///
/// let owning_ref_b: OwningRef<Box<Vec<(i32, bool)>>, Vec<(i32, bool)>>
/// = OwningRef::new(Box::new(vec![(0, false), (1, true)]));
///
/// let owning_ref_a: OwningRef<Box<[i32; 4]>, i32>
/// = owning_ref_a.map(|a| &a[0]);
///
/// let owning_ref_b: OwningRef<Box<Vec<(i32, bool)>>, i32>
/// = owning_ref_b.map(|a| &a[1].0);
///
/// let owning_refs: [OwningRef<Box<Erased>, i32>; 2]
/// = [owning_ref_a.erase_owner(), owning_ref_b.erase_owner()];
///
/// assert_eq!(*owning_refs[0], 1);
/// assert_eq!(*owning_refs[1], 1);
/// }
/// ```
pub fn erase_owner<'a>(self) -> OwningRef<O::Erased, T>
where O: IntoErased<'a>,
{
OwningRef {
reference: self.reference,
owner: self.owner.into_erased(),
}
}
/// Erases the concrete base type of the owner with a trait object which implements `Send`.
///
/// This allows mixing of owned references with different owner base types.
pub fn erase_send_owner<'a>(self) -> OwningRef<O::Erased, T>
where O: IntoErasedSend<'a>,
{
OwningRef {
reference: self.reference,
owner: self.owner.into_erased_send(),
}
}
/// Erases the concrete base type of the owner with a trait object
/// which implements `Send` and `Sync`.
///
/// This allows mixing of owned references with different owner base types.
pub fn erase_send_sync_owner<'a>(self) -> OwningRef<O::Erased, T>
where O: IntoErasedSendSync<'a>,
{
OwningRef {
reference: self.reference,
owner: self.owner.into_erased_send_sync(),
}
}
// UNIMPLEMENTED: wrap_owner
// FIXME: Naming convention?
/// A getter for the underlying owner.
pub fn owner(&self) -> &O {
&self.owner
}
// FIXME: Naming convention?
/// Discards the reference and retrieves the owner.
pub fn into_inner(self) -> O {
self.owner
}
}
impl<O, T: ?Sized> OwningRefMut<O, T> {
/// Creates a new owning reference from a owner
/// initialized to the direct dereference of it.
///
/// # Example
/// ```
/// extern crate owning_ref;
/// use owning_ref::OwningRefMut;
///
/// fn main() {
/// let owning_ref_mut = OwningRefMut::new(Box::new(42));
/// assert_eq!(*owning_ref_mut, 42);
/// }
/// ```
pub fn new(mut o: O) -> Self
where O: StableAddress,
O: DerefMut<Target = T>,
{
OwningRefMut {
reference: &mut *o,
owner: o,
}
}
/// Like `new`, but doesn’t require `O` to implement the `StableAddress` trait.
/// Instead, the caller is responsible to make the same promises as implementing the trait.
///
/// This is useful for cases where coherence rules prevents implementing the trait
/// without adding a dependency to this crate in a third-party library.
pub unsafe fn new_assert_stable_address(mut o: O) -> Self
where O: DerefMut<Target = T>,
{
OwningRefMut {
reference: &mut *o,
owner: o,
}
}
/// Converts `self` into a new _shared_ owning reference that points at
/// something reachable from the previous one.
///
/// This can be a reference to a field of `U`, something reachable from a field of
/// `U`, or even something unrelated with a `'static` lifetime.
///
/// # Example
/// ```
/// extern crate owning_ref;
/// use owning_ref::OwningRefMut;
///
/// fn main() {
/// let owning_ref_mut = OwningRefMut::new(Box::new([1, 2, 3, 4]));
///
/// // create a owning reference that points at the
/// // third element of the array.
/// let owning_ref = owning_ref_mut.map(|array| &array[2]);
/// assert_eq!(*owning_ref, 3);
/// }
/// ```
pub fn map<F, U: ?Sized>(mut self, f: F) -> OwningRef<O, U>
where O: StableAddress,
F: FnOnce(&mut T) -> &U
{
OwningRef {
reference: f(&mut self),
owner: self.owner,
}
}
/// Converts `self` into a new _mutable_ owning reference that points at
/// something reachable from the previous one.
///
/// This can be a reference to a field of `U`, something reachable from a field of
/// `U`, or even something unrelated with a `'static` lifetime.
///
/// # Example
/// ```
/// extern crate owning_ref;
/// use owning_ref::OwningRefMut;
///
/// fn main() {
/// let owning_ref_mut = OwningRefMut::new(Box::new([1, 2, 3, 4]));
///
/// // create a owning reference that points at the
/// // third element of the array.
/// let owning_ref_mut = owning_ref_mut.map_mut(|array| &mut array[2]);
/// assert_eq!(*owning_ref_mut, 3);
/// }
/// ```
pub fn map_mut<F, U: ?Sized>(mut self, f: F) -> OwningRefMut<O, U>
where O: StableAddress,
F: FnOnce(&mut T) -> &mut U
{
OwningRefMut {
reference: f(&mut self),
owner: self.owner,
}
}
/// Tries to convert `self` into a new _shared_ owning reference that points
/// at something reachable from the previous one.
///
/// This can be a reference to a field of `U`, something reachable from a field of
/// `U`, or even something unrelated with a `'static` lifetime.
///
/// # Example
/// ```
/// extern crate owning_ref;
/// use owning_ref::OwningRefMut;
///
/// fn main() {
/// let owning_ref_mut = OwningRefMut::new(Box::new([1, 2, 3, 4]));
///
/// // create a owning reference that points at the
/// // third element of the array.
/// let owning_ref = owning_ref_mut.try_map(|array| {
/// if array[2] == 3 { Ok(&array[2]) } else { Err(()) }
/// });
/// assert_eq!(*owning_ref.unwrap(), 3);
/// }
/// ```
pub fn try_map<F, U: ?Sized, E>(mut self, f: F) -> Result<OwningRef<O, U>, E>
where O: StableAddress,
F: FnOnce(&mut T) -> Result<&U, E>
{
Ok(OwningRef {
reference: f(&mut self)?,
owner: self.owner,
})
}
/// Tries to convert `self` into a new _mutable_ owning reference that points
/// at something reachable from the previous one.
///
/// This can be a reference to a field of `U`, something reachable from a field of
/// `U`, or even something unrelated with a `'static` lifetime.
///
/// # Example
/// ```
/// extern crate owning_ref;
/// use owning_ref::OwningRefMut;
///
/// fn main() {
/// let owning_ref_mut = OwningRefMut::new(Box::new([1, 2, 3, 4]));
///
/// // create a owning reference that points at the
/// // third element of the array.
/// let owning_ref_mut = owning_ref_mut.try_map_mut(|array| {
/// if array[2] == 3 { Ok(&mut array[2]) } else { Err(()) }
/// });
/// assert_eq!(*owning_ref_mut.unwrap(), 3);
/// }
/// ```
pub fn try_map_mut<F, U: ?Sized, E>(mut self, f: F) -> Result<OwningRefMut<O, U>, E>
where O: StableAddress,
F: FnOnce(&mut T) -> Result<&mut U, E>
{
Ok(OwningRefMut {
reference: f(&mut self)?,
owner: self.owner,
})
}
/// Converts `self` into a new owning reference with a different owner type.
///
/// The new owner type needs to still contain the original owner in some way
/// so that the reference into it remains valid. This function is marked unsafe
/// because the user needs to manually uphold this guarantee.
pub unsafe fn map_owner<F, P>(self, f: F) -> OwningRefMut<P, T>
where O: StableAddress,
P: StableAddress,
F: FnOnce(O) -> P
{
OwningRefMut {
reference: self.reference,
owner: f(self.owner),
}
}
/// Converts `self` into a new owning reference where the owner is wrapped
/// in an additional `Box<O>`.
///
/// This can be used to safely erase the owner of any `OwningRefMut<O, T>`
/// to a `OwningRefMut<Box<Erased>, T>`.
pub fn map_owner_box(self) -> OwningRefMut<Box<O>, T> {
OwningRefMut {
reference: self.reference,
owner: Box::new(self.owner),
}
}
/// Erases the concrete base type of the owner with a trait object.
///
/// This allows mixing of owned references with different owner base types.
///
/// # Example
/// ```
/// extern crate owning_ref;
/// use owning_ref::{OwningRefMut, Erased};
///
/// fn main() {
/// // N.B., using the concrete types here for explicitness.
/// // For less verbose code type aliases like `BoxRef` are provided.
///
/// let owning_ref_mut_a: OwningRefMut<Box<[i32; 4]>, [i32; 4]>
/// = OwningRefMut::new(Box::new([1, 2, 3, 4]));
///
/// let owning_ref_mut_b: OwningRefMut<Box<Vec<(i32, bool)>>, Vec<(i32, bool)>>
/// = OwningRefMut::new(Box::new(vec![(0, false), (1, true)]));
///
/// let owning_ref_mut_a: OwningRefMut<Box<[i32; 4]>, i32>
/// = owning_ref_mut_a.map_mut(|a| &mut a[0]);
///
/// let owning_ref_mut_b: OwningRefMut<Box<Vec<(i32, bool)>>, i32>
/// = owning_ref_mut_b.map_mut(|a| &mut a[1].0);
///
/// let owning_refs_mut: [OwningRefMut<Box<Erased>, i32>; 2]
/// = [owning_ref_mut_a.erase_owner(), owning_ref_mut_b.erase_owner()];
///
/// assert_eq!(*owning_refs_mut[0], 1);
/// assert_eq!(*owning_refs_mut[1], 1);
/// }
/// ```
pub fn erase_owner<'a>(self) -> OwningRefMut<O::Erased, T>
where O: IntoErased<'a>,
{
OwningRefMut {
reference: self.reference,
owner: self.owner.into_erased(),
}
}
// UNIMPLEMENTED: wrap_owner
// FIXME: Naming convention?
/// A getter for the underlying owner.
pub fn owner(&self) -> &O {
&self.owner
}
// FIXME: Naming convention?
/// Discards the reference and retrieves the owner.
pub fn into_inner(self) -> O {
self.owner
}
}
/////////////////////////////////////////////////////////////////////////////
// OwningHandle
/////////////////////////////////////////////////////////////////////////////
use std::ops::{Deref, DerefMut};
/// `OwningHandle` is a complement to `OwningRef`. Where `OwningRef` allows
/// consumers to pass around an owned object and a dependent reference,
/// `OwningHandle` contains an owned object and a dependent _object_.
///
/// `OwningHandle` can encapsulate a `RefMut` along with its associated
/// `RefCell`, or an `RwLockReadGuard` along with its associated `RwLock`.
/// However, the API is completely generic and there are no restrictions on
/// what types of owning and dependent objects may be used.
///
/// `OwningHandle` is created by passing an owner object (which dereferences
/// to a stable address) along with a callback which receives a pointer to
/// that stable location. The callback may then dereference the pointer and
/// mint a dependent object, with the guarantee that the returned object will
/// not outlive the referent of the pointer.
///
/// Since the callback needs to dereference a raw pointer, it requires `unsafe`
/// code. To avoid forcing this unsafety on most callers, the `ToHandle` trait is
/// implemented for common data structures. Types that implement `ToHandle` can
/// be wrapped into an `OwningHandle` without passing a callback.
pub struct OwningHandle<O, H>
where O: StableAddress, H: Deref,
{
handle: H,
_owner: O,
}
impl<O, H> Deref for OwningHandle<O, H>
where O: StableAddress, H: Deref,
{
type Target = H::Target;
fn deref(&self) -> &H::Target {
self.handle.deref()
}
}
unsafe impl<O, H> StableAddress for OwningHandle<O, H>
where O: StableAddress, H: StableAddress,
{}
impl<O, H> DerefMut for OwningHandle<O, H>
where O: StableAddress, H: DerefMut,
{
fn deref_mut(&mut self) -> &mut H::Target {
self.handle.deref_mut()
}
}
/// Trait to implement the conversion of owner to handle for common types.
pub trait ToHandle {
/// The type of handle to be encapsulated by the OwningHandle.
type Handle: Deref;
/// Given an appropriately-long-lived pointer to ourselves, create a
/// handle to be encapsulated by the `OwningHandle`.
unsafe fn to_handle(x: *const Self) -> Self::Handle;
}
/// Trait to implement the conversion of owner to mutable handle for common types.
pub trait ToHandleMut {
/// The type of handle to be encapsulated by the OwningHandle.
type HandleMut: DerefMut;
/// Given an appropriately-long-lived pointer to ourselves, create a
/// mutable handle to be encapsulated by the `OwningHandle`.
unsafe fn to_handle_mut(x: *const Self) -> Self::HandleMut;
}
impl<O, H> OwningHandle<O, H>
where
O: StableAddress<Target: ToHandle<Handle = H>>,
H: Deref,
{
/// Creates a new `OwningHandle` for a type that implements `ToHandle`. For types
/// that don't implement `ToHandle`, callers may invoke `new_with_fn`, which accepts
/// a callback to perform the conversion.
pub fn new(o: O) -> Self {
OwningHandle::new_with_fn(o, |x| unsafe { O::Target::to_handle(x) })
}
}
impl<O, H> OwningHandle<O, H>
where
O: StableAddress<Target: ToHandleMut<HandleMut = H>>,
H: DerefMut,
{
/// Creates a new mutable `OwningHandle` for a type that implements `ToHandleMut`.
pub fn new_mut(o: O) -> Self {
OwningHandle::new_with_fn(o, |x| unsafe { O::Target::to_handle_mut(x) })
}
}
impl<O, H> OwningHandle<O, H>
where O: StableAddress, H: Deref,
{
/// Creates a new OwningHandle. The provided callback will be invoked with
/// a pointer to the object owned by `o`, and the returned value is stored
/// as the object to which this `OwningHandle` will forward `Deref` and
/// `DerefMut`.
pub fn new_with_fn<F>(o: O, f: F) -> Self
where F: FnOnce(*const O::Target) -> H
{
let h: H;
{
h = f(o.deref() as *const O::Target);
}
OwningHandle {
handle: h,
_owner: o,
}
}
/// Creates a new OwningHandle. The provided callback will be invoked with
/// a pointer to the object owned by `o`, and the returned value is stored
/// as the object to which this `OwningHandle` will forward `Deref` and
/// `DerefMut`.
pub fn try_new<F, E>(o: O, f: F) -> Result<Self, E>
where F: FnOnce(*const O::Target) -> Result<H, E>
{
let h: H;
{
h = f(o.deref() as *const O::Target)?;
}
Ok(OwningHandle {
handle: h,
_owner: o,
})
}
}
/////////////////////////////////////////////////////////////////////////////
// std traits
/////////////////////////////////////////////////////////////////////////////
use std::convert::From;
use std::fmt::{self, Debug};
use std::marker::{Send, Sync};
use std::cmp::{Eq, PartialEq, Ord, PartialOrd, Ordering};
use std::hash::{Hash, Hasher};
use std::borrow::Borrow;
impl<O, T: ?Sized> Deref for OwningRef<O, T> {
type Target = T;
fn deref(&self) -> &T {
unsafe {
&*self.reference
}
}
}
impl<O, T: ?Sized> Deref for OwningRefMut<O, T> {
type Target = T;
fn deref(&self) -> &T {
unsafe {
&*self.reference
}
}
}
impl<O, T: ?Sized> DerefMut for OwningRefMut<O, T> {
fn deref_mut(&mut self) -> &mut T {
unsafe {
&mut *self.reference
}
}
}
unsafe impl<O, T: ?Sized> StableAddress for OwningRef<O, T> {}
impl<O, T: ?Sized> AsRef<T> for OwningRef<O, T> {
fn as_ref(&self) -> &T {
&*self
}
}
impl<O, T: ?Sized> AsRef<T> for OwningRefMut<O, T> {
fn as_ref(&self) -> &T {
&*self
}
}
impl<O, T: ?Sized> AsMut<T> for OwningRefMut<O, T> {
fn as_mut(&mut self) -> &mut T {
&mut *self
}
}
impl<O, T: ?Sized> Borrow<T> for OwningRef<O, T> {
fn borrow(&self) -> &T {
&*self
}
}
impl<O, T: ?Sized> From<O> for OwningRef<O, T>
where O: StableAddress,
O: Deref<Target = T>,
{
fn from(owner: O) -> Self {
OwningRef::new(owner)
}
}
impl<O, T: ?Sized> From<O> for OwningRefMut<O, T>
where O: StableAddress,
O: DerefMut<Target = T>
{
fn from(owner: O) -> Self {
OwningRefMut::new(owner)
}
}
impl<O, T: ?Sized> From<OwningRefMut<O, T>> for OwningRef<O, T>
where O: StableAddress,
O: DerefMut<Target = T>
{
fn from(other: OwningRefMut<O, T>) -> Self {
OwningRef {
owner: other.owner,
reference: other.reference,
}
}
}
// ^ FIXME: Is a Into impl for calling into_inner() possible as well?
impl<O, T: ?Sized> Debug for OwningRef<O, T>
where O: Debug,
T: Debug,
{
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f,
"OwningRef {{ owner: {:?}, reference: {:?} }}",
self.owner(),
&**self)
}
}
impl<O, T: ?Sized> Debug for OwningRefMut<O, T>
where O: Debug,
T: Debug,
{
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f,
"OwningRefMut {{ owner: {:?}, reference: {:?} }}",
self.owner(),
&**self)
}
}
impl<O, T: ?Sized> Clone for OwningRef<O, T>
where O: CloneStableAddress,
{
fn clone(&self) -> Self {
OwningRef {
owner: self.owner.clone(),
reference: self.reference,
}
}
}
unsafe impl<O, T: ?Sized> CloneStableAddress for OwningRef<O, T>
where O: CloneStableAddress {}
unsafe impl<O, T: ?Sized> Send for OwningRef<O, T>
where O: Send, for<'a> (&'a T): Send {}
unsafe impl<O, T: ?Sized> Sync for OwningRef<O, T>
where O: Sync, for<'a> (&'a T): Sync {}
unsafe impl<O, T: ?Sized> Send for OwningRefMut<O, T>
where O: Send, for<'a> (&'a mut T): Send {}
unsafe impl<O, T: ?Sized> Sync for OwningRefMut<O, T>
where O: Sync, for<'a> (&'a mut T): Sync {}
impl Debug for dyn Erased {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "<Erased>",)
}
}
impl<O, T: ?Sized> PartialEq for OwningRef<O, T> where T: PartialEq {
fn eq(&self, other: &Self) -> bool {
(&*self as &T).eq(&*other as &T)
}
}
impl<O, T: ?Sized> Eq for OwningRef<O, T> where T: Eq {}
impl<O, T: ?Sized> PartialOrd for OwningRef<O, T> where T: PartialOrd {
fn partial_cmp(&self, other: &Self) -> Option<Ordering> {
(&*self as &T).partial_cmp(&*other as &T)
}
}
impl<O, T: ?Sized> Ord for OwningRef<O, T> where T: Ord {
fn cmp(&self, other: &Self) -> Ordering {
(&*self as &T).cmp(&*other as &T)
}
}
impl<O, T: ?Sized> Hash for OwningRef<O, T> where T: Hash {
fn hash<H: Hasher>(&self, state: &mut H) {
(&*self as &T).hash(state);
}
}
impl<O, T: ?Sized> PartialEq for OwningRefMut<O, T> where T: PartialEq {
fn eq(&self, other: &Self) -> bool {
(&*self as &T).eq(&*other as &T)
}
}
impl<O, T: ?Sized> Eq for OwningRefMut<O, T> where T: Eq {}
impl<O, T: ?Sized> PartialOrd for OwningRefMut<O, T> where T: PartialOrd {
fn partial_cmp(&self, other: &Self) -> Option<Ordering> {
(&*self as &T).partial_cmp(&*other as &T)
}
}
impl<O, T: ?Sized> Ord for OwningRefMut<O, T> where T: Ord {
fn cmp(&self, other: &Self) -> Ordering {
(&*self as &T).cmp(&*other as &T)
}
}
impl<O, T: ?Sized> Hash for OwningRefMut<O, T> where T: Hash {
fn hash<H: Hasher>(&self, state: &mut H) {
(&*self as &T).hash(state);
}
}
/////////////////////////////////////////////////////////////////////////////
// std types integration and convenience type defs
/////////////////////////////////////////////////////////////////////////////
use std::boxed::Box;
use std::rc::Rc;
use std::sync::Arc;
use std::sync::{MutexGuard, RwLockReadGuard, RwLockWriteGuard};
use std::cell::{Ref, RefCell, RefMut};
impl<T: 'static> ToHandle for RefCell<T> {
type Handle = Ref<'static, T>;
unsafe fn to_handle(x: *const Self) -> Self::Handle { (*x).borrow() }
}
impl<T: 'static> ToHandleMut for RefCell<T> {
type HandleMut = RefMut<'static, T>;
unsafe fn to_handle_mut(x: *const Self) -> Self::HandleMut { (*x).borrow_mut() }
}
// N.B., implementing ToHandle{,Mut} for Mutex and RwLock requires a decision
// about which handle creation to use (i.e., read() vs try_read()) as well as
// what to do with error results.
/// Typedef of a owning reference that uses a `Box` as the owner.
pub type BoxRef<T, U = T> = OwningRef<Box<T>, U>;
/// Typedef of a owning reference that uses a `Vec` as the owner.
pub type VecRef<T, U = T> = OwningRef<Vec<T>, U>;
/// Typedef of a owning reference that uses a `String` as the owner.
pub type StringRef = OwningRef<String, str>;
/// Typedef of a owning reference that uses a `Rc` as the owner.
pub type RcRef<T, U = T> = OwningRef<Rc<T>, U>;
/// Typedef of a owning reference that uses a `Arc` as the owner.
pub type ArcRef<T, U = T> = OwningRef<Arc<T>, U>;
/// Typedef of a owning reference that uses a `Ref` as the owner.
pub type RefRef<'a, T, U = T> = OwningRef<Ref<'a, T>, U>;
/// Typedef of a owning reference that uses a `RefMut` as the owner.
pub type RefMutRef<'a, T, U = T> = OwningRef<RefMut<'a, T>, U>;
/// Typedef of a owning reference that uses a `MutexGuard` as the owner.
pub type MutexGuardRef<'a, T, U = T> = OwningRef<MutexGuard<'a, T>, U>;
/// Typedef of a owning reference that uses a `RwLockReadGuard` as the owner.
pub type RwLockReadGuardRef<'a, T, U = T> = OwningRef<RwLockReadGuard<'a, T>, U>;
/// Typedef of a owning reference that uses a `RwLockWriteGuard` as the owner.
pub type RwLockWriteGuardRef<'a, T, U = T> = OwningRef<RwLockWriteGuard<'a, T>, U>;
/// Typedef of a mutable owning reference that uses a `Box` as the owner.
pub type BoxRefMut<T, U = T> = OwningRefMut<Box<T>, U>;
/// Typedef of a mutable owning reference that uses a `Vec` as the owner.
pub type VecRefMut<T, U = T> = OwningRefMut<Vec<T>, U>;
/// Typedef of a mutable owning reference that uses a `String` as the owner.
pub type StringRefMut = OwningRefMut<String, str>;
/// Typedef of a mutable owning reference that uses a `RefMut` as the owner.
pub type RefMutRefMut<'a, T, U = T> = OwningRefMut<RefMut<'a, T>, U>;
/// Typedef of a mutable owning reference that uses a `MutexGuard` as the owner.
pub type MutexGuardRefMut<'a, T, U = T> = OwningRefMut<MutexGuard<'a, T>, U>;
/// Typedef of a mutable owning reference that uses a `RwLockWriteGuard` as the owner.
pub type RwLockWriteGuardRefMut<'a, T, U = T> = OwningRef<RwLockWriteGuard<'a, T>, U>;
unsafe impl<'a, T: 'a> IntoErased<'a> for Box<T> {
type Erased = Box<dyn Erased + 'a>;
fn into_erased(self) -> Self::Erased {
self
}
}
unsafe impl<'a, T: 'a> IntoErased<'a> for Rc<T> {
type Erased = Rc<dyn Erased + 'a>;
fn into_erased(self) -> Self::Erased {
self
}
}
unsafe impl<'a, T: 'a> IntoErased<'a> for Arc<T> {
type Erased = Arc<dyn Erased + 'a>;
fn into_erased(self) -> Self::Erased {
self
}
}
unsafe impl<'a, T: Send + 'a> IntoErasedSend<'a> for Box<T> {
type Erased = Box<dyn Erased + Send + 'a>;
fn into_erased_send(self) -> Self::Erased {
self
}
}
unsafe impl<'a, T: Send + 'a> IntoErasedSendSync<'a> for Box<T> {
type Erased = Box<dyn Erased + Sync + Send + 'a>;
fn into_erased_send_sync(self) -> Self::Erased {
let result: Box<dyn Erased + Send + 'a> = self;
// This is safe since Erased can always implement Sync
// Only the destructor is available and it takes &mut self
unsafe {
mem::transmute(result)
}
}
}
unsafe impl<'a, T: Send + Sync + 'a> IntoErasedSendSync<'a> for Arc<T> {
type Erased = Arc<dyn Erased + Send + Sync + 'a>;
fn into_erased_send_sync(self) -> Self::Erased {
self
}
}
/// Typedef of a owning reference that uses an erased `Box` as the owner.
pub type ErasedBoxRef<U> = OwningRef<Box<dyn Erased>, U>;
/// Typedef of a owning reference that uses an erased `Rc` as the owner.
pub type ErasedRcRef<U> = OwningRef<Rc<dyn Erased>, U>;
/// Typedef of a owning reference that uses an erased `Arc` as the owner.
pub type ErasedArcRef<U> = OwningRef<Arc<dyn Erased>, U>;
/// Typedef of a mutable owning reference that uses an erased `Box` as the owner.
pub type ErasedBoxRefMut<U> = OwningRefMut<Box<dyn Erased>, U>;
#[cfg(test)]
mod tests;