Crate owning_ref
source · [−]Expand description
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:
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:
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));
}
Structs
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.
An owning reference.
An mutable owning reference.
Traits
An unsafe marker trait for types where clones deref to the same address. This has all the requirements of StableDeref, and additionally requires that after calling clone(), both the old and new value deref to the same address. For example, Rc and Arc implement CloneStableDeref, but Box and Vec do not.
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.
Helper trait for erasing the concrete type of what an owner derferences to,
for example Box<T> -> Box<dyn Erased>
. This would be unneeded with
higher kinded types support in the language.
An unsafe marker trait for types that deref to a stable address, even when moved. For example, this is implemented by Box, Vec, Rc, Arc and String, among others. Even when a Box is moved, the underlying storage remains at a fixed location.
Trait to implement the conversion of owner to handle for common types.
Trait to implement the conversion of owner to mutable handle for common types.
Type Definitions
Typedef of a owning reference that uses a Arc
as the owner.
Typedef of a owning reference that uses a Box
as the owner.
Typedef of a mutable owning reference that uses a Box
as the owner.
Typedef of a owning reference that uses an erased Arc
as the owner.
Typedef of a owning reference that uses an erased Box
as the owner.
Typedef of a mutable owning reference that uses an erased Box
as the owner.
Typedef of a owning reference that uses an erased Rc
as the owner.
Typedef of a owning reference that uses a MutexGuard
as the owner.
Typedef of a mutable owning reference that uses a MutexGuard
as the owner.
Typedef of a owning reference that uses a Rc
as the owner.
Typedef of a owning reference that uses a RefMut
as the owner.
Typedef of a mutable owning reference that uses a RefMut
as the owner.
Typedef of a owning reference that uses a Ref
as the owner.
Typedef of a owning reference that uses a RwLockReadGuard
as the owner.
Typedef of a owning reference that uses a RwLockWriteGuard
as the owner.
Typedef of a mutable owning reference that uses a RwLockWriteGuard
as the owner.
Typedef of a owning reference that uses a String
as the owner.
Typedef of a mutable owning reference that uses a String
as the owner.
Typedef of a owning reference that uses a Vec
as the owner.
Typedef of a mutable owning reference that uses a Vec
as the owner.