I'd like to create an Rc<str> because I want reduce the indirection from following the 2 pointers that accessing an Rc<String> requires. I need to use an Rc because I truly have shared ownership. I detail in another question more specific issues I have around my string type.

Rc has a ?Sized bound:

pub struct Rc<T: ?Sized> { /* fields omitted */ }

I've also heard that Rust 1.2 will come with proper support for storing unsized types in an Rc, but I'm unsure how this differs from 1.1.

Taking the str case as example, my naive attempt (also this for building from a String) fails with:

use std::rc::Rc;

fn main() {
    let a: &str = "test";
    let b: Rc<str> = Rc::new(*a);
    println!("{}", b);
error[E0277]: the trait bound `str: std::marker::Sized` is not satisfied
 --> src/main.rs:5:22
5 |     let b: Rc<str> = Rc::new(*a);
  |                      ^^^^^^^ `str` does not have a constant size known at compile-time
  = help: the trait `std::marker::Sized` is not implemented for `str`
  = note: required by `<std::rc::Rc<T>>::new`

It's clear that in order to create an Rc<str>, I need to copy the whole string: RcBox would be itself an unsized type, storing the string itself alongside the weak and strong pointers — the naive code above doesn't even make sense.

I've been told that one can not instantiate such type, but instead instantiate an Rc<T> with a sized T and then coerce it to an unsized type. The example given is for the storing a trait object: first create Rc<ConcreteType> and then coerce to Rc<Trait>. But this doesn't make sense either: neither this nor this work (and you can't coerce from &str or String to str anyway).

  • Because accessing an Rc<String> requires following 2 pointers (also, I need Rc because I truly have shared ownership). I detail in another question more specific issues I've around my string type. My tentative definition Rc<Utf16Str> would also require an unsized type Utf16Str (it would have the same layout as Rc<[u16]>).
    – darque
    Jul 28, 2015 at 23:29

2 Answers 2


As of Rust 1.21.0 and as mandated by RFC 1845, creating an Rc<str> or Arc<str> is now possible:

use std::rc::Rc;
use std::sync::Arc;

fn main() {
    let a: &str = "hello world";
    let b: Rc<str> = Rc::from(a);
    println!("{}", b);

    // or equivalently:
    let b: Rc<str> = a.into();
    println!("{}", b);

    // we can also do this for Arc,
    let a: &str = "hello world";
    let b: Arc<str> = Arc::from(a);
    println!("{}", b);


See <Rc as From<&str>> and <Arc as From<&str>>.


Creating an Rc<[T]> can be done via coercions and as-casts from fixed sized arrays, e.g. coercions can be done as follows:

use std::rc::Rc;

fn main() {
    let x: Rc<[i32; 4]> = Rc::new([1, 2, 3, 4]);

    let y: Rc<[i32]> = x;

    println!("{:?}", y);

However, this doesn't work for strings, since they have no raw fixed-sized equivalent to create the first value. It is possible to do unsafely, e.g. by creating a UTF-8 encoded Rc<[u8]> and transmuting that to Rc<str>. Theoretically there could be a crate on crates.io for it, but I can't find one at the moment.

An alternative is owning_ref, which isn't quite std::rc::Rc itself, but should allow, for example, getting an RcRef<..., str> pointing into an Rc<String>. (This approach will work best if one uses RcRef uniformly in place of Rc, except for construction.)

extern crate owning_ref;
use owning_ref::RcRef;
use std::rc::Rc;

fn main() {
    let some_string = "foo".to_owned();

    let val: RcRef<String> = RcRef::new(Rc::new(some_string));

    let borrowed: RcRef<String, str> = val.map(|s| &**s);

    let erased: RcRef<owning_ref::Erased, str> = borrowed.erase_owner();

The erasing means that RcRef<..., str>s can come from multiple different sources, e.g. a RcRef<Erased, str> can come from a string literal too.

NB. at the time of writing, the erasure with RcRef requires a nightly compiler, and depending on owning_ref with the nightly feature:

owning_ref = { version = "0.1", features = ["nightly"] }
  • 1
    So a Rc<[T]> can't be created when the length of [T] is unknown at compile time, right? (But why is that? Isn't Rc allocated in the heap? since it's a fat pointer it already "knows" its size)
    – darque
    Jul 28, 2015 at 23:41
  • Yeah, an Rc<[T]> can't be constructed via coercion with dynamic lengths. However the concept totally makes sense, the only blocking problem is that there's no good way to construct one.
    – huon
    Jul 28, 2015 at 23:44
  • Also, would accessing the String inside RcRef require following two pointers? (the whole issue is that Rc<String> has a pointer to String that has a pointer to the beginning of the string...). I can't figure out if this just has a pointer to the String.
    – darque
    Jul 28, 2015 at 23:46
  • Re: "the concept totally makes sense" - does it means that besides Rc<[T]>, Rc<str> (and other unsized types) could work on a future version of Rust?
    – darque
    Jul 28, 2015 at 23:47
  • @darque it already can for certain unsized types, like traits. This was new as of Rust 1.1 IIRC.
    – Shepmaster
    Jul 28, 2015 at 23:55

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.