I am a newbie to Rust and writing to understand the "Smart pointers" in Rust. I have basic understanding of how smart pointers works in C++ and has been using it for memory management since a few years ago. But to my very much surprise, Rust also provides such utility explicitly.

Because from a tutorial here (https://pcwalton.github.io/2013/03/18/an-overview-of-memory-management-in-rust.html), it seems that every raw pointers have been automatically wrapped with a smart pointer, which seems very reasonable. Then why do we still need such Box<T>, Rc<T>, and Ref<T> stuff? According to this specification: https://doc.rust-lang.org/book/ch15-00-smart-pointers.html

Any comments will be apprecicated a lot. Thanks.

  • "it seems that every raw pointers have been automatically wrapped with a smart pointer" -- no, that sounds like there are implicit conversions happening all over the place. Raw pointers still exist, but they aren't ever used automatically, and most of their use cases have been replaced with some flavor of smart pointer, of which Rc<T>, Box<T> and Ref<T> are examples.
    – trent
    Mar 9, 2019 at 12:10
  • "why do we still need such Box<T>, Rc<T>, and Ref<T> stuff?" -- I don't understand the question. Those are smart pointers. How else would you use them, other than "explicitly"? It sounds like you're asking in c++, "I know what smart pointers are and how to use them, but I don't know what we need unique_ptr and shared_ptr for."
    – trent
    Mar 9, 2019 at 12:13
  • @trentcl No, what I means is that. Does compiler use these three to actually implement smart pointers? Mar 9, 2019 at 13:48
  • Does the compiler use smart pointers to implement smart pointers? Sorry, I still don't understand. Smart pointers are implemented using raw pointers in Rust, just the same as in C++. You can look at the source code for Rc<T>, for example: it contains a NonNull, which is just a wrapper around a *const (raw) pointer. This is all in the standard library, not in the compiler itself.
    – trent
    Mar 9, 2019 at 14:09
  • 1
    If the syntax of the first article is confusing you, that's because it is very old. I wrote an answer to this effect. Leaving the previous comments in place in case I am wrong
    – trent
    Mar 9, 2019 at 15:39

2 Answers 2


You can think about the difference between a T and a Box<T> as the difference between a statically allocated object and a dynamically allocated object (the latter being created via a new expression in C++ terms).

In Rust, both T and Box<T> represent a variable that has ownership over the referent object (i.e. when the variable goes out of scope, the object will be destroyed, whether it was stored by value or by reference). On the contrary, &T and &mut T represent borrowing of the object (i.e. these variables are not responsible for destroying the object, and they cannot outlive the owner of the object).

By default, you'd probably want to use T, but sometimes you might want (or have) to use Box<T>. For example, you would use a Box<T> if you want to own a T that's too large to be allocated in place. You would also use it when the object doesn't have a known size at all, which means that your only choice to store it or pass it around is through the "pointer" (the Box<T>).

In Rust, an object is generally either mutable or aliased, but not both. If you have given out immutable references to an object, you normally need to wait until those references are over before you can mutate that object again.

Additionally, Rust's immutability is transitive. If you receive an object immutably, it means that you have access to its contents (and the contents of those contents, and so on) also immutably.

Normally, all of these things are enforced at compile time. This means that you catch errors faster, but you are limited to being able to express only what the compiler can prove statically.

Like T and Box<T>, you may sometimes use RefCell<T>, which is another ownership type. But unlike T and Box<T>, the RefCell<T> enforces the borrow checking rules at runtime instead of compile time, meaning that sometimes you can do things with it that are safe but wouldn't pass the compiler's static borrow checker. The main example for this is getting a mutable reference to the interior of an object that was received immutably (which, under the statically enforced rules of Rust, would make the entire interior immutable).

The types Ref<T> and RefMut<T> are the runtime-checked equivalents of &T and &mut T respectively.

(EDIT: This whole thing is somewhat of a lie. &mut really means "unique borrow" and & means "non-unique borrow". Certain types, like mutexes, can be non-uniquely but still mutably borrowed, because otherwise they would be useless.)

Rust's ownership model tries to push you to write programs in which objects' lifetimes are known at compile time. This works well in certain scenarios, but makes other scenarios difficult or impossible to express.

Rc<T> and its atomic sibling Arc<T> are reference-counting wrappers of T. They offer you an alternative to the ownership model.

They are useful when you want to use and properly dispose an object, but it is not easy (or possible) to determine, at the moment you're writing the code, which specific variable should be the owner of that object (and therefore should take care of disposing it). Much like in C++, this means that there is no single owner of the object and that the object will be disposed by the last reference-counting wrapper that points to it.

  • The T should be allocated on stack first, and then pass to Box::new(), then if T is large, it does't help via Box?
    – kingluo
    Feb 2, 2020 at 12:04

The article you linked uses outdated syntax. Certain smart pointers used to have special names and associated syntax that has been removed since some time before Rust 1.0:

  • Box<T> replaced ~T ("owned pointers")
  • Rc<T> replaced @T ("managed pointers")

Because the Internet never forgets, you can still find pre-1.0 documentation and articles (such as the one you linked) that use the old syntax. Check the date of the article: if it's before May 2015, you're dealing with an early, unstable Rust.

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