Rc<T>
, the Reference Counted Smart Pointer
In the majority of cases, ownership is clear: you know exactly which variable owns a given value. However, there are cases when a single value might have multiple owners. For example, in graph data structures, multiple edges might point to the same node, and that node is conceptually owned by all of the edges that point to it. A node shouldn’t be cleaned up unless it doesn’t have any edges pointing to it.
To enable multiple ownership, Rust has a type called Rc<T>
, which is an
abbreviation for reference counting. The Rc<T>
type keeps track of the
number of references to a value which determines whether or not a value is
still in use. If there are zero references to a value, the value can be cleaned
up without any references becoming invalid.
Imagine Rc<T>
as a TV in a family room. When one person enters to watch TV,
they turn it on. Others can come into the room and watch the TV. When the last
person leaves the room, they turn off the TV because it’s no longer being used.
If someone turns off the TV while others are still watching it, there would be
uproar from the remaining TV watchers!
We use the Rc<T>
type when we want to allocate some data on the heap for
multiple parts of our program to read and we can’t determine at compile time
which part will finish using the data last. If we knew which part would finish
last, we could just make that part the data’s owner, and the normal ownership
rules enforced at compile time would take effect.
Note that Rc<T>
is only for use in single-threaded scenarios. When we discuss
concurrency in Chapter 16, we’ll cover how to do reference counting in
multithreaded programs.
Using Rc<T>
to Share Data
Let’s return to our cons list example in Listing 15-5. Recall that we defined
it using Box<T>
. This time, we’ll create two lists that both share ownership
of a third list. Conceptually, this looks similar to Figure 15-3:
We’ll create list a
that contains 5 and then 10. Then we’ll make two more
lists: b
that starts with 3 and c
that starts with 4. Both b
and c
lists will then continue on to the first a
list containing 5 and 10. In other
words, both lists will share the first list containing 5 and 10.
Trying to implement this scenario using our definition of List
with Box<T>
won’t work, as shown in Listing 15-17:
Filename: src/main.rs
enum List {
Cons(i32, Box<List>),
Nil,
}
use crate::List::{Cons, Nil};
fn main() {
let a = Cons(5,
Box::new(Cons(10,
Box::new(Nil))));
let b = Cons(3, Box::new(a));
let c = Cons(4, Box::new(a));
}
When we compile this code, we get this error:
error[E0382]: use of moved value: `a`
--> src/main.rs:13:30
|
12 | let b = Cons(3, Box::new(a));
| - value moved here
13 | let c = Cons(4, Box::new(a));
| ^ value used here after move
|
= note: move occurs because `a` has type `List`, which does not implement
the `Copy` trait
The Cons
variants own the data they hold, so when we create the b
list, a
is moved into b
and b
owns a
. Then, when we try to use a
again when
creating c
, we’re not allowed to because a
has been moved.
We could change the definition of Cons
to hold references instead, but then
we would have to specify lifetime parameters. By specifying lifetime
parameters, we would be specifying that every element in the list will live at
least as long as the entire list. The borrow checker wouldn’t let us compile
let a = Cons(10, &Nil);
for example, because the temporary Nil
value would
be dropped before a
could take a reference to it.
Instead, we’ll change our definition of List
to use Rc<T>
in place of
Box<T>
, as shown in Listing 15-18. Each Cons
variant will now hold a value
and an Rc<T>
pointing to a List
. When we create b
, instead of taking
ownership of a
, we’ll clone the Rc<List>
that a
is holding, thereby
increasing the number of references from one to two and letting a
and b
share ownership of the data in that Rc<List>
. We’ll also clone a
when
creating c
, increasing the number of references from two to three. Every time
we call Rc::clone
, the reference count to the data within the Rc<List>
will
increase, and the data won’t be cleaned up unless there are zero references to
it.
Filename: src/main.rs
enum List { Cons(i32, Rc<List>), Nil, } use crate::List::{Cons, Nil}; use std::rc::Rc; fn main() { let a = Rc::new(Cons(5, Rc::new(Cons(10, Rc::new(Nil))))); let b = Cons(3, Rc::clone(&a)); let c = Cons(4, Rc::clone(&a)); }
We need to add a use
statement to bring Rc<T>
into scope because it’s not
in the prelude. In main
, we create the list holding 5 and 10 and store it in
a new Rc<List>
in a
. Then when we create b
and c
, we call the
Rc::clone
function and pass a reference to the Rc<List>
in a
as an
argument.
We could have called a.clone()
rather than Rc::clone(&a)
, but Rust’s
convention is to use Rc::clone
in this case. The implementation of
Rc::clone
doesn’t make a deep copy of all the data like most types’
implementations of clone
do. The call to Rc::clone
only increments the
reference count, which doesn’t take much time. Deep copies of data can take a
lot of time. By using Rc::clone
for reference counting, we can visually
distinguish between the deep-copy kinds of clones and the kinds of clones that
increase the reference count. When looking for performance problems in the
code, we only need to consider the deep-copy clones and can disregard calls to
Rc::clone
.
Cloning an Rc<T>
Increases the Reference Count
Let’s change our working example in Listing 15-18 so we can see the reference
counts changing as we create and drop references to the Rc<List>
in a
.
In Listing 15-19, we’ll change main
so it has an inner scope around list c
;
then we can see how the reference count changes when c
goes out of scope.
Filename: src/main.rs
enum List { Cons(i32, Rc<List>), Nil, } use crate::List::{Cons, Nil}; use std::rc::Rc; fn main() { let a = Rc::new(Cons(5, Rc::new(Cons(10, Rc::new(Nil))))); println!("count after creating a = {}", Rc::strong_count(&a)); let b = Cons(3, Rc::clone(&a)); println!("count after creating b = {}", Rc::strong_count(&a)); { let c = Cons(4, Rc::clone(&a)); println!("count after creating c = {}", Rc::strong_count(&a)); } println!("count after c goes out of scope = {}", Rc::strong_count(&a)); }
At each point in the program where the reference count changes, we print the
reference count, which we can get by calling the Rc::strong_count
function.
This function is named strong_count
rather than count
because the Rc<T>
type also has a weak_count
; we’ll see what weak_count
is used for in the
“Preventing Reference Cycles: Turning an Rc<T>
into a
Weak<T>
” section.
This code prints the following:
count after creating a = 1
count after creating b = 2
count after creating c = 3
count after c goes out of scope = 2
We can see that the Rc<List>
in a
has an initial reference count of 1; then
each time we call clone
, the count goes up by 1. When c
goes out of scope,
the count goes down by 1. We don’t have to call a function to decrease the
reference count like we have to call Rc::clone
to increase the reference
count: the implementation of the Drop
trait decreases the reference count
automatically when an Rc<T>
value goes out of scope.
What we can’t see in this example is that when b
and then a
go out of scope
at the end of main
, the count is then 0, and the Rc<List>
is cleaned up
completely at that point. Using Rc<T>
allows a single value to have
multiple owners, and the count ensures that the value remains valid as long as
any of the owners still exist.
Via immutable references, Rc<T>
allows you to share data between multiple
parts of your program for reading only. If Rc<T>
allowed you to have multiple
mutable references too, you might violate one of the borrowing rules discussed
in Chapter 4: multiple mutable borrows to the same place can cause data races
and inconsistencies. But being able to mutate data is very useful! In the next
section, we’ll discuss the interior mutability pattern and the RefCell<T>
type that you can use in conjunction with an Rc<T>
to work with this
immutability restriction.