RefCell<T>
and the Interior Mutability Pattern
Interior mutability is a design pattern in Rust that allows you to mutate
data even when there are immutable references to that data; normally, this
action is disallowed by the borrowing rules. To mutate data, the pattern uses
unsafe
code inside a data structure to bend Rust’s usual rules that govern
mutation and borrowing. We haven’t yet covered unsafe code; we will in
Chapter 19. We can use types that use the interior mutability pattern when we
can ensure that the borrowing rules will be followed at runtime, even though
the compiler can’t guarantee that. The unsafe
code involved is then wrapped
in a safe API, and the outer type is still immutable.
Let’s explore this concept by looking at the RefCell<T>
type that follows the
interior mutability pattern.
Enforcing Borrowing Rules at Runtime with RefCell<T>
Unlike Rc<T>
, the RefCell<T>
type represents single ownership over the data
it holds. So, what makes RefCell<T>
different from a type like Box<T>
?
Recall the borrowing rules you learned in Chapter 4:
- At any given time, you can have either (but not both of) one mutable reference or any number of immutable references.
- References must always be valid.
With references and Box<T>
, the borrowing rules’ invariants are enforced at
compile time. With RefCell<T>
, these invariants are enforced at runtime.
With references, if you break these rules, you’ll get a compiler error. With
RefCell<T>
, if you break these rules, your program will panic and exit.
The advantages of checking the borrowing rules at compile time are that errors will be caught sooner in the development process, and there is no impact on runtime performance because all the analysis is completed beforehand. For those reasons, checking the borrowing rules at compile time is the best choice in the majority of cases, which is why this is Rust’s default.
The advantage of checking the borrowing rules at runtime instead is that certain memory-safe scenarios are then allowed, whereas they are disallowed by the compile-time checks. Static analysis, like the Rust compiler, is inherently conservative. Some properties of code are impossible to detect by analyzing the code: the most famous example is the Halting Problem, which is beyond the scope of this book but is an interesting topic to research.
Because some analysis is impossible, if the Rust compiler can’t be sure the
code complies with the ownership rules, it might reject a correct program; in
this way, it’s conservative. If Rust accepted an incorrect program, users
wouldn’t be able to trust in the guarantees Rust makes. However, if Rust
rejects a correct program, the programmer will be inconvenienced, but nothing
catastrophic can occur. The RefCell<T>
type is useful when you’re sure your
code follows the borrowing rules but the compiler is unable to understand and
guarantee that.
Similar to Rc<T>
, RefCell<T>
is only for use in single-threaded scenarios
and will give you a compile-time error if you try using it in a multithreaded
context. We’ll talk about how to get the functionality of RefCell<T>
in a
multithreaded program in Chapter 16.
Here is a recap of the reasons to choose Box<T>
, Rc<T>
, or RefCell<T>
:
Rc<T>
enables multiple owners of the same data;Box<T>
andRefCell<T>
have single owners.Box<T>
allows immutable or mutable borrows checked at compile time;Rc<T>
allows only immutable borrows checked at compile time;RefCell<T>
allows immutable or mutable borrows checked at runtime.- Because
RefCell<T>
allows mutable borrows checked at runtime, you can mutate the value inside theRefCell<T>
even when theRefCell<T>
is immutable.
Mutating the value inside an immutable value is the interior mutability pattern. Let’s look at a situation in which interior mutability is useful and examine how it’s possible.
Interior Mutability: A Mutable Borrow to an Immutable Value
A consequence of the borrowing rules is that when you have an immutable value, you can’t borrow it mutably. For example, this code won’t compile:
fn main() {
let x = 5;
let y = &mut x;
}
If you tried to compile this code, you’d get the following error:
error[E0596]: cannot borrow immutable local variable `x` as mutable
--> src/main.rs:3:18
|
2 | let x = 5;
| - consider changing this to `mut x`
3 | let y = &mut x;
| ^ cannot borrow mutably
However, there are situations in which it would be useful for a value to mutate
itself in its methods but appear immutable to other code. Code outside the
value’s methods would not be able to mutate the value. Using RefCell<T>
is
one way to get the ability to have interior mutability. But RefCell<T>
doesn’t get around the borrowing rules completely: the borrow checker in the
compiler allows this interior mutability, and the borrowing rules are checked
at runtime instead. If you violate the rules, you’ll get a panic!
instead of
a compiler error.
Let’s work through a practical example where we can use RefCell<T>
to mutate
an immutable value and see why that is useful.
A Use Case for Interior Mutability: Mock Objects
A test double is the general programming concept for a type used in place of another type during testing. Mock objects are specific types of test doubles that record what happens during a test so you can assert that the correct actions took place.
Rust doesn’t have objects in the same sense as other languages have objects, and Rust doesn’t have mock object functionality built into the standard library as some other languages do. However, you can definitely create a struct that will serve the same purposes as a mock object.
Here’s the scenario we’ll test: we’ll create a library that tracks a value against a maximum value and sends messages based on how close to the maximum value the current value is. This library could be used to keep track of a user’s quota for the number of API calls they’re allowed to make, for example.
Our library will only provide the functionality of tracking how close to the
maximum a value is and what the messages should be at what times. Applications
that use our library will be expected to provide the mechanism for sending the
messages: the application could put a message in the application, send an
email, send a text message, or something else. The library doesn’t need to know
that detail. All it needs is something that implements a trait we’ll provide
called Messenger
. Listing 15-20 shows the library code:
Filename: src/lib.rs
# #![allow(unused_variables)] #fn main() { pub trait Messenger { fn send(&self, msg: &str); } pub struct LimitTracker<'a, T: 'a + Messenger> { messenger: &'a T, value: usize, max: usize, } impl<'a, T> LimitTracker<'a, T> where T: Messenger { pub fn new(messenger: &T, max: usize) -> LimitTracker<T> { LimitTracker { messenger, value: 0, max, } } pub fn set_value(&mut self, value: usize) { self.value = value; let percentage_of_max = self.value as f64 / self.max as f64; if percentage_of_max >= 0.75 && percentage_of_max < 0.9 { self.messenger.send("Warning: You've used up over 75% of your quota!"); } else if percentage_of_max >= 0.9 && percentage_of_max < 1.0 { self.messenger.send("Urgent warning: You've used up over 90% of your quota!"); } else if percentage_of_max >= 1.0 { self.messenger.send("Error: You are over your quota!"); } } } #}
One important part of this code is that the Messenger
trait has one method
called send
that takes an immutable reference to self
and the text of the
message. This is the interface our mock object needs to have. The other
important part is that we want to test the behavior of the set_value
method
on the LimitTracker
. We can change what we pass in for the value
parameter,
but set_value
doesn’t return anything for us to make assertions on. We want
to be able to say that if we create a LimitTracker
with something that
implements the Messenger
trait and a particular value for max
, when we pass
different numbers for value
, the messenger is told to send the appropriate
messages.
We need a mock object that, instead of sending an email or text message when we
call send
, will only keep track of the messages it’s told to send. We can
create a new instance of the mock object, create a LimitTracker
that uses the
mock object, call the set_value
method on LimitTracker
, and then check that
the mock object has the messages we expect. Listing 15-21 shows an attempt to
implement a mock object to do just that, but the borrow checker won’t allow it:
Filename: src/lib.rs
# #![allow(unused_variables)] #fn main() { #[cfg(test)] mod tests { use super::*; struct MockMessenger { sent_messages: Vec<String>, } impl MockMessenger { fn new() -> MockMessenger { MockMessenger { sent_messages: vec![] } } } impl Messenger for MockMessenger { fn send(&self, message: &str) { self.sent_messages.push(String::from(message)); } } #[test] fn it_sends_an_over_75_percent_warning_message() { let mock_messenger = MockMessenger::new(); let mut limit_tracker = LimitTracker::new(&mock_messenger, 100); limit_tracker.set_value(80); assert_eq!(mock_messenger.sent_messages.len(), 1); } } #}
This test code defines a MockMessenger
struct that has a sent_messages
field with a Vec
of String
values to keep track of the messages it’s told
to send. We also define an associated function new
to make it convenient to
create new MockMessenger
values that start with an empty list of messages. We
then implement the Messenger
trait for MockMessenger
so we can give a
MockMessenger
to a LimitTracker
. In the definition of the send
method, we
take the message passed in as a parameter and store it in the MockMessenger
list of sent_messages
.
In the test, we’re testing what happens when the LimitTracker
is told to set
value
to something that is more than 75 percent of the max
value. First, we
create a new MockMessenger
, which will start with an empty list of messages.
Then we create a new LimitTracker
and give it a reference to the new
MockMessenger
and a max
value of 100. We call the set_value
method on the
LimitTracker
with a value of 80, which is more than 75 percent of 100. Then
we assert that the list of messages that the MockMessenger
is keeping track
of should now have one message in it.
However, there’s one problem with this test, as shown here:
error[E0596]: cannot borrow immutable field `self.sent_messages` as mutable
--> src/lib.rs:52:13
|
51 | fn send(&self, message: &str) {
| ----- use `&mut self` here to make mutable
52 | self.sent_messages.push(String::from(message));
| ^^^^^^^^^^^^^^^^^^ cannot mutably borrow immutable field
We can’t modify the MockMessenger
to keep track of the messages, because the
send
method takes an immutable reference to self
. We also can’t take the
suggestion from the error text to use &mut self
instead, because then the
signature of send
wouldn’t match the signature in the Messenger
trait
definition (feel free to try and see what error message you get).
This is a situation in which interior mutability can help! We’ll store the
sent_messages
within a RefCell<T>
, and then the send
message will be
able to modify sent_messages
to store the messages we’ve seen. Listing 15-22
shows what that looks like:
Filename: src/lib.rs
# #![allow(unused_variables)] #fn main() { #[cfg(test)] mod tests { use super::*; use std::cell::RefCell; struct MockMessenger { sent_messages: RefCell<Vec<String>>, } impl MockMessenger { fn new() -> MockMessenger { MockMessenger { sent_messages: RefCell::new(vec![]) } } } impl Messenger for MockMessenger { fn send(&self, message: &str) { self.sent_messages.borrow_mut().push(String::from(message)); } } #[test] fn it_sends_an_over_75_percent_warning_message() { // --snip-- # let mock_messenger = MockMessenger::new(); # let mut limit_tracker = LimitTracker::new(&mock_messenger, 100); # limit_tracker.set_value(75); assert_eq!(mock_messenger.sent_messages.borrow().len(), 1); } } #}
The sent_messages
field is now of type RefCell<Vec<String>>
instead of
Vec<String>
. In the new
function, we create a new RefCell<Vec<String>>
instance around the empty vector.
For the implementation of the send
method, the first parameter is still an
immutable borrow of self
, which matches the trait definition. We call
borrow_mut
on the RefCell<Vec<String>>
in self.sent_messages
to get a
mutable reference to the value inside the RefCell<Vec<String>>
, which is
the vector. Then we can call push
on the mutable reference to the vector to
keep track of the messages sent during the test.
The last change we have to make is in the assertion: to see how many items are
in the inner vector, we call borrow
on the RefCell<Vec<String>>
to get an
immutable reference to the vector.
Now that you’ve seen how to use RefCell<T>
, let’s dig into how it works!
Keeping Track of Borrows at Runtime with RefCell<T>
When creating immutable and mutable references, we use the &
and &mut
syntax, respectively. With RefCell<T>
, we use the borrow
and borrow_mut
methods, which are part of the safe API that belongs to RefCell<T>
. The
borrow
method returns the smart pointer type Ref<T>
, and borrow_mut
returns the smart pointer type RefMut<T>
. Both types implement Deref
, so we
can treat them like regular references.
The RefCell<T>
keeps track of how many Ref<T>
and RefMut<T>
smart
pointers are currently active. Every time we call borrow
, the RefCell<T>
increases its count of how many immutable borrows are active. When a Ref<T>
value goes out of scope, the count of immutable borrows goes down by one. Just
like the compile-time borrowing rules, RefCell<T>
lets us have many immutable
borrows or one mutable borrow at any point in time.
If we try to violate these rules, rather than getting a compiler error as we
would with references, the implementation of RefCell<T>
will panic at
runtime. Listing 15-23 shows a modification of the implementation of send
in
Listing 15-22. We’re deliberately trying to create two mutable borrows active
for the same scope to illustrate that RefCell<T>
prevents us from doing this
at runtime.
Filename: src/lib.rs
impl Messenger for MockMessenger {
fn send(&self, message: &str) {
let mut one_borrow = self.sent_messages.borrow_mut();
let mut two_borrow = self.sent_messages.borrow_mut();
one_borrow.push(String::from(message));
two_borrow.push(String::from(message));
}
}
We create a variable one_borrow
for the RefMut<T>
smart pointer returned
from borrow_mut
. Then we create another mutable borrow in the same way in the
variable two_borrow
. This makes two mutable references in the same scope,
which isn’t allowed. When we run the tests for our library, the code in Listing
15-23 will compile without any errors, but the test will fail:
---- tests::it_sends_an_over_75_percent_warning_message stdout ----
thread 'tests::it_sends_an_over_75_percent_warning_message' panicked at
'already borrowed: BorrowMutError', src/libcore/result.rs:906:4
note: Run with `RUST_BACKTRACE=1` for a backtrace.
Notice that the code panicked with the message already borrowed: BorrowMutError
. This is how RefCell<T>
handles violations of the borrowing
rules at runtime.
Catching borrowing errors at runtime rather than compile time means that you
would find a mistake in your code later in the development process and possibly
not until your code was deployed to production. Also, your code would incur a
small runtime performance penalty as a result of keeping track of the borrows
at runtime rather than compile time. However, using RefCell<T>
makes it
possible to write a mock object that can modify itself to keep track of the
messages it has seen while you’re using it in a context where only immutable
values are allowed. You can use RefCell<T>
despite its trade-offs to get more
functionality than regular references provide.
Having Multiple Owners of Mutable Data by Combining Rc<T>
and RefCell<T>
A common way to use RefCell<T>
is in combination with Rc<T>
. Recall that
Rc<T>
lets you have multiple owners of some data, but it only gives immutable
access to that data. If you have an Rc<T>
that holds a RefCell<T>
, you can
get a value that can have multiple owners and that you can mutate!
For example, recall the cons list example in Listing 15-18 where we used
Rc<T>
to allow multiple lists to share ownership of another list. Because
Rc<T>
holds only immutable values, we can’t change any of the values in the
list once we’ve created them. Let’s add in RefCell<T>
to gain the ability to
change the values in the lists. Listing 15-24 shows that by using a
RefCell<T>
in the Cons
definition, we can modify the value stored in all
the lists:
Filename: src/main.rs
#[derive(Debug)] enum List { Cons(Rc<RefCell<i32>>, Rc<List>), Nil, } use List::{Cons, Nil}; use std::rc::Rc; use std::cell::RefCell; fn main() { let value = Rc::new(RefCell::new(5)); let a = Rc::new(Cons(Rc::clone(&value), Rc::new(Nil))); let b = Cons(Rc::new(RefCell::new(6)), Rc::clone(&a)); let c = Cons(Rc::new(RefCell::new(10)), Rc::clone(&a)); *value.borrow_mut() += 10; println!("a after = {:?}", a); println!("b after = {:?}", b); println!("c after = {:?}", c); }
We create a value that is an instance of Rc<RefCell<i32>>
and store it in a
variable named value
so we can access it directly later. Then we create a
List
in a
with a Cons
variant that holds value
. We need to clone
value
so both a
and value
have ownership of the inner 5
value rather
than transferring ownership from value
to a
or having a
borrow from
value
.
We wrap the list a
in an Rc<T>
so when we create lists b
and c
, they
can both refer to a
, which is what we did in Listing 15-18.
After we’ve created the lists in a
, b
, and c
, we add 10 to the value in
value
. We do this by calling borrow_mut
on value
, which uses the
automatic dereferencing feature we discussed in Chapter 5 (see the section
“Where’s the ->
Operator?”) to dereference the Rc<T>
to the inner
RefCell<T>
value. The borrow_mut
method returns a RefMut<T>
smart
pointer, and we use the dereference operator on it and change the inner value.
When we print a
, b
, and c
, we can see that they all have the modified
value of 15 rather than 5:
a after = Cons(RefCell { value: 15 }, Nil)
b after = Cons(RefCell { value: 6 }, Cons(RefCell { value: 15 }, Nil))
c after = Cons(RefCell { value: 10 }, Cons(RefCell { value: 15 }, Nil))
This technique is pretty neat! By using RefCell<T>
, we have an outwardly
immutable List
value. But we can use the methods on RefCell<T>
that provide
access to its interior mutability so we can modify our data when we need to.
The runtime checks of the borrowing rules protect us from data races, and it’s
sometimes worth trading a bit of speed for this flexibility in our data
structures.
The standard library has other types that provide interior mutability, such as
Cell<T>
, which is similar except that instead of giving references to the
inner value, the value is copied in and out of the Cell<T>
. There’s also
Mutex<T>
, which offers interior mutability that’s safe to use across threads;
we’ll discuss its use in Chapter 16. Check out the standard library docs for
more details on the differences between these types.