Shared-State Concurrency
Message passing is a fine way of handling concurrency, but it’s not the only one. Consider this part of the slogan from the Go language documentation again: “do not communicate by sharing memory.”
What would communicating by sharing memory look like? In addition, why would message-passing enthusiasts not use it and do the opposite instead?
In a way, channels in any programming language are similar to single ownership, because once you transfer a value down a channel, you should no longer use that value. Shared memory concurrency is like multiple ownership: multiple threads can access the same memory location at the same time. As you saw in Chapter 15, where smart pointers made multiple ownership possible, multiple ownership can add complexity because these different owners need managing. Rust’s type system and ownership rules greatly assist in getting this management correct. For an example, let’s look at mutexes, one of the more common concurrency primitives for shared memory.
Using Mutexes to Allow Access to Data from One Thread at a Time
Mutex is an abbreviation for mutual exclusion, as in, a mutex allows only one thread to access some data at any given time. To access the data in a mutex, a thread must first signal that it wants access by asking to acquire the mutex’s lock. The lock is a data structure that is part of the mutex that keeps track of who currently has exclusive access to the data. Therefore, the mutex is described as guarding the data it holds via the locking system.
Mutexes have a reputation for being difficult to use because you have to remember two rules:
- You must attempt to acquire the lock before using the data.
- When you’re done with the data that the mutex guards, you must unlock the data so other threads can acquire the lock.
For a real-world metaphor for a mutex, imagine a panel discussion at a conference with only one microphone. Before a panelist can speak, they have to ask or signal that they want to use the microphone. When they get the microphone, they can talk for as long as they want to and then hand the microphone to the next panelist who requests to speak. If a panelist forgets to hand the microphone off when they’re finished with it, no one else is able to speak. If management of the shared microphone goes wrong, the panel won’t work as planned!
Management of mutexes can be incredibly tricky to get right, which is why so many people are enthusiastic about channels. However, thanks to Rust’s type system and ownership rules, you can’t get locking and unlocking wrong.
The API of Mutex<T>
As an example of how to use a mutex, let’s start by using a mutex in a single-threaded context, as shown in Listing 16-12:
Filename: src/main.rs
use std::sync::Mutex; fn main() { let m = Mutex::new(5); { let mut num = m.lock().unwrap(); *num = 6; } println!("m = {:?}", m); }
As with many types, we create a Mutex<T>
using the associated function new
.
To access the data inside the mutex, we use the lock
method to acquire the
lock. This call will block the current thread so it can’t do any work until
it’s our turn to have the lock.
The call to lock
would fail if another thread holding the lock panicked. In
that case, no one would ever be able to get the lock, so we’ve chosen to
unwrap
and have this thread panic if we’re in that situation.
After we’ve acquired the lock, we can treat the return value, named num
in
this case, as a mutable reference to the data inside. The type system ensures
that we acquire a lock before using the value in m
: Mutex<i32>
is not an
i32
, so we must acquire the lock to be able to use the i32
value. We
can’t forget; the type system won’t let us access the inner i32
otherwise.
As you might suspect, Mutex<T>
is a smart pointer. More accurately, the call
to lock
returns a smart pointer called MutexGuard
, wrapped in a
LockResult
that we handled with the call to unwrap
. The MutexGuard
smart
pointer implements Deref
to point at our inner data; the smart pointer also
has a Drop
implementation that releases the lock automatically when a
MutexGuard
goes out of scope, which happens at the end of the inner scope in
Listing 16-12. As a result, we don’t risk forgetting to release the lock and
blocking the mutex from being used by other threads because the lock release
happens automatically.
After dropping the lock, we can print the mutex value and see that we were able
to change the inner i32
to 6.
Sharing a Mutex<T>
Between Multiple Threads
Now, let’s try to share a value between multiple threads using Mutex<T>
.
We’ll spin up 10 threads and have them each increment a counter value by 1, so
the counter goes from 0 to 10. The next example in Listing 16-13 will have
a compiler error, and we’ll use that error to learn more about using
Mutex<T>
and how Rust helps us use it correctly.
Filename: src/main.rs
use std::sync::Mutex;
use std::thread;
fn main() {
let counter = Mutex::new(0);
let mut handles = vec![];
for _ in 0..10 {
let handle = thread::spawn(move || {
let mut num = counter.lock().unwrap();
*num += 1;
});
handles.push(handle);
}
for handle in handles {
handle.join().unwrap();
}
println!("Result: {}", *counter.lock().unwrap());
}
We create a counter
variable to hold an i32
inside a Mutex<T>
, as we
did in Listing 16-12. Next, we create 10 threads by iterating over a range
of numbers. We use thread::spawn
and give all the threads the same closure,
one that moves the counter into the thread, acquires a lock on the Mutex<T>
by calling the lock
method, and then adds 1 to the value in the mutex. When a
thread finishes running its closure, num
will go out of scope and release the
lock so another thread can acquire it.
In the main thread, we collect all the join handles. Then, as we did in Listing
16-2, we call join
on each handle to make sure all the threads finish. At
that point, the main thread will acquire the lock and print the result of this
program.
We hinted that this example wouldn’t compile. Now let’s find out why!
$ cargo run
Compiling shared-state v0.1.0 (file:///projects/shared-state)
error[E0382]: use of moved value: `counter`
--> src/main.rs:9:36
|
5 | let counter = Mutex::new(0);
| ------- move occurs because `counter` has type `Mutex<i32>`, which does not implement the `Copy` trait
...
9 | let handle = thread::spawn(move || {
| ^^^^^^^ value moved into closure here, in previous iteration of loop
10 | let mut num = counter.lock().unwrap();
| ------- use occurs due to use in closure
For more information about this error, try `rustc --explain E0382`.
error: could not compile `shared-state` due to previous error
The error message states that the counter
value was moved in the previous
iteration of the loop. So Rust is telling us that we can’t move the ownership
of lock counter
into multiple threads. Let’s fix the compiler error with a
multiple-ownership method we discussed in Chapter 15.
Multiple Ownership with Multiple Threads
In Chapter 15, we gave a value multiple owners by using the smart pointer
Rc<T>
to create a reference counted value. Let’s do the same here and see
what happens. We’ll wrap the Mutex<T>
in Rc<T>
in Listing 16-14 and clone
the Rc<T>
before moving ownership to the thread.
Filename: src/main.rs
use std::rc::Rc;
use std::sync::Mutex;
use std::thread;
fn main() {
let counter = Rc::new(Mutex::new(0));
let mut handles = vec![];
for _ in 0..10 {
let counter = Rc::clone(&counter);
let handle = thread::spawn(move || {
let mut num = counter.lock().unwrap();
*num += 1;
});
handles.push(handle);
}
for handle in handles {
handle.join().unwrap();
}
println!("Result: {}", *counter.lock().unwrap());
}
Once again, we compile and get... different errors! The compiler is teaching us a lot.
$ cargo run
Compiling shared-state v0.1.0 (file:///projects/shared-state)
error[E0277]: `Rc<Mutex<i32>>` cannot be sent between threads safely
--> src/main.rs:11:22
|
11 | let handle = thread::spawn(move || {
| ______________________^^^^^^^^^^^^^_-
| | |
| | `Rc<Mutex<i32>>` cannot be sent between threads safely
12 | | let mut num = counter.lock().unwrap();
13 | |
14 | | *num += 1;
15 | | });
| |_________- within this `[closure@src/main.rs:11:36: 15:10]`
|
= help: within `[closure@src/main.rs:11:36: 15:10]`, the trait `Send` is not implemented for `Rc<Mutex<i32>>`
= note: required because it appears within the type `[closure@src/main.rs:11:36: 15:10]`
For more information about this error, try `rustc --explain E0277`.
error: could not compile `shared-state` due to previous error
Wow, that error message is very wordy! Here’s the important part to focus
on: `Rc<Mutex<i32>>` cannot be sent between threads safely
. The compiler
is also telling us the reason why: the trait `Send` is not implemented for `Rc<Mutex<i32>>`
. We’ll talk about Send
in the next section: it’s one of
the traits that ensures the types we use with threads are meant for use in
concurrent situations.
Unfortunately, Rc<T>
is not safe to share across threads. When Rc<T>
manages the reference count, it adds to the count for each call to clone
and
subtracts from the count when each clone is dropped. But it doesn’t use any
concurrency primitives to make sure that changes to the count can’t be
interrupted by another thread. This could lead to wrong counts—subtle bugs that
could in turn lead to memory leaks or a value being dropped before we’re done
with it. What we need is a type exactly like Rc<T>
but one that makes changes
to the reference count in a thread-safe way.
Atomic Reference Counting with Arc<T>
Fortunately, Arc<T>
is a type like Rc<T>
that is safe to use in
concurrent situations. The a stands for atomic, meaning it’s an atomically
reference counted type. Atomics are an additional kind of concurrency
primitive that we won’t cover in detail here: see the standard library
documentation for std::sync::atomic
for more details. At this point, you just
need to know that atomics work like primitive types but are safe to share
across threads.
You might then wonder why all primitive types aren’t atomic and why standard
library types aren’t implemented to use Arc<T>
by default. The reason is that
thread safety comes with a performance penalty that you only want to pay when
you really need to. If you’re just performing operations on values within a
single thread, your code can run faster if it doesn’t have to enforce the
guarantees atomics provide.
Let’s return to our example: Arc<T>
and Rc<T>
have the same API, so we fix
our program by changing the use
line, the call to new
, and the call to
clone
. The code in Listing 16-15 will finally compile and run:
Filename: src/main.rs
use std::sync::{Arc, Mutex}; use std::thread; fn main() { let counter = Arc::new(Mutex::new(0)); let mut handles = vec![]; for _ in 0..10 { let counter = Arc::clone(&counter); let handle = thread::spawn(move || { let mut num = counter.lock().unwrap(); *num += 1; }); handles.push(handle); } for handle in handles { handle.join().unwrap(); } println!("Result: {}", *counter.lock().unwrap()); }
This code will print the following:
Result: 10
We did it! We counted from 0 to 10, which may not seem very impressive, but it
did teach us a lot about Mutex<T>
and thread safety. You could also use this
program’s structure to do more complicated operations than just incrementing a
counter. Using this strategy, you can divide a calculation into independent
parts, split those parts across threads, and then use a Mutex<T>
to have each
thread update the final result with its part.
Similarities Between RefCell<T>
/Rc<T>
and Mutex<T>
/Arc<T>
You might have noticed that counter
is immutable but we could get a mutable
reference to the value inside it; this means Mutex<T>
provides interior
mutability, as the Cell
family does. In the same way we used RefCell<T>
in
Chapter 15 to allow us to mutate contents inside an Rc<T>
, we use Mutex<T>
to mutate contents inside an Arc<T>
.
Another detail to note is that Rust can’t protect you from all kinds of logic
errors when you use Mutex<T>
. Recall in Chapter 15 that using Rc<T>
came
with the risk of creating reference cycles, where two Rc<T>
values refer to
each other, causing memory leaks. Similarly, Mutex<T>
comes with the risk of
creating deadlocks. These occur when an operation needs to lock two resources
and two threads have each acquired one of the locks, causing them to wait for
each other forever. If you’re interested in deadlocks, try creating a Rust
program that has a deadlock; then research deadlock mitigation strategies for
mutexes in any language and have a go at implementing them in Rust. The
standard library API documentation for Mutex<T>
and MutexGuard
offers
useful information.
We’ll round out this chapter by talking about the Send
and Sync
traits and
how we can use them with custom types.