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| Original file line number | Diff line number | Diff line change |
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| % Choosing your Guarantees | ||
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| One important feature of Rust as language is that it lets us control the costs and guarantees | ||
| of a program. | ||
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| There are various “wrapper type” abstractions in the Rust standard library which embody | ||
| a multitude of tradeoffs between cost, ergonomics, and guarantees. Many let one choose between | ||
| run time and compile time enforcement. This section will explain a few selected abstractions in | ||
| detail. | ||
|
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| Before proceeding, it is highly recommended that one reads about [ownership][ownership] and | ||
| [borrowing][borrowing] in Rust. | ||
|
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| [ownership]: ownership.html | ||
| [borrowing]: references-and-borrowing.html | ||
|
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| # Basic pointer types | ||
|
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| ## `Box<T>` | ||
|
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| [`Box<T>`][box] is pointer which is “owned”, or a “box”. While it can hand | ||
| out references to the contained data, it is the only owner of the data. In particular, when | ||
| something like the following occurs: | ||
|
|
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| ```rust | ||
| let x = Box::new(1); | ||
| let y = x; | ||
| // x no longer accessible here | ||
| ``` | ||
|
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| Here, the box was _moved_ into `y`. As `x` no longer owns it, the compiler will no longer allow the | ||
| programmer to use `x` after this. A box can similarly be moved _out_ of a function by returning it. | ||
|
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| When a box (that hasn't been moved) goes out of scope, destructors are run. These destructors take | ||
| care of deallocating the inner data. | ||
|
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| This is a zero-cost abstraction for dynamic allocation. If you want to allocate some memory on the | ||
| heap and safely pass around a pointer to that memory, this is ideal. Note that you will only be | ||
| allowed to share references to this by the regular borrowing rules, checked at compile time. | ||
|
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| [box]: ../std/boxed/struct.Box.html | ||
|
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| ## `&T` and `&mut T` | ||
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| These are immutable and mutable references respectively. They follow the &lquo;read-write lock&rquo; | ||
| pattern, such that one may either have only one mutable reference to some data, or any number of | ||
| immutable ones, but not both. This guarantee is enforced at compile time, and has no visible cost at | ||
| runtime. In most cases these two pointer types suffice for sharing cheap references between sections | ||
| of code. | ||
|
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| These pointers cannot be copied in such a way that they outlive the lifetime associated with them. | ||
|
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| ## `*const T` and `*mut T` | ||
|
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| These are C-like raw pointers with no lifetime or ownership attached to them. They just point to | ||
| some location in memory with no other restrictions. The only guarantee that these provide is that | ||
| they cannot be dereferenced except in code marked `unsafe`. | ||
|
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| These are useful when building safe, low cost abstractions like `Vec<T>`, but should be avoided in | ||
| safe code. | ||
|
|
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| ## `Rc<T>` | ||
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| This is the first wrapper we will cover that has a runtime cost. | ||
|
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| [`Rc<T>`][rc] is a reference counted pointer. In other words, this lets us have multiple "owning" | ||
| pointers to the same data, and the data will be dropped (destructors will be run) when all pointers | ||
| are out of scope. | ||
|
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| Internally, it contains a shared “reference count” (also called “refcount”), | ||
| which is incremented each time the `Rc` is cloned, and decremented each time one of the `Rc`s goes | ||
| out of scope. The main responsibility of `Rc<T>` is to ensure that destructors are called for shared | ||
| data. | ||
|
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| The internal data here is immutable, and if a cycle of references is created, the data will be | ||
| leaked. If we want data that doesn't leak when there are cycles, we need a garbage collector. | ||
|
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| #### Guarantees | ||
|
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| The main guarantee provided here is that the data will not be destroyed until all references to it | ||
| are out of scope. | ||
|
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| This should be used when we wish to dynamically allocate and share some data (read-only) between | ||
| various portions of yur program, where it is not certain which portion will finish using the pointer | ||
| last. It's a viable alternative to `&T` when `&T` is either impossible to statically check for | ||
| correctness, or creates extremely unergonomic code where the programmer does not wish to spend the | ||
| development cost of working with. | ||
|
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| This pointer is _not_ thread safe, and Rust will not let it be sent or shared with other threads. | ||
| This lets one avoid the cost of atomics in situations where they are unnecessary. | ||
|
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| There is a sister smart pointer to this one, `Weak<T>`. This is a non-owning, but also non-borrowed, | ||
| smart pointer. It is also similar to `&T`, but it is not restricted in lifetime—a `Weak<T>` | ||
| can be held on to forever. However, it is possible that an attempt to access the inner data may fail | ||
| and return `None`, since this can outlive the owned `Rc`s. This is useful for cyclic | ||
| data structures and other things. | ||
|
|
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| #### Cost | ||
|
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| As far as memory goes, `Rc<T>` is a single allocation, though it will allocate two extra words (i.e. | ||
| two `usize` values) as compared to a regular `Box<T>` (for "strong" and "weak" refcounts). | ||
|
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| `Rc<T>` has the computational cost of incrementing/decrementing the refcount whenever it is cloned | ||
| or goes out of scope respectively. Note that a clone will not do a deep copy, rather it will simply | ||
| increment the inner reference count and return a copy of the `Rc<T>`. | ||
|
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| [rc]: ../std/rc/struct.Rc.html | ||
|
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| # Cell types | ||
|
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| &lquo;Cell&rquo;s provide interior mutability. In other words, they contain data which can be manipulated even | ||
| if the type cannot be obtained in a mutable form (for example, when it is behind an `&`-ptr or | ||
| `Rc<T>`). | ||
|
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| [The documentation for the `cell` module has a pretty good explanation for these][cell-mod]. | ||
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| These types are _generally_ found in struct fields, but they may be found elsewhere too. | ||
|
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| ## `Cell<T>` | ||
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| [`Cell<T>`][cell] is a type that provides zero-cost interior mutability, but only for `Copy` types. | ||
| Since the compiler knows that all the data owned by the contained value is on the stack, there's | ||
| no worry of leaking any data behind references (or worse!) by simply replacing the data. | ||
|
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| It is still possible to violate your own invariants using this wrapper, so be careful when using it. | ||
| If a field is wrapped in `Cell`, it's a nice indicator that the chunk of data is mutable and may not | ||
| stay the same between the time you first read it and when you intend to use it. | ||
|
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| ```rust | ||
| # use std::cell::Cell; | ||
| let x = Cell::new(1); | ||
| let y = &x; | ||
| let z = &x; | ||
| x.set(2); | ||
| y.set(3); | ||
| z.set(4); | ||
| println!("{}", x.get()); | ||
| ``` | ||
|
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| Note that here we were able to mutate the same value from various immutable references. | ||
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| This has the same runtime cost as the following: | ||
|
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| ```rust,ignore | ||
| let mut x = 1; | ||
| let y = &mut x; | ||
| let z = &mut x; | ||
| x = 2; | ||
| *y = 3; | ||
| *z = 4; | ||
| println!("{}", x); | ||
| ``` | ||
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| but it has the added benefit of actually compiling successfully. | ||
|
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| #### Guarantees | ||
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| This relaxes the “no aliasing with mutability” restriction in places where it's | ||
| unnecessary. However, this also relaxes the guarantees that the restriction provides; so if your | ||
| invariants depend on data stored within `Cell`, you should be careful. | ||
|
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| This is useful for mutating primitives and other `Copy` types when there is no easy way of | ||
| doing it in line with the static rules of `&` and `&mut`. | ||
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| `Cell` does not let you obtain interior references to the data, which makes it safe to freely | ||
| mutate. | ||
|
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| #### Cost | ||
|
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| There is no runtime cost to using `Cell<T>`, however if you are using it to wrap larger (`Copy`) | ||
| structs, it might be worthwhile to instead wrap individual fields in `Cell<T>` since each write is | ||
| otherwise a full copy of the struct. | ||
|
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|
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| ## `RefCell<T>` | ||
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| [`RefCell<T>`][refcell] also provides interior mutability, but isn't restricted to `Copy` types. | ||
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| Instead, it has a runtime cost. `RefCell<T>` enforces the read-write lock pattern at runtime (it's | ||
| like a single-threaded mutex), unlike `&T`/`&mut T` which do so at compile time. This is done by the | ||
| `borrow()` and `borrow_mut()` functions, which modify an internal reference count and return smart | ||
| pointers which can be dereferenced immutably and mutably respectively. The refcount is restored when | ||
| the smart pointers go out of scope. With this system, we can dynamically ensure that there are never | ||
| any other borrows active when a mutable borrow is active. If the programmer attempts to make such a | ||
| borrow, the thread will panic. | ||
|
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| ```rust | ||
| # use std::cell::RefCell; | ||
| let x = RefCell::new(vec![1,2,3,4]); | ||
| { | ||
| println!("{:?}", *x.borrow()) | ||
| } | ||
|
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| { | ||
| let mut my_ref = x.borrow_mut(); | ||
| my_ref.push(1); | ||
| } | ||
| ``` | ||
|
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| Similar to `Cell`, this is mainly useful for situations where it's hard or impossible to satisfy the | ||
| borrow checker. Generally we know that such mutations won't happen in a nested form, but it's good | ||
| to check. | ||
|
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| For large, complicated programs, it becomes useful to put some things in `RefCell`s to make things | ||
| simpler. For example, a lot of the maps in [the `ctxt` struct][ctxt] in the rust compiler internals | ||
| are inside this wrapper. These are only modified once (during creation, which is not right after | ||
| initialization) or a couple of times in well-separated places. However, since this struct is | ||
| pervasively used everywhere, juggling mutable and immutable pointers would be hard (perhaps | ||
| impossible) and probably form a soup of `&`-ptrs which would be hard to extend. On the other hand, | ||
| the `RefCell` provides a cheap (not zero-cost) way of safely accessing these. In the future, if | ||
| someone adds some code that attempts to modify the cell when it's already borrowed, it will cause a | ||
| (usually deterministic) panic which can be traced back to the offending borrow. | ||
|
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| Similarly, in Servo's DOM there is a lot of mutation, most of which is local to a DOM type, but some | ||
| of which crisscrosses the DOM and modifies various things. Using `RefCell` and `Cell` to guard all | ||
| mutation lets us avoid worrying about mutability everywhere, and it simultaneously highlights the | ||
| places where mutation is _actually_ happening. | ||
|
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| Note that `RefCell` should be avoided if a mostly simple solution is possible with `&` pointers. | ||
|
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| #### Guarantees | ||
|
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| `RefCell` relaxes the _static_ restrictions preventing aliased mutation, and replaces them with | ||
| _dynamic_ ones. As such the guarantees have not changed. | ||
|
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| #### Cost | ||
|
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| `RefCell` does not allocate, but it contains an additional "borrow state" | ||
| indicator (one word in size) along with the data. | ||
|
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| At runtime each borrow causes a modification/check of the refcount. | ||
|
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| [cell-mod]: ../std/cell/ | ||
| [cell]: ../std/cell/struct.Cell.html | ||
| [refcell]: ../std/cell/struct.RefCell.html | ||
| [ctxt]: ../rustc/middle/ty/struct.ctxt.html | ||
|
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| # Synchronous types | ||
|
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| Many of the types above cannot be used in a threadsafe manner. Particularly, `Rc<T>` and | ||
| `RefCell<T>`, which both use non-atomic reference counts (_atomic_ reference counts are those which | ||
| can be incremented from multiple threads without causing a data race), cannot be used this way. This | ||
| makes them cheaper to use, but we need thread safe versions of these too. They exist, in the form of | ||
| `Arc<T>` and `Mutex<T>`/`RWLock<T>` | ||
|
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| Note that the non-threadsafe types _cannot_ be sent between threads, and this is checked at compile | ||
| time. | ||
|
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| There are many useful wrappers for concurrent programming in the [sync][sync] module, but only the | ||
| major ones will be covered below. | ||
|
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| [sync]: ../std/sync/index.html | ||
|
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| ## `Arc<T>` | ||
|
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| [`Arc<T>`][arc] is just a version of `Rc<T>` that uses an atomic reference count (hence, "Arc"). | ||
| This can be sent freely between threads. | ||
|
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| C++'s `shared_ptr` is similar to `Arc`, however in the case of C++ the inner data is always mutable. | ||
| For semantics similar to that from C++, we should use `Arc<Mutex<T>>`, `Arc<RwLock<T>>`, or | ||
| `Arc<UnsafeCell<T>>`[^4] (`UnsafeCell<T>` is a cell type that can be used to hold any data and has | ||
| no runtime cost, but accessing it requires `unsafe` blocks). The last one should only be used if we | ||
| are certain that the usage won't cause any memory unsafety. Remember that writing to a struct is not | ||
| an atomic operation, and many functions like `vec.push()` can reallocate internally and cause unsafe | ||
| behavior, so even monotonicity may not be enough to justify `UnsafeCell`. | ||
|
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| [^4]: `Arc<UnsafeCell<T>>` actually won't compile since `UnsafeCell<T>` isn't `Send` or `Sync`, but we can wrap it in a type and implement `Send`/`Sync` for it manually to get `Arc<Wrapper<T>>` where `Wrapper` is `struct Wrapper<T>(UnsafeCell<T>)`. | ||
|
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| #### Guarantees | ||
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| Like `Rc`, this provides the (thread safe) guarantee that the destructor for the internal data will | ||
| be run when the last `Arc` goes out of scope (barring any cycles). | ||
|
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| #### Cost | ||
|
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| This has the added cost of using atomics for changing the refcount (which will happen whenever it is | ||
| cloned or goes out of scope). When sharing data from an `Arc` in a single thread, it is preferable | ||
| to share `&` pointers whenever possible. | ||
|
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| [arc]: ../std/sync/struct.Arc.html | ||
|
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| ## `Mutex<T>` and `RwLock<T>` | ||
|
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| [`Mutex<T>`][mutex] and [`RwLock<T>`][rwlock] provide mutual-exclusion via RAII guards (guards are | ||
| objects which maintain some state, like a lock, until their destructor is called). For both of | ||
| these, the mutex is opaque until we call `lock()` on it, at which point the thread will block | ||
| until a lock can be acquired, and then a guard will be returned. This guard can be used to access | ||
| the inner data (mutably), and the lock will be released when the guard goes out of scope. | ||
|
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| ```rust,ignore | ||
| { | ||
| let guard = mutex.lock(); | ||
| // guard dereferences mutably to the inner type | ||
| *guard += 1; | ||
| } // lock released when destructor runs | ||
| ``` | ||
|
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|
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| `RwLock` has the added benefit of being efficient for multiple reads. It is always safe to have | ||
| multiple readers to shared data as long as there are no writers; and `RwLock` lets readers acquire a | ||
| "read lock". Such locks can be acquired concurrently and are kept track of via a reference count. | ||
| Writers must obtain a "write lock" which can only be obtained when all readers have gone out of | ||
| scope. | ||
|
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| #### Guarantees | ||
|
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| Both of these provide safe shared mutability across threads, however they are prone to deadlocks. | ||
| Some level of additional protocol safety can be obtained via the type system. | ||
| #### Costs | ||
|
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| These use internal atomic-like types to maintain the locks, which are pretty costly (they can block | ||
| all memory reads across processors till they're done). Waiting on these locks can also be slow when | ||
| there's a lot of concurrent access happening. | ||
|
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| [rwlock]: ../std/sync/struct.RwLock.html | ||
| [mutex]: ../std/sync/struct.Mutex.html | ||
| [sessions]: https://github.com/Munksgaard/rust-sessions | ||
|
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| # Composition | ||
|
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| A common gripe when reading Rust code is with types like `Rc<RefCell<Vec<T>>>` (or even more more | ||
| complicated compositions of such types). It's not always clear what the composition does, or why the | ||
| author chose one like this (and when one should be using such a composition in one's own code) | ||
|
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| Usually, it's a case of composing together the guarantees that you need, without paying for stuff | ||
| that is unnecessary. | ||
|
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| For example, `Rc<RefCell<T>>` is one such composition. `Rc<T>` itself can't be dereferenced mutably; | ||
| because `Rc<T>` provides sharing and shared mutability can lead to unsafe behavior, so we put | ||
| `RefCell<T>` inside to get dynamically verified shared mutability. Now we have shared mutable data, | ||
| but it's shared in a way that there can only be one mutator (and no readers) or multiple readers. | ||
|
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| Now, we can take this a step further, and have `Rc<RefCell<Vec<T>>>` or `Rc<Vec<RefCell<T>>>`. These | ||
| are both shareable, mutable vectors, but they're not the same. | ||
|
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| With the former, the `RefCell<T>` is wrapping the `Vec<T>`, so the `Vec<T>` in its entirety is | ||
| mutable. At the same time, there can only be one mutable borrow of the whole `Vec` at a given time. | ||
| This means that your code cannot simultaneously work on different elements of the vector from | ||
| different `Rc` handles. However, we are able to push and pop from the `Vec<T>` at will. This is | ||
| similar to an `&mut Vec<T>` with the borrow checking done at runtime. | ||
|
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| With the latter, the borrowing is of individual elements, but the overall vector is immutable. Thus, | ||
| we can independently borrow separate elements, but we cannot push or pop from the vector. This is | ||
| similar to an `&mut [T]`[^3], but, again, the borrow checking is at runtime. | ||
|
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| In concurrent programs, we have a similar situation with `Arc<Mutex<T>>`, which provides shared | ||
| mutability and ownership. | ||
|
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| When reading code that uses these, go in step by step and look at the guarantees/costs provided. | ||
|
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| When choosing a composed type, we must do the reverse; figure out which guarantees we want, and at | ||
| which point of the composition we need them. For example, if there is a choice between | ||
| `Vec<RefCell<T>>` and `RefCell<Vec<T>>`, we should figure out the tradeoffs as done above and pick | ||
| one. | ||
|
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| [^3]: `&[T]` and `&mut [T]` are _slices_; they consist of a pointer and a length and can refer to a portion of a vector or array. `&mut [T]` can have its elements mutated, however its length cannot be touched. |