Exotically Sized Types

Most of the time, we expect types to have a statically known and positive size. This isn’t always the case in Rust.

Dynamically Sized Types (DSTs)

Rust supports Dynamically Sized Types (DSTs): types without a statically known size or alignment. On the surface, this is a bit nonsensical: Rust must know the size and alignment of something in order to correctly work with it! In this regard, DSTs are not normal types. Because they lack a statically known size, these types can only exist behind a pointer. Any pointer to a DST consequently becomes a wide pointer consisting of the pointer and the information that “completes” them (more on this below).

There are two major DSTs exposed by the language:

  • trait objects: dyn MyTrait
  • slices: [T], str, and others

A trait object represents some type that implements the traits it specifies. The exact original type is erased in favor of runtime reflection with a vtable containing all the information necessary to use the type. The information that completes a trait object pointer is the vtable pointer. The runtime size of the pointee can be dynamically requested from the vtable.

A slice is simply a view into some contiguous storage – typically an array or Vec. The information that completes a slice pointer is just the number of elements it points to. The runtime size of the pointee is just the statically known size of an element multiplied by the number of elements.

Structs can actually store a single DST directly as their last field, but this makes them a DST as well:

#![allow(unused)]
fn main() {
// Can't be stored on the stack directly
struct MySuperSlice {
    info: u32,
    data: [u8],
}
}

Although such a type is largely useless without a way to construct it. Currently the only properly supported way to create a custom DST is by making your type generic and performing an unsizing coercion:

struct MySuperSliceable<T: ?Sized> {
    info: u32,
    data: T,
}

fn main() {
    let sized: MySuperSliceable<[u8; 8]> = MySuperSliceable {
        info: 17,
        data: [0; 8],
    };

    let dynamic: &MySuperSliceable<[u8]> = &sized;

    // prints: "17 [0, 0, 0, 0, 0, 0, 0, 0]"
    println!("{} {:?}", dynamic.info, &dynamic.data);
}

(Yes, custom DSTs are a largely half-baked feature for now.)

Zero Sized Types (ZSTs)

Rust also allows types to be specified that occupy no space:

#![allow(unused)]
fn main() {
struct Nothing; // No fields = no size

// All fields have no size = no size
struct LotsOfNothing {
    foo: Nothing,
    qux: (),      // empty tuple has no size
    baz: [u8; 0], // empty array has no size
}
}

On their own, Zero Sized Types (ZSTs) are, for obvious reasons, pretty useless. However as with many curious layout choices in Rust, their potential is realized in a generic context: Rust largely understands that any operation that produces or stores a ZST can be reduced to a no-op. First off, storing it doesn’t even make sense – it doesn’t occupy any space. Also there’s only one value of that type, so anything that loads it can just produce it from the aether – which is also a no-op since it doesn’t occupy any space.

One of the most extreme examples of this is Sets and Maps. Given a Map<Key, Value>, it is common to implement a Set<Key> as just a thin wrapper around Map<Key, UselessJunk>. In many languages, this would necessitate allocating space for UselessJunk and doing work to store and load UselessJunk only to discard it. Proving this unnecessary would be a difficult analysis for the compiler.

However in Rust, we can just say that Set<Key> = Map<Key, ()>. Now Rust statically knows that every load and store is useless, and no allocation has any size. The result is that the monomorphized code is basically a custom implementation of a HashSet with none of the overhead that HashMap would have to support values.

Safe code need not worry about ZSTs, but unsafe code must be careful about the consequence of types with no size. In particular, pointer offsets are no-ops, and allocators typically require a non-zero size.

Note that references to ZSTs (including empty slices), just like all other references, must be non-null and suitably aligned. Dereferencing a null or unaligned pointer to a ZST is undefined behavior, just like for any other type.

Empty Types

Rust also enables types to be declared that cannot even be instantiated. These types can only be talked about at the type level, and never at the value level. Empty types can be declared by specifying an enum with no variants:

#![allow(unused)]
fn main() {
enum Void {} // No variants = EMPTY
}

Empty types are even more marginal than ZSTs. The primary motivating example for an empty type is type-level unreachability. For instance, suppose an API needs to return a Result in general, but a specific case actually is infallible. It’s actually possible to communicate this at the type level by returning a Result<T, Void>. Consumers of the API can confidently unwrap such a Result knowing that it’s statically impossible for this value to be an Err, as this would require providing a value of type Void.

In principle, Rust can do some interesting analyses and optimizations based on this fact. For instance, Result<T, Void> is represented as just T, because the Err case doesn’t actually exist (strictly speaking, this is only an optimization that is not guaranteed, so for example transmuting one into the other is still Undefined Behavior).

The following could also compile:

#![allow(unused)]
fn main() {
enum Void {}

let res: Result<u32, Void> = Ok(0);

// Err doesn't exist anymore, so Ok is actually irrefutable.
let Ok(num) = res;
}

But this trick doesn’t work yet.

One final subtle detail about empty types is that raw pointers to them are actually valid to construct, but dereferencing them is Undefined Behavior because that wouldn’t make sense.

We recommend against modelling C’s void* type with *const Void. A lot of people started doing that but quickly ran into trouble because Rust doesn’t really have any safety guards against trying to instantiate empty types with unsafe code, and if you do it, it’s Undefined Behavior. This was especially problematic because developers had a habit of converting raw pointers to references and &Void is also Undefined Behavior to construct.

*const () (or equivalent) works reasonably well for void*, and can be made into a reference without any safety problems. It still doesn’t prevent you from trying to read or write values, but at least it compiles to a no-op instead of Undefined Behavior.

Extern Types

There is an accepted RFC to add proper types with an unknown size, called extern types, which would let Rust developers model things like C’s void* and other “declared but never defined” types more accurately. However as of Rust 2018, the feature is stuck in limbo over how size_of_val::<MyExternType>() should behave.