proxy-enum
| Crates.io | proxy-enum |
| lib.rs | proxy-enum |
| version | 0.3.1 |
| source | src |
| created_at | 2020-04-28 23:11:38.611177 |
| updated_at | 2021-01-07 05:19:32.394332 |
| description | Emulate dynamic dispatch and sealed classes using a proxy enum, which defers all method calls to its variants. |
| homepage | |
| repository | https://github.com/NyxCode/proxy-enum |
| max_upload_size | |
| id | 235154 |
| size | 17,297 |
NyxCode (NyxCode)
documentation
README
proxy-enum
Emulate dynamic dispatch and "sealed classes" using a proxy enum, which defers all method calls to its variants.
Introduction
In rust, dynamic dispatch is done using trait objects (dyn Trait).
They enable us to have runtime polymorphism, a way of expressing that a type implements a
certain trait while ignoring its concrete implementation.
let animal: &dyn Animal = random_animal();
animal.feed(); // may print "mew", "growl" or "squeak"
Trait objects come with a downside though: getting a concrete implementation back from a trait object (downcasting) is painfull. (see [std::any::Any])
If you know there are only a finite number of implentations to work with, an enum might be
better at expressing such a relationship:
enum Animal {
Cat(Cat),
Lion(Lion),
Mouse(Mouse)
}
match random_animal() {
Animal::Cat(cat) => cat.feed(),
Animal::Lion(lion) => lion.feed(),
Animal::Mouse(mouse) => mouse.feed()
}
Some languages have special support for such types, like Kotlin with so called "sealed classes".
Rust, however, does not.
proxy-enum simplifies working with such types using procedural macros.
Usage
#[proxy_enum::proxy(Animal)]
mod proxy {
enum Animal {
Cat(Cat),
Lion(Lion),
Mouse(Mouse)
}
impl Animal {
#[implement]
fn feed(&self) {}
}
}
This will expand to:
mod proxy {
enum Animal {
Cat(Cat),
Lion(Lion),
Mouse(Mouse)
}
impl Animal {
fn feed(&self) {
match self {
Animal::Cat(cat) => cat.feed(),
Animal::Lion(lion) => lion.feed(),
Animal::Mouse(mouse) => mouse.feed()
}
}
}
impl From<Cat> for Animal { /* ... */ }
impl From<Lion> for Animal { /* ... */ }
impl From<Mouse> for Animal { /* ... */ }
}
This, however, will only compile if Cat, Lion and Mouse all have a method called feed.
Since rust has traits to express common functionality, trait implentations can be generated too:
#[proxy_enum::proxy(Animal)]
mod proxy {
enum Animal {
Cat(Cat),
Lion(Lion),
Mouse(Mouse)
}
trait Eat {
fn feed(&self);
}
#[implement]
impl Eat for Animal {}
}
Since the macro has to know which methods the trait contains, it has to be defined within the module. However, implementations for external traits can be generated too:
#[proxy_enum::proxy(Animal)]
mod proxy {
enum Animal {
Cat(Cat),
Lion(Lion),
Mouse(Mouse)
}
#[external(std::string::ToString)]
trait ToString {
fn to_string(&self) -> String;
}
#[implement]
impl std::string::ToString for Animal {}
}