generators
The tracking issue for this feature is: #43122
The generators
feature gate in Rust allows you to define generator or
coroutine literals. A generator is a "resumable function" that syntactically
resembles a closure but compiles to much different semantics in the compiler
itself. The primary feature of a generator is that it can be suspended during
execution to be resumed at a later date. Generators use the yield
keyword to
"return", and then the caller can resume
a generator to resume execution just
after the yield
keyword.
Generators are an extra-unstable feature in the compiler right now. Added in RFC 2033 they're mostly intended right now as a information/constraint gathering phase. The intent is that experimentation can happen on the nightly compiler before actual stabilization. A further RFC will be required to stabilize generators/coroutines and will likely contain at least a few small tweaks to the overall design.
A syntactical example of a generator is:
#![feature(generators, generator_trait)] use std::ops::{Generator, GeneratorState}; fn main() { let mut generator = || { yield 1; return "foo" }; match unsafe { generator.resume() } { GeneratorState::Yielded(1) => {} _ => panic!("unexpected value from resume"), } match unsafe { generator.resume() } { GeneratorState::Complete("foo") => {} _ => panic!("unexpected value from resume"), } }
Generators are closure-like literals which can contain a yield
statement. The
yield
statement takes an optional expression of a value to yield out of the
generator. All generator literals implement the Generator
trait in the
std::ops
module. The Generator
trait has one main method, resume
, which
resumes execution of the generator at the previous suspension point.
An example of the control flow of generators is that the following example prints all numbers in order:
#![feature(generators, generator_trait)] use std::ops::Generator; fn main() { let mut generator = || { println!("2"); yield; println!("4"); }; println!("1"); unsafe { generator.resume() }; println!("3"); unsafe { generator.resume() }; println!("5"); }
At this time the main intended use case of generators is an implementation primitive for async/await syntax, but generators will likely be extended to ergonomic implementations of iterators and other primitives in the future. Feedback on the design and usage is always appreciated!
The Generator
trait
The Generator
trait in std::ops
currently looks like:
# #![feature(generator_trait)]
# use std::ops::GeneratorState;
pub trait Generator {
type Yield;
type Return;
unsafe fn resume(&mut self) -> GeneratorState<Self::Yield, Self::Return>;
}
The Generator::Yield
type is the type of values that can be yielded with the
yield
statement. The Generator::Return
type is the returned type of the
generator. This is typically the last expression in a generator's definition or
any value passed to return
in a generator. The resume
function is the entry
point for executing the Generator
itself.
The return value of resume
, GeneratorState
, looks like:
pub enum GeneratorState<Y, R> {
Yielded(Y),
Complete(R),
}
The Yielded
variant indicates that the generator can later be resumed. This
corresponds to a yield
point in a generator. The Complete
variant indicates
that the generator is complete and cannot be resumed again. Calling resume
after a generator has returned Complete
will likely result in a panic of the
program.
Closure-like semantics
The closure-like syntax for generators alludes to the fact that they also have closure-like semantics. Namely:
-
When created, a generator executes no code. A closure literal does not actually execute any of the closure's code on construction, and similarly a generator literal does not execute any code inside the generator when constructed.
-
Generators can capture outer variables by reference or by move, and this can be tweaked with the
move
keyword at the beginning of the closure. Like closures all generators will have an implicit environment which is inferred by the compiler. Outer variables can be moved into a generator for use as the generator progresses. -
Generator literals produce a value with a unique type which implements the
std::ops::Generator
trait. This allows actual execution of the generator through theGenerator::resume
method as well as also naming it in return types and such. -
Traits like
Send
andSync
are automatically implemented for aGenerator
depending on the captured variables of the environment. Unlike closures, generators also depend on variables live across suspension points. This means that although the ambient environment may beSend
orSync
, the generator itself may not be due to internal variables live acrossyield
points being not-Send
or not-Sync
. Note that generators, like closures, do not implement traits likeCopy
orClone
automatically. -
Whenever a generator is dropped it will drop all captured environment variables.
Note that unlike closures generators at this time cannot take any arguments.
That is, generators must always look like || { ... }
. This restriction may be
lifted at a future date, the design is ongoing!
Generators as state machines
In the compiler, generators are currently compiled as state machines. Each
yield
expression will correspond to a different state that stores all live
variables over that suspension point. Resumption of a generator will dispatch on
the current state and then execute internally until a yield
is reached, at
which point all state is saved off in the generator and a value is returned.
Let's take a look at an example to see what's going on here:
#![feature(generators, generator_trait)] use std::ops::Generator; fn main() { let ret = "foo"; let mut generator = move || { yield 1; return ret }; unsafe { generator.resume() }; unsafe { generator.resume() }; }
This generator literal will compile down to something similar to:
#![feature(generators, generator_trait)] use std::ops::{Generator, GeneratorState}; fn main() { let ret = "foo"; let mut generator = { enum __Generator { Start(&'static str), Yield1(&'static str), Done, } impl Generator for __Generator { type Yield = i32; type Return = &'static str; unsafe fn resume(&mut self) -> GeneratorState<i32, &'static str> { use std::mem; match mem::replace(self, __Generator::Done) { __Generator::Start(s) => { *self = __Generator::Yield1(s); GeneratorState::Yielded(1) } __Generator::Yield1(s) => { *self = __Generator::Done; GeneratorState::Complete(s) } __Generator::Done => { panic!("generator resumed after completion") } } } } __Generator::Start(ret) }; unsafe { generator.resume() }; unsafe { generator.resume() }; }
Notably here we can see that the compiler is generating a fresh type,
__Generator
in this case. This type has a number of states (represented here
as an enum
) corresponding to each of the conceptual states of the generator.
At the beginning we're closing over our outer variable foo
and then that
variable is also live over the yield
point, so it's stored in both states.
When the generator starts it'll immediately yield 1, but it saves off its state
just before it does so indicating that it has reached the yield point. Upon
resuming again we'll execute the return ret
which returns the Complete
state.
Here we can also note that the Done
state, if resumed, panics immediately as
it's invalid to resume a completed generator. It's also worth noting that this
is just a rough desugaring, not a normative specification for what the compiler
does.