Introduction
About 9 months ago we announced the creation of the Keyword Generics
Initiative; a group working under the lang team with the intent to solve the
function coloring problem 1 through the type system not just for
async
, but for const
and all current and future function modifier keywords
as well.
We're happy to share that we've made a lot of progress over these last several months, and we're finally ready to start putting some of our designs forward through RFCs. Because it's been a while since our last update, and because we're excited to share what we've been working on, in this post we'll be going over some of the things we're planning to propose.
An async example
In our previous post we introduced the placeholder async<A>
syntax to describe the
concept of a "function which is generic over its asyncness". We always knew we
wanted something that felt lighter weight than that, so in for our current design
we've chosen to drop the notion of a generic parameter for the end-user syntax,
and instead picked the ?async
notation. We've borrowed this from the trait
system, where for example + ?Sized
indicates that something may or may not
implement the Sized
trait. Similarly ?async
means a function may or may not be
async. We also refer to these as "maybe-async" functions.
Time for an example. Say we took the Read
trait and the
read_to_string_methods. In the stdlib their implementations look somewhat
like this today:
trait Read {
fn read(&mut self, buf: &mut [u8]) -> Result<usize>;
fn read_to_string(&mut self, buf: &mut String) -> Result<usize> { ... }
}
/// Read from a reader into a string.
fn read_to_string(reader: &mut impl Read) -> std::io::Result<String> {
let mut string = String::new();
reader.read_to_string(&mut string)?;
Ok(string)
}
Now, what if we wanted to make these async in the future? Using ?async
notation we could change them to look like this:
trait ?async Read {
?async fn read(&mut self, buf: &mut [u8]) -> Result<usize>;
?async fn read_to_string(&mut self, buf: &mut String) -> Result<usize> { ... }
}
/// Read from a reader into a string.
?async fn read_to_string(reader: &mut impl ?async Read) -> std::io::Result<String> {
let mut string = String::new();
reader.read_to_string(&mut string).await?;
Ok(string)
}
The way this would work is that Read
and read_to_string
would become generic over
their "asyncness". When compiled for an async
context, they will behave
asynchronously. When compiled in a non-async context, they will behave
synchronously. The .await
in the read_to_string
function body is necessary
to mark the cancellation point in case the function is compiled as async; but
when not async would essentially become a no-op 2:
// `read_to_string` is inferred to be `!async` because
// we didn't `.await` it, nor expected a future of any kind.
#[test]
fn sync_call() {
let _string = read_to_string("file.txt")?;
}
// `read_to_string` is inferred to be `async` because
// we `.await`ed it.
#[async_std::test]
async fn async_call() {
let _string = read_to_string("file.txt").await?;
}
We expect ?async
notation would be most useful for library code which doesn't
do anything particularly specific to async Rust. Think: most of the stdlib, and
ecosystem libraries such as parsers, encoders, and drivers. We expect most
applications to choose to be compiled either as async or non-async, making them
mostly a consumer of ?async
APIs.
A const example
A main driver of the keywords generics initiative has been our desire to make the different modifier keywords in Rust feel consistent with one another. Both the const WG and the async WG were thinking about introducing keyword-traits at the same time, and we figured we should probably start talking with each other to make sure that what we were going to introduce felt like it was part of the same language - and could be extended to support more keywords in the future.
So with that in mind, it may be unsurprising that for the maybe-const
trait
bounds and declarations we're going to propose using the ?const
notation.
A common source of confusion with const fn
is that it actually doesn't
guarantee compile-time execution; it only means that it's possible to evaluate
in a const
compile-time context. So in a way const fn
has always been a way
of declaring a "maybe-const" function, and there isn't a way to declare an
"always-const" function. More on that later in this post.
Taking the Read
example we used earlier, we could imagine a "maybe-const" version
of the Read
trait to look very similar:
trait ?const Read {
?const fn read(&mut self, buf: &mut [u8]) -> Result<usize>;
?const fn read_to_string(&mut self, buf: &mut String) -> Result<usize> { ... }
}
Which we could then use use as a bound in the const read_to_string
function,
like this:
const fn read_to_string(reader: &mut impl ?const Read) -> std::io::Result<String> {
let mut string = String::new();
reader.read_to_string(&mut string)?;
Ok(string)
}
Just like with ?async
traits, ?const
traits would also need to be labeled as
?const
when used as a bound. This is important to surface at the trait level,
because it's allowed to pass non-const bounds to maybe-const functions, as long
as no trait methods are called in the function body. This means we need to
distinguish between "never-const" and "maybe-const".
You may have noticed the ?const
on the trait declaration and the extra
?const
on the trait methods. This is on purpose: it keeps the path open to
potentially add support for "always-const" or "never-const" methods on traits as
well. In ?async
we know that even if the entire trait is ?async
, some
methods (such as Iterator::size_hint
) will never be async. And this would
make ?const
and ?async
traits behave similarly using the same rules.
Combining const and async
We've covered ?async
, and we've covered ?const
. Now what happens if we were
to use them together? Let's take a look at what the Read
trait would look like
when if we extended it using our designs for ?const
and ?async
:
trait ?const ?async Read {
?const ?async fn read(&mut self, buf: &mut [u8]) -> Result<usize>;
?const ?async fn read_to_string(&mut self, buf: &mut String) -> Result<usize> { .. }
}
/// Read from a reader into a string.
const ?async fn read_to_string(reader: &mut impl ?const ?async Read) -> io::Result<String> {
let mut string = String::new();
reader.read_to_string(&mut string).await?;
Ok(string)
}
That's sure starting to feel like a lot of keywords, right? We've accurately
described exactly what's going on, but there's a lot of repetition. We know that
if we're dealing with a const ?async fn
, most arguments probably will
want to be ?const ?async
. But under the syntax rules we've proposed so far,
you'd end up repeating that everywhere. And it probably gets worse once we start
adding in more keywords. Not ideal!
So we're very eager to make sure that we find a solution to this. And we've been
thinking about a way we could get out of this, which we've been calling
effect/.do
-notation. This would allow you to mark a function as "generic over
all modifier keywords" by annotating it as effect fn
, and it would allow the
compiler to insert all the right .await
, ?
, and yield
keywords in the
function body by suffixing function calls with .do
.
Just to set some expectations: this is the least developed part of our proposal,
and we don't intend to formally propose this until after we're done with some of
the other proposals. But we think it's an important part of the entire vision,
so we wanted to make sure we shared it here. And with that out of the way,
here's the same example we had above, but this time using the effect/.do
-notation:
trait ?effect Read {
?effect fn read(&mut self, buf: &mut [u8]) -> Result<usize>;
?effect fn read_to_string(&mut self, buf: &mut String) -> Result<usize> { .. }
}
/// Read from a reader into a string.
?effect fn read_to_string(reader: &mut impl ?effect Read) -> std::io::Result<String> {
let mut string = String::new();
reader.read_to_string(&mut string).do; // note the singular `.do` here
string
}
One of the things we would like to figure out as part of effect/.do
is a way
to enable writing conditional effect-bounds. For example: there may be a
function which is always async, may never panic, and is generic over the
remainder of the effects. Or like we're seeing with APIs such as
Vec::reserve
and Vec::try_reserve
: the ability to panic xor return an
error. This will take more time and research to figure out, but we believe it
is something which can be solved.
Adding support for types
Something we're keen on doing is not just adding support for ?async
and to
apply to functions, traits, and trait bounds. We would like ?async
to be
possible to use with types as well. This would enable the ecosystem to stop
having to provide both sync and async versions of crates. It would also enable
the stdlib to gradually "asyncify" just like we have been with const.
The challenge with async types, especially in the stdlib, is that their behavior
will often have to be different when used in async and non-async contexts. At
the very lowest level async system calls work a bit differently from non-async
system calls. But we think we may have a solution for that too in the form of
the is_async
compiler built-in method.
Say we wanted to implement ?async File
with a single ?async open
method. The
way we expect this to look will be something like this:
/// A file which may or may not be async
struct ?async File {
file_descriptor: std::os::RawFd, // shared field in all contexts
async waker: Waker, // field only available in async contexts
!async meta: Metadata, // field only available in non-async contexts
}
impl ?async File {
/// Attempts to open a file in read-only mode.
?async fn open(path: Path) -> io::Result<Self> {
if is_async() { // compiler built-in function
// create an async `File` here; can use `.await`
} else {
// create a non-async `File` here
}
}
}
This would enable authors to use different fields depending on whether they're
compiling for async or not, while still sharing a common core. And within
function bodies it would be possible to provide different behaviors depending on
the context as well. The function body notation would work as a generalization
of the currently unstable const_eval_select
intrinsic, and at
least for the function bodies we expect a similar is_const()
compiler built-in
to be made available as well.
Consistent syntax
As we alluded to earlier in the post: one of the biggest challenges we see in language design is adding features in a way that makes them feel like they're in harmony with the rest of the language - and not something which stands out as noticably different. And because we're touching on something core to Rust, the way we do keywords, we have to pay extra close attention here to make sure Rust keeps feeling like a single language.
Luckily Rust has the ability to make surface-level changes to the
language through the edition system. There are many things this doesn't let us
do, but it does allow us to require syntax changes. A possibility we're
exploring is leveraging the edition system to make some minor changes to const
and async
so they feel more consistent with one another, and with ?const
and
?async
.
For const
this means there should be a syntactic distinction between const
declarations and const
uses. Like we mentioned earlier in the post, when you
write const fn
you get a function which can be evaluated both at runtime and
during compilation. But when you write const FOO: () = ..;
the meaning of
const
there guarantees compile-time evaluation. One keyword, different
meanings. So for that reason we're wondering whether perhaps it would make more
sense if we changed const fn
to ?const fn
. This would make it clear that
it's a function which may be const-evaluated, but doesn't necessarily have to -
and can also be called from non-const
contexts.
//! Define a function which may be evaluated both at runtime and during
//! compilation.
// Current
const fn meow() -> String { .. }
// Proposed
?const fn meow() -> String { .. }
For async
we're considering some similar surface-level changes. The Async WG
is in the process of expanding the "async functions in traits" design into an
design covering "async traits" entirely, largely motivated by the desire to be
able to add + Send
bound to anonymous futures. There are more details about
this in "Lightweight, Predictable Async Send Bounds" by Eric
Holk. But it would roughly become the following notation:
struct File { .. }
impl async Read for File { // async trait declaration
async fn read(&mut self, buf: &mut [u8]) -> io::Result<usize> { .. } // async method
}
async fn read_to_string(reader: &mut impl async Read) -> io::Result<String> { // async trait bound
let mut string = String::new();
reader.read_to_string(&mut string).await?;
Ok(string)
}
This would make impl ?async Read
and impl async Read
consistent with each
other. And it would open the door for trait ?async
traits to be passed to
impl async Read
and be guaranteed to be always interpreted as trait async
.
Which is another nice consistency gain.
The final thing we're looking at is async
-notation for types. To implement
inherent ?async
methods on types, our current design requires the type to also
be marked as ?async
. In order to bring ?async
and async
closer together,
we're exploring whether it might also make sense to require types to be marked
as async
as well:
//! Proposed: define a method on a maybe-async type
struct ?async File { .. }
impl ?async File {
?async fn open(path: PathBuf) -> io::Result<Self> { .. }
}
//! Current: define a method on an always-async type
struct File { .. }
impl File {
async fn open(path: PathBuf) -> io::Result<Self> { .. }
}
//! Proposed: define a method on an always-async type
struct async File { .. }
impl async File {
async fn open(path: PathBuf) -> io::Result<Self> { .. }
}
We already have something similar going on for "always-const" arguments via the const-generics system. These look something like this:
fn foo<const N: usize>() {}
Every "always-const" argument to the function must always be marked by const
,
so it wouldn't be entirely without precedent for every "always-async" type to
always require to be marked using async
. So we're exploring some of what might
be possible here.
The tentative plan
We plan to initially focus our efforts on the async
and const
keywords only.
We're feeling ready to start converting some of our designs into RFCs, and start
putting them out for review. In the coming months we expect to start writing
the following proposals (in no particular order):
?async fn
notation without trait bounds, including anis_async
mechanism.trait async
declarations and bounds.trait ?async
declarations and bounds,trait ?const
declarations and bounds.?const fn
notation without trait bounds.struct async
notation andstruct ?const
notation.
We'll be working closely with the Lang Team, Const WG, and Async WG on these
proposals, and in some cases (such as trait async
) we may even take an
advising role with a WG directly driving the RFC. As usual, these will be going
through the RFC-nightly-stabilization cycle. And only once we're fully confident
in them will they become available on stable Rust.
We're intentionally not yet including effect/.do
notation on this roadmap. We
expect to only be able to start this work once we have ?async
on nightly,
which we don't yet have. So for now we'll continue work on designing it within
the initiative, and hold off on making plans to introduce it quiet yet.
Conclusion
And that concludes the 9-month progress report of the Keyword Generics Initiative. We hope to be able to provide more exact details about things such as desugarings, semantics, and alternatives in the RFCs. We're pretty stoked with the progress we've made in these past few months! Something which I don't think we've mentioned yet, but is probably good to share: we've actually prototyped much of the work in this post already; so we're feeling fairly confident all of this may actually actually work. And that is something we're incredibly excited for!
-
To briefly recap this problem: you can't call an
async fn
from a non-async fn. This makes the "async" notation go viral, as every function that calls it also needs to be async. But we believe possibly more importantly: it requires a duplication of most stdlib types and ecosystem libraries. Instead we suspected we might be able to overcome this issue by introducing a new kind of generic which would enable functions and types to be "generic" over whether they're async or not, const or not, etc. ↩ -
One restriction
?async
contexts have is that they can only call other?async
and non-async
functions. Because if we could call an always-async
function, there would be no clear right thing to do when compiled in non-async mode. So things like async concurrency operations won't directly work in always-async contexts. But we have a way out of this we talk about later in the post:if is_async() .. else ..
. This allows you to branch the body of a?async fn
based on which mode it's being compiled in, and will allow you to write different logic for async and non-async modes. This means you can choose to use async concurrency in the async version, but keep things sequential in the non-async version. ↩