- Feature Name: dst_coercions
- Start Date: 2015-03-16
- RFC PR: rust-lang/rfcs#982
- Rust Issue: rust-lang/rust#18598
Summary
Custom coercions allow smart pointers to fully participate in the DST system.
In particular, they allow practical use of Rc<T>
and Arc<T>
where T
is unsized.
This RFC subsumes part of RFC 401 coercions.
Motivation
DST is not really finished without this, in particular there is a need for types
like reference counted trait objects (Rc<Trait>
) which are not currently well-
supported (without coercions, it is pretty much impossible to create such values
with such a type).
Detailed design
There is an Unsize
trait and lang item. This trait signals that a type can be
converted using the compiler’s coercion machinery from a sized to an unsized
type. All implementations of this trait are implicit and compiler generated. It
is an error to implement this trait. If &T
can be coerced to &U
then there
will be an implementation of Unsize<U>
for T
. E.g, [i32; 42]: Unsize<[i32]>
. Note that the existence of an Unsize
impl does not signify a
coercion can itself can take place, it represents an internal part of the
coercion mechanism (it corresponds with coerce_inner
from RFC 401). The trait
is defined as:
#[lang="unsize"]
trait Unsize<T: ?Sized>: ::std::marker::PhantomFn<Self, T> {}
There are implementations for any fixed size array to the corresponding unsized
array, for any type to any trait that that type implements, for structs and
tuples where the last field can be unsized, and for any pair of traits where
Self
is a sub-trait of T
(see RFC 401 for more details).
There is a CoerceUnsized
trait which is implemented by smart pointer types to
opt-in to DST coercions. It is defined as:
#[lang="coerce_unsized"]
trait CoerceUnsized<Target>: ::std::marker::PhantomFn<Self, Target> + Sized {}
An example implementation:
impl<T: ?Sized+Unsize<U>, U: ?Sized> CoerceUnsized<Rc<U>> for Rc<T> {}
impl<T: Zeroable+CoerceUnsized<U>, U: Zeroable> CoerceUnsized<NonZero<U>> for NonZero<T> {}
// For reference, the definitions of Rc and NonZero:
pub struct Rc<T: ?Sized> {
_ptr: NonZero<*mut RcBox<T>>,
}
pub struct NonZero<T: Zeroable>(T);
Implementing CoerceUnsized
indicates that the self type should be able to be
coerced to the Target
type. E.g., the above implementation means that
Rc<[i32; 42]>
can be coerced to Rc<[i32]>
. There will be CoerceUnsized
impls
for the various pointer kinds available in Rust and which allow coercions, therefore
CoerceUnsized
when used as a bound indicates coercible types. E.g.,
fn foo<T: CoerceUnsized<U>, U>(x: T) -> U {
x
}
Built-in pointer impls:
impl<'a, 'b: 'aT: ?Sized+Unsize<U>, U: ?Sized> CoerceUnsized<&'a U> for &'b mut T {}
impl<'a, T: ?Sized+Unsize<U>, U: ?Sized> CoerceUnsized<&'a mut U> for &'a mut T {}
impl<'a, T: ?Sized+Unsize<U>, U: ?Sized> CoerceUnsized<*const U> for &'a mut T {}
impl<'a, T: ?Sized+Unsize<U>, U: ?Sized> CoerceUnsized<*mut U> for &'a mut T {}
impl<'a, 'b: 'a, T: ?Sized+Unsize<U>, U: ?Sized> CoerceUnsized<&'a U> for &'b T {}
impl<'b, T: ?Sized+Unsize<U>, U: ?Sized> CoerceUnsized<*const U> for &'b T {}
impl<T: ?Sized+Unsize<U>, U: ?Sized> CoerceUnsized<*const U> for *mut T {}
impl<T: ?Sized+Unsize<U>, U: ?Sized> CoerceUnsized<*mut U> for *mut T {}
impl<T: ?Sized+Unsize<U>, U: ?Sized> CoerceUnsized<*const U> for *const T {}
Note that there are some coercions which are not given by CoerceUnsized
, e.g.,
from safe to unsafe function pointers, so it really is a CoerceUnsized
trait,
not a general Coerce
trait.
Compiler checking
On encountering an implementation of CoerceUnsized
(type collection phase)
- If the impl is for a built-in pointer type, we check nothing, otherwise…
- The compiler checks that the
Self
type is a struct or tuple struct and that theTarget
type is a simple substitution of type parameters from theSelf
type (i.e., ThatSelf
isFoo<Ts>
,Target
isFoo<Us>
and that there existVs
andXs
(whereXs
are all type parameters) such thatTarget = [Vs/Xs]Self
. One day, with HKT, this could be a regular part of type checking, for now it must be an ad hoc check). We might enforce that this substitution is of the formX/Y
whereX
andY
are both formal type parameters of the implementation (I don’t think this is necessary, but it makes checking coercions easier and is satisfied for all smart pointers). - The compiler checks each field in the
Self
type against the corresponding field in theTarget
type. AssumingFs
is the type of a field inSelf
andFt
is the type of the corresponding field inTarget
, then eitherFt <: Fs
orFs: CoerceUnsized<Ft>
(note that this includes some built-in coercions, coercions unrelated to unsizing are excluded, these could probably be added later, if needed). - There must be only one non-PhantomData field that is coerced.
- We record for each impl, the index of the field in the
Self
type which is coerced.
On encountering a potential coercion (type checking phase)
-
If we have an expression with type
E
where the typeF
is required during type checking andE
is not a subtype ofF
, nor is it coercible using the built-in coercions, then we search for a bound ofE: CoerceUnsized<F>
. Note that we may not at this stage find the actual impl, but finding the bound is good enough for type checking. -
If we require a coercion in the receiver of a method call or field lookup, we perform the same search that we currently do, except that where we currently check for coercions, we check for built-in coercions and then for
CoerceUnsized
bounds. We must also check forUnsize
bounds for the case where the receiver is auto-deref’ed, but not autoref’ed.
On encountering an adjustment (translation phase)
- In trans (which is post-monomorphisation) we should always be able to find an
impl for any
CoerceUnsized
bound. - If the impl is for a built-in pointer type, then we use the current coercion
code for the various pointer kinds (
Box<T>
has different behaviour than&
and*
pointers). - Otherwise, we lookup which field is coerced due to the opt-in coercion, move the object being coerced and coerce the field in question by recursing (the built-in pointers are the base cases).
Adjustment types
We add AdjustCustom
to the AutoAdjustment
enum as a placeholder for coercions
due to a CoerceUnsized
bound. I don’t think we need the UnsizeKind
enum at
all now, since all checking is postponed until trans or relies on traits and impls.
Drawbacks
Not as flexible as the previous proposal.
Alternatives
The original DST5 proposal contains a similar proposal with no opt-in trait, i.e., coercions are completely automatic and arbitrarily deep. This is a little too magical and unpredictable. It violates some ‘soft abstraction boundaries’ by interefering with the deep structure of objects, sometimes even automatically (and implicitly) allocating.
RFC 401
proposed a scheme for proposals where users write their own coercion using
intrinsics. Although more flexible, this allows for implicit execution of
arbitrary code. If we need the increased flexibility, I believe we can add a
manual option to the CoerceUnsized
trait backwards compatibly.
The proposed design could be tweaked: for example, we could change the
CoerceUnsized
trait in many ways (we experimented with an associated type to
indicate the field type which is coerced, for example).
Unresolved questions
It is unclear to what extent DST coercions should support multiple fields that
refer to the same type parameter. PhantomData<T>
should definitely be
supported as an “extra” field that’s skipped, but can all zero-sized fields
be skipped? Are there cases where this would enable by-passing the abstractions
that make some API safe?
Updates since being accepted
Since it was accepted, the RFC has been updated as follows:
CoerceUnsized
was specified to ignore PhantomData fields.