Features/Rust/QOM: Difference between revisions
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<pre> | <pre> | ||
pub trait | pub trait ObjectCast: Copy + Deref | ||
where | |||
<Self as Deref>::Target: ObjectType, | |||
{ | |||
fn as_ref(&self) -> &Self:: | fn as_ref(&self) -> &Self::Target; | ||
fn upcast<U: ObjectType>(self) -> &U where Self:: | fn upcast<U: ObjectType>(self) -> &U where Self::Target: IsA<U>; | ||
fn downcast<U: IsA<Self:: | fn downcast<U: IsA<Self::Target>>(self) -> Option<&U>; | ||
fn dynamic_cast<U: ObjectType>(self) -> Option<&U>; | fn dynamic_cast<U: ObjectType>(self) -> Option<&U>; | ||
unsafe fn unsafe_cast<U: ObjectType>(self) -> &U; | unsafe fn unsafe_cast<U: ObjectType>(self) -> &U; | ||
} | } | ||
impl<T: ObjectType> ObjectCast for &T {} | |||
</pre> | </pre> | ||
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;trait: ObjectMethods, DeviceMethods, UserCreatableMethods, ... | ;trait: ObjectMethods, DeviceMethods, UserCreatableMethods, ... | ||
:* defines methods of non-final classes and interfaces, for example ObjectMethods::typename(&self) | :* defines methods of non-final classes and interfaces, for example ObjectMethods::typename(&self) | ||
:* automatically implemented by &T or qom::Arc<T> where T is a subclass | :* automatically implemented by &T or qom::Arc<T> where T is a subclass. The idea is that you can operate as if [https://web.mit.edu/rust-lang_v1.25/arch/amd64_ubuntu1404/share/doc/rust/html/book/first-edition/deref-coercions.html deref coercion] could also convert to superclasses. | ||
It is implemented as follows | |||
<pre> | <pre> | ||
pub | pub trait ObjectMethods: Deref | ||
where | where | ||
Self::Target: IsA<Object>, | |||
{ | |||
/// Remove the object from the QOM tree | |||
fn unparent(&self) { | |||
let obj = self.upcast::<Object>(); | |||
// SAFETY: safety of this is the requirement for implementing IsA | |||
unsafe { | |||
object_unparent(obj.as_ptr_mut()); | |||
} | |||
} | |||
} | |||
impl<R: Deref> ObjectMethods for R where R::Target: IsA<Object> {} | |||
</pre> | </pre> | ||
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<pre> | <pre> | ||
pub trait DeviceImpl: ObjectImpl + DeviceTypeImpl { | pub trait DeviceImpl: ObjectImpl + DeviceTypeImpl { | ||
const REALIZE: Option<fn(obj: &Self) -> | const REALIZE: Option<fn(obj: &Self) -> qom::Result<()>> = None; | ||
const UNREALIZE: Option<fn(obj: &Self)> = None; | const UNREALIZE: Option<fn(obj: &Self)> = None; | ||
const COLD_RESET: Option<fn(obj: &Self)> = None; | const COLD_RESET: Option<fn(obj: &Self)> = None; | ||
Line 102: | Line 116: | ||
Rust implementation types contain a configuration part (implements Default + ConstDefault) and a state part (implements Default): | Rust implementation types contain a configuration part (implements Default + ConstDefault) and a state part (implements Default): | ||
* instance_init is implemented automatically via Default/ConstDefault trait (using MaybeUninit to move the default values into the struct). | * instance_init is implemented automatically via Default/ConstDefault trait (using MaybeUninit to move the default values into the struct). | ||
**Change in common code: pre_init hook that replaces memset(obj, 0, type->instance_size)? This would allow filling in the default values of the configuration fields ''before'' property initialization. This is safer, because otherwise we have to rely entirely on qdev properties to initialize the configuration fields. | |||
* instance_finalize implemented automatically via drop_in_place | * instance_finalize implemented automatically via drop_in_place | ||
== TODO == | == TODO == |
Latest revision as of 08:43, 26 June 2024
Rust QOM interoperability design, very loosely inspired by glib-rs.
Passing objects around
- ObjectCast
-
- trait for performing casts on objects
- upcasts safe at compile time, downcasts safe at runtime
- implemented by &T
- casting &T produces &U
pub trait ObjectCast: Copy + Deref where <Self as Deref>::Target: ObjectType, { fn as_ref(&self) -> &Self::Target; fn upcast<U: ObjectType>(self) -> &U where Self::Target: IsA<U>; fn downcast<U: IsA<Self::Target>>(self) -> Option<&U>; fn dynamic_cast<U: ObjectType>(self) -> Option<&U>; unsafe fn unsafe_cast<U: ObjectType>(self) -> &U; } impl<T: ObjectType> ObjectCast for &T {}
- qom::Arc<T>
-
- T is a struct for a QOM object
- cloning qom::Arc calls object_ref, dropping qom::Arc calls object_unref
- possible to go (unsafely) from &T to Arc<T>
- associated functions for casting owned references similar to the above (except downcast/dynamic_cast returns Result<Arc<U>, Arc<T>>)
- consider renaming this to Owned<> or (similar to Linux) ARef<>?
Calling methods (bindings to classes implemented in C)
All methods receive &self (interior mutability). Rust implementation needs to wrap state with Cell<>, RefCell<> or Mutex<>
Two traits describe the hierarchy and provide the mapping from Rust types to C string names:
pub unsafe trait IsA<P: ObjectType>: ObjectType {} pub unsafe trait ObjectType: Sized { const TYPE: &'static CStr; fn new() -> qom::Arc<Self> { ... } }
Each class is composed of:
- one struct that provides the layout. It implements ObjectType and IsA<> for each direct or indirect parent
- methods are placed on a trait for non-final classes. The trait is automatically visible to all structs that implement IsA for that class.
Each interface only has the latter.
- Struct
- Object, Device, ...
- defines constructors
- defines methods of final classes
- trait
- ObjectMethods, DeviceMethods, UserCreatableMethods, ...
- defines methods of non-final classes and interfaces, for example ObjectMethods::typename(&self)
- automatically implemented by &T or qom::Arc<T> where T is a subclass. The idea is that you can operate as if deref coercion could also convert to superclasses.
It is implemented as follows
pub trait ObjectMethods: Deref where Self::Target: IsA<Object>, { /// Remove the object from the QOM tree fn unparent(&self) { let obj = self.upcast::<Object>(); // SAFETY: safety of this is the requirement for implementing IsA unsafe { object_unparent(obj.as_ptr_mut()); } } } impl<R: Deref> ObjectMethods for R where R::Target: IsA<Object> {}
Defining QOM classes in Rust
struct must be #[repr(C)]
One trait per class if it has virtual functions
pub trait DeviceImpl: ObjectImpl + DeviceTypeImpl { const REALIZE: Option<fn(obj: &Self) -> qom::Result<()>> = None; const UNREALIZE: Option<fn(obj: &Self)> = None; const COLD_RESET: Option<fn(obj: &Self)> = None; }
Instance-side functions (e.g. fn unrealize(&self)) implemented as private methods and exposed via the above trait; None means use superclass.
Each superclass must implement a function like
pub unsafe extern "C" fn rust_class_init<T: DeviceImpl>(klass: *mut c_void) ...
The function becomes the subclass's class_init and that daisy-chains to the superclass's rust_class_init. It sets up QOM to call these functions via unsafe wrappers:
unsafe extern "C" fn rust_cold_reset<T: DeviceImpl>(obj: *mut DeviceState) { let f = T::COLD_RESET.unwrap(); f((&*obj).unsafe_cast::<T>()) } if T::COLD_RESET.is_some() { self.cold_reset = rust_cold_reset::<T>; // self is &mut DeviceClass }
Rust implementation types contain a configuration part (implements Default + ConstDefault) and a state part (implements Default):
- instance_init is implemented automatically via Default/ConstDefault trait (using MaybeUninit to move the default values into the struct).
- Change in common code: pre_init hook that replaces memset(obj, 0, type->instance_size)? This would allow filling in the default values of the configuration fields before property initialization. This is safer, because otherwise we have to rely entirely on qdev properties to initialize the configuration fields.
- instance_finalize implemented automatically via drop_in_place
TODO
- Creating new objects requires object_property_set* wrappers
- Defining classes not part of qdev (i.e. not under DeviceState) is not considered because properties would require full-blown Visitor support. Alternative: Features/QOM-QAPI_integration