// Copyright 2024, Linaro Limited
// Author(s): Manos Pitsidianakis <manos.pitsidianakis@linaro.org>
// SPDX-License-Identifier: GPL-2.0-or-later
//! Bindings to access QOM functionality from Rust.
//!
//! The QEMU Object Model (QOM) provides inheritance and dynamic typing for QEMU
//! devices. This module makes QOM's features available in Rust through three
//! main mechanisms:
//!
//! * Automatic creation and registration of `TypeInfo` for classes that are
//! written in Rust, as well as mapping between Rust traits and QOM vtables.
//!
//! * Type-safe casting between parent and child classes, through the [`IsA`]
//! trait and methods such as [`upcast`](ObjectCast::upcast) and
//! [`downcast`](ObjectCast::downcast).
//!
//! * Automatic delegation of parent class methods to child classes. When a
//! trait uses [`IsA`] as a bound, its contents become available to all child
//! classes through blanket implementations. This works both for class methods
//! and for instance methods accessed through references or smart pointers.
//!
//! # Structure of a class
//!
//! A leaf class only needs a struct holding instance state. The struct must
//! implement the [`ObjectType`] and [`IsA`] traits, as well as any `*Impl`
//! traits that exist for its superclasses.
//!
//! If a class has subclasses, it will also provide a struct for instance data,
//! with the same characteristics as for concrete classes, but it also needs
//! additional components to support virtual methods:
//!
//! * a struct for class data, for example `DeviceClass`. This corresponds to
//! the C "class struct" and holds the vtable that is used by instances of the
//! class and its subclasses. It must start with its parent's class struct.
//!
//! * a trait for virtual method implementations, for example `DeviceImpl`.
//! Child classes implement this trait to provide their own behavior for
//! virtual methods. The trait's methods take `&self` to access instance data.
//!
//! * an implementation of [`ClassInitImpl`], for example
//! `ClassInitImpl<DeviceClass>`. This fills the vtable in the class struct;
//! the source for this is the `*Impl` trait; the associated consts and
//! functions if needed are wrapped to map C types into Rust types.
//!
//! * a trait for instance methods, for example `DeviceMethods`. This trait is
//! automatically implemented for any reference or smart pointer to a device
//! instance. It calls into the vtable provides access across all subclasses
//! to methods defined for the class.
//!
//! * optionally, a trait for class methods, for example `DeviceClassMethods`.
//! This provides access to class-wide functionality that doesn't depend on
//! instance data. Like instance methods, these are automatically inherited by
//! child classes.
use std::{
ffi::CStr,
fmt,
ops::{Deref, DerefMut},
os::raw::c_void,
};
pub use bindings::{Object, ObjectClass};
use crate::bindings::{self, object_dynamic_cast, object_get_class, object_get_typename, TypeInfo};
/// Marker trait: `Self` can be statically upcasted to `P` (i.e. `P` is a direct
/// or indirect parent of `Self`).
///
/// # Safety
///
/// The struct `Self` must be `#[repr(C)]` and must begin, directly or
/// indirectly, with a field of type `P`. This ensures that invalid casts,
/// which rely on `IsA<>` for static checking, are rejected at compile time.
pub unsafe trait IsA<P: ObjectType>: ObjectType {}
// SAFETY: it is always safe to cast to your own type
unsafe impl<T: ObjectType> IsA<T> for T {}
/// Macro to mark superclasses of QOM classes. This enables type-safe
/// up- and downcasting.
///
/// # Safety
///
/// This macro is a thin wrapper around the [`IsA`] trait and performs
/// no checking whatsoever of what is declared. It is the caller's
/// responsibility to have $struct begin, directly or indirectly, with
/// a field of type `$parent`.
#[macro_export]
macro_rules! qom_isa {
($struct:ty : $($parent:ty),* ) => {
$(
// SAFETY: it is the caller responsibility to have $parent as the
// first field
unsafe impl $crate::qom::IsA<$parent> for $struct {}
impl AsRef<$parent> for $struct {
fn as_ref(&self) -> &$parent {
// SAFETY: follows the same rules as for IsA<U>, which is
// declared above.
let ptr: *const Self = self;
unsafe { &*ptr.cast::<$parent>() }
}
}
)*
};
}
/// This is the same as [`ManuallyDrop<T>`](std::mem::ManuallyDrop), though
/// it hides the standard methods of `ManuallyDrop`.
///
/// The first field of an `ObjectType` must be of type `ParentField<T>`.
/// (Technically, this is only necessary if there is at least one Rust
/// superclass in the hierarchy). This is to ensure that the parent field is
/// dropped after the subclass; this drop order is enforced by the C
/// `object_deinit` function.
///
/// # Examples
///
/// ```ignore
/// #[repr(C)]
/// #[derive(qemu_api_macros::Object)]
/// pub struct MyDevice {
/// parent: ParentField<DeviceState>,
/// ...
/// }
/// ```
#[derive(Debug)]
#[repr(transparent)]
pub struct ParentField<T: ObjectType>(std::mem::ManuallyDrop<T>);
impl<T: ObjectType> Deref for ParentField<T> {
type Target = T;
#[inline(always)]
fn deref(&self) -> &Self::Target {
&self.0
}
}
impl<T: ObjectType> DerefMut for ParentField<T> {
#[inline(always)]
fn deref_mut(&mut self) -> &mut Self::Target {
&mut self.0
}
}
impl<T: fmt::Display + ObjectType> fmt::Display for ParentField<T> {
#[inline(always)]
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> Result<(), fmt::Error> {
self.0.fmt(f)
}
}
unsafe extern "C" fn rust_instance_init<T: ObjectImpl>(obj: *mut Object) {
// SAFETY: obj is an instance of T, since rust_instance_init<T>
// is called from QOM core as the instance_init function
// for class T
unsafe { T::INSTANCE_INIT.unwrap()(&mut *obj.cast::<T>()) }
}
unsafe extern "C" fn rust_instance_post_init<T: ObjectImpl>(obj: *mut Object) {
// SAFETY: obj is an instance of T, since rust_instance_post_init<T>
// is called from QOM core as the instance_post_init function
// for class T
T::INSTANCE_POST_INIT.unwrap()(unsafe { &*obj.cast::<T>() })
}
unsafe extern "C" fn rust_class_init<T: ObjectType + ClassInitImpl<T::Class>>(
klass: *mut ObjectClass,
_data: *mut c_void,
) {
// SAFETY: klass is a T::Class, since rust_class_init<T>
// is called from QOM core as the class_init function
// for class T
T::class_init(unsafe { &mut *klass.cast::<T::Class>() })
}
unsafe extern "C" fn drop_object<T: ObjectImpl>(obj: *mut Object) {
// SAFETY: obj is an instance of T, since drop_object<T> is called
// from the QOM core function object_deinit() as the instance_finalize
// function for class T. Note that while object_deinit() will drop the
// superclass field separately after this function returns, `T` must
// implement the unsafe trait ObjectType; the safety rules for the
// trait mandate that the parent field is manually dropped.
unsafe { std::ptr::drop_in_place(obj.cast::<T>()) }
}
/// Trait exposed by all structs corresponding to QOM objects.
///
/// # Safety
///
/// For classes declared in C:
///
/// - `Class` and `TYPE` must match the data in the `TypeInfo`;
///
/// - the first field of the struct must be of the instance type corresponding
/// to the superclass, as declared in the `TypeInfo`
///
/// - likewise, the first field of the `Class` struct must be of the class type
/// corresponding to the superclass
///
/// For classes declared in Rust and implementing [`ObjectImpl`]:
///
/// - the struct must be `#[repr(C)]`;
///
/// - the first field of the struct must be of type
/// [`ParentField<T>`](ParentField), where `T` is the parent type
/// [`ObjectImpl::ParentType`]
///
/// - the first field of the `Class` must be of the class struct corresponding
/// to the superclass, which is `ObjectImpl::ParentType::Class`. `ParentField`
/// is not needed here.
///
/// In both cases, having a separate class type is not necessary if the subclass
/// does not add any field.
pub unsafe trait ObjectType: Sized {
/// The QOM class object corresponding to this struct. This is used
/// to automatically generate a `class_init` method.
type Class;
/// The name of the type, which can be passed to `object_new()` to
/// generate an instance of this type.
const TYPE_NAME: &'static CStr;
/// Return the receiver as an Object. This is always safe, even
/// if this type represents an interface.
fn as_object(&self) -> &Object {
unsafe { &*self.as_object_ptr() }
}
/// Return the receiver as a const raw pointer to Object.
/// This is preferrable to `as_object_mut_ptr()` if a C
/// function only needs a `const Object *`.
fn as_object_ptr(&self) -> *const Object {
self.as_ptr().cast()
}
/// Return the receiver as a mutable raw pointer to Object.
///
/// # Safety
///
/// This cast is always safe, but because the result is mutable
/// and the incoming reference is not, this should only be used
/// for calls to C functions, and only if needed.
unsafe fn as_object_mut_ptr(&self) -> *mut Object {
self.as_object_ptr() as *mut _
}
}
/// This trait provides safe casting operations for QOM objects to raw pointers,
/// to be used for example for FFI. The trait can be applied to any kind of
/// reference or smart pointers, and enforces correctness through the [`IsA`]
/// trait.
pub trait ObjectDeref: Deref
where
Self::Target: ObjectType,
{
/// Convert to a const Rust pointer, to be used for example for FFI.
/// The target pointer type must be the type of `self` or a superclass
fn as_ptr<U: ObjectType>(&self) -> *const U
where
Self::Target: IsA<U>,
{
let ptr: *const Self::Target = self.deref();
ptr.cast::<U>()
}
/// Convert to a mutable Rust pointer, to be used for example for FFI.
/// The target pointer type must be the type of `self` or a superclass.
/// Used to implement interior mutability for objects.
///
/// # Safety
///
/// This method is unsafe because it overrides const-ness of `&self`.
/// Bindings to C APIs will use it a lot, but otherwise it should not
/// be necessary.
unsafe fn as_mut_ptr<U: ObjectType>(&self) -> *mut U
where
Self::Target: IsA<U>,
{
#[allow(clippy::as_ptr_cast_mut)]
{
self.as_ptr::<U>() as *mut _
}
}
}
/// Trait that adds extra functionality for `&T` where `T` is a QOM
/// object type. Allows conversion to/from C objects in generic code.
pub trait ObjectCast: ObjectDeref + Copy
where
Self::Target: ObjectType,
{
/// Safely convert from a derived type to one of its parent types.
///
/// This is always safe; the [`IsA`] trait provides static verification
/// trait that `Self` dereferences to `U` or a child of `U`.
fn upcast<'a, U: ObjectType>(self) -> &'a U
where
Self::Target: IsA<U>,
Self: 'a,
{
// SAFETY: soundness is declared via IsA<U>, which is an unsafe trait
unsafe { self.unsafe_cast::<U>() }
}
/// Attempt to convert to a derived type.
///
/// Returns `None` if the object is not actually of type `U`. This is
/// verified at runtime by checking the object's type information.
fn downcast<'a, U: IsA<Self::Target>>(self) -> Option<&'a U>
where
Self: 'a,
{
self.dynamic_cast::<U>()
}
/// Attempt to convert between any two types in the QOM hierarchy.
///
/// Returns `None` if the object is not actually of type `U`. This is
/// verified at runtime by checking the object's type information.
fn dynamic_cast<'a, U: ObjectType>(self) -> Option<&'a U>
where
Self: 'a,
{
unsafe {
// SAFETY: upcasting to Object is always valid, and the
// return type is either NULL or the argument itself
let result: *const U =
object_dynamic_cast(self.as_object_mut_ptr(), U::TYPE_NAME.as_ptr()).cast();
result.as_ref()
}
}
/// Convert to any QOM type without verification.
///
/// # Safety
///
/// What safety? You need to know yourself that the cast is correct; only
/// use when performance is paramount. It is still better than a raw
/// pointer `cast()`, which does not even check that you remain in the
/// realm of QOM `ObjectType`s.
///
/// `unsafe_cast::<Object>()` is always safe.
unsafe fn unsafe_cast<'a, U: ObjectType>(self) -> &'a U
where
Self: 'a,
{
unsafe { &*(self.as_ptr::<Self::Target>().cast::<U>()) }
}
}
impl<T: ObjectType> ObjectDeref for &T {}
impl<T: ObjectType> ObjectCast for &T {}
/// Trait for mutable type casting operations in the QOM hierarchy.
///
/// This trait provides the mutable counterparts to [`ObjectCast`]'s conversion
/// functions. Unlike `ObjectCast`, this trait returns `Result` for fallible
/// conversions to preserve the original smart pointer if the cast fails. This
/// is necessary because mutable references cannot be copied, so a failed cast
/// must return ownership of the original reference. For example:
///
/// ```ignore
/// let mut dev = get_device();
/// // If this fails, we need the original `dev` back to try something else
/// match dev.dynamic_cast_mut::<FooDevice>() {
/// Ok(foodev) => /* use foodev */,
/// Err(dev) => /* still have ownership of dev */
/// }
/// ```
pub trait ObjectCastMut: Sized + ObjectDeref + DerefMut
where
Self::Target: ObjectType,
{
/// Safely convert from a derived type to one of its parent types.
///
/// This is always safe; the [`IsA`] trait provides static verification
/// that `Self` dereferences to `U` or a child of `U`.
fn upcast_mut<'a, U: ObjectType>(self) -> &'a mut U
where
Self::Target: IsA<U>,
Self: 'a,
{
// SAFETY: soundness is declared via IsA<U>, which is an unsafe trait
unsafe { self.unsafe_cast_mut::<U>() }
}
/// Attempt to convert to a derived type.
///
/// Returns `Ok(..)` if the object is of type `U`, or `Err(self)` if the
/// object if the conversion failed. This is verified at runtime by
/// checking the object's type information.
fn downcast_mut<'a, U: IsA<Self::Target>>(self) -> Result<&'a mut U, Self>
where
Self: 'a,
{
self.dynamic_cast_mut::<U>()
}
/// Attempt to convert between any two types in the QOM hierarchy.
///
/// Returns `Ok(..)` if the object is of type `U`, or `Err(self)` if the
/// object if the conversion failed. This is verified at runtime by
/// checking the object's type information.
fn dynamic_cast_mut<'a, U: ObjectType>(self) -> Result<&'a mut U, Self>
where
Self: 'a,
{
unsafe {
// SAFETY: upcasting to Object is always valid, and the
// return type is either NULL or the argument itself
let result: *mut U =
object_dynamic_cast(self.as_object_mut_ptr(), U::TYPE_NAME.as_ptr()).cast();
result.as_mut().ok_or(self)
}
}
/// Convert to any QOM type without verification.
///
/// # Safety
///
/// What safety? You need to know yourself that the cast is correct; only
/// use when performance is paramount. It is still better than a raw
/// pointer `cast()`, which does not even check that you remain in the
/// realm of QOM `ObjectType`s.
///
/// `unsafe_cast::<Object>()` is always safe.
unsafe fn unsafe_cast_mut<'a, U: ObjectType>(self) -> &'a mut U
where
Self: 'a,
{
unsafe { &mut *self.as_mut_ptr::<Self::Target>().cast::<U>() }
}
}
impl<T: ObjectType> ObjectDeref for &mut T {}
impl<T: ObjectType> ObjectCastMut for &mut T {}
/// Trait a type must implement to be registered with QEMU.
pub trait ObjectImpl: ObjectType + ClassInitImpl<Self::Class> {
/// The parent of the type. This should match the first field of the
/// struct that implements `ObjectImpl`, minus the `ParentField<_>` wrapper.
type ParentType: ObjectType;
/// Whether the object can be instantiated
const ABSTRACT: bool = false;
/// Function that is called to initialize an object. The parent class will
/// have already been initialized so the type is only responsible for
/// initializing its own members.
///
/// FIXME: The argument is not really a valid reference. `&mut
/// MaybeUninit<Self>` would be a better description.
const INSTANCE_INIT: Option<unsafe fn(&mut Self)> = None;
/// Function that is called to finish initialization of an object, once
/// `INSTANCE_INIT` functions have been called.
const INSTANCE_POST_INIT: Option<fn(&Self)> = None;
/// Called on descendent classes after all parent class initialization
/// has occurred, but before the class itself is initialized. This
/// is only useful if a class is not a leaf, and can be used to undo
/// the effects of copying the contents of the parent's class struct
/// to the descendants.
const CLASS_BASE_INIT: Option<
unsafe extern "C" fn(klass: *mut ObjectClass, data: *mut c_void),
> = None;
const TYPE_INFO: TypeInfo = TypeInfo {
name: Self::TYPE_NAME.as_ptr(),
parent: Self::ParentType::TYPE_NAME.as_ptr(),
instance_size: core::mem::size_of::<Self>(),
instance_align: core::mem::align_of::<Self>(),
instance_init: match Self::INSTANCE_INIT {
None => None,
Some(_) => Some(rust_instance_init::<Self>),
},
instance_post_init: match Self::INSTANCE_POST_INIT {
None => None,
Some(_) => Some(rust_instance_post_init::<Self>),
},
instance_finalize: Some(drop_object::<Self>),
abstract_: Self::ABSTRACT,
class_size: core::mem::size_of::<Self::Class>(),
class_init: Some(rust_class_init::<Self>),
class_base_init: Self::CLASS_BASE_INIT,
class_data: core::ptr::null_mut(),
interfaces: core::ptr::null_mut(),
};
// methods on ObjectClass
const UNPARENT: Option<fn(&Self)> = None;
}
/// Internal trait used to automatically fill in a class struct.
///
/// Each QOM class that has virtual methods describes them in a
/// _class struct_. Class structs include a parent field corresponding
/// to the vtable of the parent class, all the way up to [`ObjectClass`].
/// Each QOM type has one such class struct; this trait takes care of
/// initializing the `T` part of the class struct, for the type that
/// implements the trait.
///
/// Each struct will implement this trait with `T` equal to each
/// superclass. For example, a device should implement at least
/// `ClassInitImpl<`[`DeviceClass`](crate::qdev::DeviceClass)`>` and
/// `ClassInitImpl<`[`ObjectClass`]`>`. Such implementations are made
/// in one of two ways.
///
/// For most superclasses, `ClassInitImpl` is provided by the `qemu-api`
/// crate itself. The Rust implementation of methods will come from a
/// trait like [`ObjectImpl`] or [`DeviceImpl`](crate::qdev::DeviceImpl),
/// and `ClassInitImpl` is provided by blanket implementations that
/// operate on all implementors of the `*Impl`* trait. For example:
///
/// ```ignore
/// impl<T> ClassInitImpl<DeviceClass> for T
/// where
/// T: ClassInitImpl<ObjectClass> + DeviceImpl,
/// ```
///
/// The bound on `ClassInitImpl<ObjectClass>` is needed so that,
/// after initializing the `DeviceClass` part of the class struct,
/// the parent [`ObjectClass`] is initialized as well.
///
/// The other case is when manual implementation of the trait is needed.
/// This covers the following cases:
///
/// * if a class implements a QOM interface, the Rust code _has_ to define its
/// own class struct `FooClass` and implement `ClassInitImpl<FooClass>`.
/// `ClassInitImpl<FooClass>`'s `class_init` method will then forward to
/// multiple other `class_init`s, for the interfaces as well as the
/// superclass. (Note that there is no Rust example yet for using interfaces).
///
/// * for classes implemented outside the ``qemu-api`` crate, it's not possible
/// to add blanket implementations like the above one, due to orphan rules. In
/// that case, the easiest solution is to implement
/// `ClassInitImpl<YourSuperclass>` for each subclass and not have a
/// `YourSuperclassImpl` trait at all.
///
/// ```ignore
/// impl ClassInitImpl<YourSuperclass> for YourSubclass {
/// fn class_init(klass: &mut YourSuperclass) {
/// klass.some_method = Some(Self::some_method);
/// <Self as ClassInitImpl<SysBusDeviceClass>>::class_init(&mut klass.parent_class);
/// }
/// }
/// ```
///
/// While this method incurs a small amount of code duplication,
/// it is generally limited to the recursive call on the last line.
/// This is because classes defined in Rust do not need the same
/// glue code that is needed when the classes are defined in C code.
/// You may consider using a macro if you have many subclasses.
pub trait ClassInitImpl<T> {
/// Initialize `klass` to point to the virtual method implementations
/// for `Self`. On entry, the virtual method pointers are set to
/// the default values coming from the parent classes; the function
/// can change them to override virtual methods of a parent class.
///
/// The virtual method implementations usually come from another
/// trait, for example [`DeviceImpl`](crate::qdev::DeviceImpl)
/// when `T` is [`DeviceClass`](crate::qdev::DeviceClass).
///
/// On entry, `klass`'s parent class is initialized, while the other fields
/// are all zero; it is therefore assumed that all fields in `T` can be
/// zeroed, otherwise it would not be possible to provide the class as a
/// `&mut T`. TODO: add a bound of [`Zeroable`](crate::zeroable::Zeroable)
/// to T; this is more easily done once Zeroable does not require a manual
/// implementation (Rust 1.75.0).
fn class_init(klass: &mut T);
}
/// # Safety
///
/// We expect the FFI user of this function to pass a valid pointer that
/// can be downcasted to type `T`. We also expect the device is
/// readable/writeable from one thread at any time.
unsafe extern "C" fn rust_unparent_fn<T: ObjectImpl>(dev: *mut Object) {
unsafe {
assert!(!dev.is_null());
let state = core::ptr::NonNull::new_unchecked(dev.cast::<T>());
T::UNPARENT.unwrap()(state.as_ref());
}
}
impl<T> ClassInitImpl<ObjectClass> for T
where
T: ObjectImpl,
{
fn class_init(oc: &mut ObjectClass) {
if <T as ObjectImpl>::UNPARENT.is_some() {
oc.unparent = Some(rust_unparent_fn::<T>);
}
}
}
unsafe impl ObjectType for Object {
type Class = ObjectClass;
const TYPE_NAME: &'static CStr =
unsafe { CStr::from_bytes_with_nul_unchecked(bindings::TYPE_OBJECT) };
}
/// Trait for methods exposed by the Object class. The methods can be
/// called on all objects that have the trait `IsA<Object>`.
///
/// The trait should only be used through the blanket implementation,
/// which guarantees safety via `IsA`
pub trait ObjectMethods: ObjectDeref
where
Self::Target: IsA<Object>,
{
/// Return the name of the type of `self`
fn typename(&self) -> std::borrow::Cow<'_, str> {
let obj = self.upcast::<Object>();
// SAFETY: safety of this is the requirement for implementing IsA
// The result of the C API has static lifetime
unsafe {
let p = object_get_typename(obj.as_mut_ptr());
CStr::from_ptr(p).to_string_lossy()
}
}
fn get_class(&self) -> &'static <Self::Target as ObjectType>::Class {
let obj = self.upcast::<Object>();
// SAFETY: all objects can call object_get_class; the actual class
// type is guaranteed by the implementation of `ObjectType` and
// `ObjectImpl`.
let klass: &'static <Self::Target as ObjectType>::Class =
unsafe { &*object_get_class(obj.as_mut_ptr()).cast() };
klass
}
}
impl<R: ObjectDeref> ObjectMethods for R where R::Target: IsA<Object> {}