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Diffstat (limited to 'rust/qemu-api/src/qdev.rs')
-rw-r--r-- | rust/qemu-api/src/qdev.rs | 410 |
1 files changed, 410 insertions, 0 deletions
diff --git a/rust/qemu-api/src/qdev.rs b/rust/qemu-api/src/qdev.rs new file mode 100644 index 0000000..36f02fb --- /dev/null +++ b/rust/qemu-api/src/qdev.rs @@ -0,0 +1,410 @@ +// Copyright 2024, Linaro Limited +// Author(s): Manos Pitsidianakis <manos.pitsidianakis@linaro.org> +// SPDX-License-Identifier: GPL-2.0-or-later + +//! Bindings to create devices and access device functionality from Rust. + +use std::{ + ffi::{c_int, c_void, CStr, CString}, + ptr::NonNull, +}; + +pub use bindings::{ClockEvent, DeviceClass, Property, ResetType}; + +use crate::{ + bindings::{self, qdev_init_gpio_in, qdev_init_gpio_out, ResettableClass}, + callbacks::FnCall, + cell::{bql_locked, Opaque}, + chardev::Chardev, + error::{Error, Result}, + irq::InterruptSource, + prelude::*, + qom::{ObjectClass, ObjectImpl, Owned, ParentInit}, + vmstate::VMStateDescription, +}; + +/// A safe wrapper around [`bindings::Clock`]. +#[repr(transparent)] +#[derive(Debug, qemu_api_macros::Wrapper)] +pub struct Clock(Opaque<bindings::Clock>); + +unsafe impl Send for Clock {} +unsafe impl Sync for Clock {} + +/// A safe wrapper around [`bindings::DeviceState`]. +#[repr(transparent)] +#[derive(Debug, qemu_api_macros::Wrapper)] +pub struct DeviceState(Opaque<bindings::DeviceState>); + +unsafe impl Send for DeviceState {} +unsafe impl Sync for DeviceState {} + +/// Trait providing the contents of the `ResettablePhases` struct, +/// which is part of the QOM `Resettable` interface. +pub trait ResettablePhasesImpl { + /// If not None, this is called when the object enters reset. It + /// can reset local state of the object, but it must not do anything that + /// has a side-effect on other objects, such as raising or lowering an + /// [`InterruptSource`], or reading or writing guest memory. It takes the + /// reset's type as argument. + const ENTER: Option<fn(&Self, ResetType)> = None; + + /// If not None, this is called when the object for entry into reset, once + /// every object in the system which is being reset has had its + /// `ResettablePhasesImpl::ENTER` method called. At this point devices + /// can do actions that affect other objects. + /// + /// If in doubt, implement this method. + const HOLD: Option<fn(&Self, ResetType)> = None; + + /// If not None, this phase is called when the object leaves the reset + /// state. Actions affecting other objects are permitted. + const EXIT: Option<fn(&Self, ResetType)> = None; +} + +/// # 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_resettable_enter_fn<T: ResettablePhasesImpl>( + obj: *mut bindings::Object, + typ: ResetType, +) { + let state = NonNull::new(obj).unwrap().cast::<T>(); + T::ENTER.unwrap()(unsafe { state.as_ref() }, typ); +} + +/// # 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_resettable_hold_fn<T: ResettablePhasesImpl>( + obj: *mut bindings::Object, + typ: ResetType, +) { + let state = NonNull::new(obj).unwrap().cast::<T>(); + T::HOLD.unwrap()(unsafe { state.as_ref() }, typ); +} + +/// # 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_resettable_exit_fn<T: ResettablePhasesImpl>( + obj: *mut bindings::Object, + typ: ResetType, +) { + let state = NonNull::new(obj).unwrap().cast::<T>(); + T::EXIT.unwrap()(unsafe { state.as_ref() }, typ); +} + +/// Trait providing the contents of [`DeviceClass`]. +pub trait DeviceImpl: ObjectImpl + ResettablePhasesImpl + IsA<DeviceState> { + /// _Realization_ is the second stage of device creation. It contains + /// all operations that depend on device properties and can fail (note: + /// this is not yet supported for Rust devices). + /// + /// If not `None`, the parent class's `realize` method is overridden + /// with the function pointed to by `REALIZE`. + const REALIZE: Option<fn(&Self) -> Result<()>> = None; + + /// An array providing the properties that the user can set on the + /// device. Not a `const` because referencing statics in constants + /// is unstable until Rust 1.83.0. + fn properties() -> &'static [Property] { + &[] + } + + /// A `VMStateDescription` providing the migration format for the device + /// Not a `const` because referencing statics in constants is unstable + /// until Rust 1.83.0. + fn vmsd() -> Option<&'static VMStateDescription> { + None + } +} + +/// # Safety +/// +/// This function is only called through the QOM machinery and +/// used by `DeviceClass::class_init`. +/// 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_realize_fn<T: DeviceImpl>( + dev: *mut bindings::DeviceState, + errp: *mut *mut bindings::Error, +) { + let state = NonNull::new(dev).unwrap().cast::<T>(); + let result = T::REALIZE.unwrap()(unsafe { state.as_ref() }); + unsafe { + Error::ok_or_propagate(result, errp); + } +} + +unsafe impl InterfaceType for ResettableClass { + const TYPE_NAME: &'static CStr = + unsafe { CStr::from_bytes_with_nul_unchecked(bindings::TYPE_RESETTABLE_INTERFACE) }; +} + +impl ResettableClass { + /// Fill in the virtual methods of `ResettableClass` based on the + /// definitions in the `ResettablePhasesImpl` trait. + pub fn class_init<T: ResettablePhasesImpl>(&mut self) { + if <T as ResettablePhasesImpl>::ENTER.is_some() { + self.phases.enter = Some(rust_resettable_enter_fn::<T>); + } + if <T as ResettablePhasesImpl>::HOLD.is_some() { + self.phases.hold = Some(rust_resettable_hold_fn::<T>); + } + if <T as ResettablePhasesImpl>::EXIT.is_some() { + self.phases.exit = Some(rust_resettable_exit_fn::<T>); + } + } +} + +impl DeviceClass { + /// Fill in the virtual methods of `DeviceClass` based on the definitions in + /// the `DeviceImpl` trait. + pub fn class_init<T: DeviceImpl>(&mut self) { + if <T as DeviceImpl>::REALIZE.is_some() { + self.realize = Some(rust_realize_fn::<T>); + } + if let Some(vmsd) = <T as DeviceImpl>::vmsd() { + self.vmsd = vmsd; + } + let prop = <T as DeviceImpl>::properties(); + if !prop.is_empty() { + unsafe { + bindings::device_class_set_props_n(self, prop.as_ptr(), prop.len()); + } + } + + ResettableClass::cast::<DeviceState>(self).class_init::<T>(); + self.parent_class.class_init::<T>(); + } +} + +#[macro_export] +macro_rules! define_property { + ($name:expr, $state:ty, $field:ident, $prop:expr, $type:ty, bit = $bitnr:expr, default = $defval:expr$(,)*) => { + $crate::bindings::Property { + // use associated function syntax for type checking + name: ::std::ffi::CStr::as_ptr($name), + info: $prop, + offset: ::std::mem::offset_of!($state, $field) as isize, + bitnr: $bitnr, + set_default: true, + defval: $crate::bindings::Property__bindgen_ty_1 { u: $defval as u64 }, + ..$crate::zeroable::Zeroable::ZERO + } + }; + ($name:expr, $state:ty, $field:ident, $prop:expr, $type:ty, default = $defval:expr$(,)*) => { + $crate::bindings::Property { + // use associated function syntax for type checking + name: ::std::ffi::CStr::as_ptr($name), + info: $prop, + offset: ::std::mem::offset_of!($state, $field) as isize, + set_default: true, + defval: $crate::bindings::Property__bindgen_ty_1 { u: $defval as u64 }, + ..$crate::zeroable::Zeroable::ZERO + } + }; + ($name:expr, $state:ty, $field:ident, $prop:expr, $type:ty$(,)*) => { + $crate::bindings::Property { + // use associated function syntax for type checking + name: ::std::ffi::CStr::as_ptr($name), + info: $prop, + offset: ::std::mem::offset_of!($state, $field) as isize, + set_default: false, + ..$crate::zeroable::Zeroable::ZERO + } + }; +} + +#[macro_export] +macro_rules! declare_properties { + ($ident:ident, $($prop:expr),*$(,)*) => { + pub static $ident: [$crate::bindings::Property; { + let mut len = 0; + $({ + _ = stringify!($prop); + len += 1; + })* + len + }] = [ + $($prop),*, + ]; + }; +} + +unsafe impl ObjectType for DeviceState { + type Class = DeviceClass; + const TYPE_NAME: &'static CStr = + unsafe { CStr::from_bytes_with_nul_unchecked(bindings::TYPE_DEVICE) }; +} +qom_isa!(DeviceState: Object); + +/// Initialization methods take a [`ParentInit`] and can be called as +/// associated functions. +impl DeviceState { + /// Add an input clock named `name`. Invoke the callback with + /// `self` as the first parameter for the events that are requested. + /// + /// The resulting clock is added as a child of `self`, but it also + /// stays alive until after `Drop::drop` is called because C code + /// keeps an extra reference to it until `device_finalize()` calls + /// `qdev_finalize_clocklist()`. Therefore (unlike most cases in + /// which Rust code has a reference to a child object) it would be + /// possible for this function to return a `&Clock` too. + #[inline] + pub fn init_clock_in<T: DeviceImpl, F: for<'a> FnCall<(&'a T, ClockEvent)>>( + this: &mut ParentInit<T>, + name: &str, + _cb: &F, + events: ClockEvent, + ) -> Owned<Clock> + where + T::ParentType: IsA<DeviceState>, + { + fn do_init_clock_in( + dev: &DeviceState, + name: &str, + cb: Option<unsafe extern "C" fn(*mut c_void, ClockEvent)>, + events: ClockEvent, + ) -> Owned<Clock> { + assert!(bql_locked()); + + // SAFETY: the clock is heap allocated, but qdev_init_clock_in() + // does not gift the reference to its caller; so use Owned::from to + // add one. The callback is disabled automatically when the clock + // is unparented, which happens before the device is finalized. + unsafe { + let cstr = CString::new(name).unwrap(); + let clk = bindings::qdev_init_clock_in( + dev.0.as_mut_ptr(), + cstr.as_ptr(), + cb, + dev.0.as_void_ptr(), + events.0, + ); + + let clk: &Clock = Clock::from_raw(clk); + Owned::from(clk) + } + } + + let cb: Option<unsafe extern "C" fn(*mut c_void, ClockEvent)> = if F::is_some() { + unsafe extern "C" fn rust_clock_cb<T, F: for<'a> FnCall<(&'a T, ClockEvent)>>( + opaque: *mut c_void, + event: ClockEvent, + ) { + // SAFETY: the opaque is "this", which is indeed a pointer to T + F::call((unsafe { &*(opaque.cast::<T>()) }, event)) + } + Some(rust_clock_cb::<T, F>) + } else { + None + }; + + do_init_clock_in(unsafe { this.upcast_mut() }, name, cb, events) + } + + /// Add an output clock named `name`. + /// + /// The resulting clock is added as a child of `self`, but it also + /// stays alive until after `Drop::drop` is called because C code + /// keeps an extra reference to it until `device_finalize()` calls + /// `qdev_finalize_clocklist()`. Therefore (unlike most cases in + /// which Rust code has a reference to a child object) it would be + /// possible for this function to return a `&Clock` too. + #[inline] + pub fn init_clock_out<T: DeviceImpl>(this: &mut ParentInit<T>, name: &str) -> Owned<Clock> + where + T::ParentType: IsA<DeviceState>, + { + unsafe { + let cstr = CString::new(name).unwrap(); + let dev: &mut DeviceState = this.upcast_mut(); + let clk = bindings::qdev_init_clock_out(dev.0.as_mut_ptr(), cstr.as_ptr()); + + let clk: &Clock = Clock::from_raw(clk); + Owned::from(clk) + } + } +} + +/// Trait for methods exposed by the [`DeviceState`] class. The methods can be +/// called on all objects that have the trait `IsA<DeviceState>`. +/// +/// The trait should only be used through the blanket implementation, +/// which guarantees safety via `IsA`. +pub trait DeviceMethods: ObjectDeref +where + Self::Target: IsA<DeviceState>, +{ + fn prop_set_chr(&self, propname: &str, chr: &Owned<Chardev>) { + assert!(bql_locked()); + let c_propname = CString::new(propname).unwrap(); + let chr: &Chardev = chr; + unsafe { + bindings::qdev_prop_set_chr( + self.upcast().as_mut_ptr(), + c_propname.as_ptr(), + chr.as_mut_ptr(), + ); + } + } + + fn init_gpio_in<F: for<'a> FnCall<(&'a Self::Target, u32, u32)>>( + &self, + num_lines: u32, + _cb: F, + ) { + fn do_init_gpio_in( + dev: &DeviceState, + num_lines: u32, + gpio_in_cb: unsafe extern "C" fn(*mut c_void, c_int, c_int), + ) { + unsafe { + qdev_init_gpio_in(dev.as_mut_ptr(), Some(gpio_in_cb), num_lines as c_int); + } + } + + let _: () = F::ASSERT_IS_SOME; + unsafe extern "C" fn rust_irq_handler<T, F: for<'a> FnCall<(&'a T, u32, u32)>>( + opaque: *mut c_void, + line: c_int, + level: c_int, + ) { + // SAFETY: the opaque was passed as a reference to `T` + F::call((unsafe { &*(opaque.cast::<T>()) }, line as u32, level as u32)) + } + + let gpio_in_cb: unsafe extern "C" fn(*mut c_void, c_int, c_int) = + rust_irq_handler::<Self::Target, F>; + + do_init_gpio_in(self.upcast(), num_lines, gpio_in_cb); + } + + fn init_gpio_out(&self, pins: &[InterruptSource]) { + unsafe { + qdev_init_gpio_out( + self.upcast().as_mut_ptr(), + InterruptSource::slice_as_ptr(pins), + pins.len() as c_int, + ); + } + } +} + +impl<R: ObjectDeref> DeviceMethods for R where R::Target: IsA<DeviceState> {} + +unsafe impl ObjectType for Clock { + type Class = ObjectClass; + const TYPE_NAME: &'static CStr = + unsafe { CStr::from_bytes_with_nul_unchecked(bindings::TYPE_CLOCK) }; +} +qom_isa!(Clock: Object); |