18e194c0eSPaolo Bonzini // SPDX-License-Identifier: MIT 28e194c0eSPaolo Bonzini // 38e194c0eSPaolo Bonzini // This file is based on library/core/src/cell.rs from 48e194c0eSPaolo Bonzini // Rust 1.82.0. 58e194c0eSPaolo Bonzini // 68e194c0eSPaolo Bonzini // Permission is hereby granted, free of charge, to any 78e194c0eSPaolo Bonzini // person obtaining a copy of this software and associated 88e194c0eSPaolo Bonzini // documentation files (the "Software"), to deal in the 98e194c0eSPaolo Bonzini // Software without restriction, including without 108e194c0eSPaolo Bonzini // limitation the rights to use, copy, modify, merge, 118e194c0eSPaolo Bonzini // publish, distribute, sublicense, and/or sell copies of 128e194c0eSPaolo Bonzini // the Software, and to permit persons to whom the Software 138e194c0eSPaolo Bonzini // is furnished to do so, subject to the following 148e194c0eSPaolo Bonzini // conditions: 158e194c0eSPaolo Bonzini // 168e194c0eSPaolo Bonzini // The above copyright notice and this permission notice 178e194c0eSPaolo Bonzini // shall be included in all copies or substantial portions 188e194c0eSPaolo Bonzini // of the Software. 198e194c0eSPaolo Bonzini // 208e194c0eSPaolo Bonzini // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF 218e194c0eSPaolo Bonzini // ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED 228e194c0eSPaolo Bonzini // TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A 238e194c0eSPaolo Bonzini // PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT 248e194c0eSPaolo Bonzini // SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY 258e194c0eSPaolo Bonzini // CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION 268e194c0eSPaolo Bonzini // OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR 278e194c0eSPaolo Bonzini // IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER 288e194c0eSPaolo Bonzini // DEALINGS IN THE SOFTWARE. 298e194c0eSPaolo Bonzini 300b9d05e3SPaolo Bonzini //! QEMU-specific mutable containers 318e194c0eSPaolo Bonzini //! 328e194c0eSPaolo Bonzini //! Rust memory safety is based on this rule: Given an object `T`, it is only 338e194c0eSPaolo Bonzini //! possible to have one of the following: 348e194c0eSPaolo Bonzini //! 358e194c0eSPaolo Bonzini //! - Having several immutable references (`&T`) to the object (also known as 368e194c0eSPaolo Bonzini //! **aliasing**). 378e194c0eSPaolo Bonzini //! - Having one mutable reference (`&mut T`) to the object (also known as 388e194c0eSPaolo Bonzini //! **mutability**). 398e194c0eSPaolo Bonzini //! 408e194c0eSPaolo Bonzini //! This is enforced by the Rust compiler. However, there are situations where 418e194c0eSPaolo Bonzini //! this rule is not flexible enough. Sometimes it is required to have multiple 428e194c0eSPaolo Bonzini //! references to an object and yet mutate it. In particular, QEMU objects 438e194c0eSPaolo Bonzini //! usually have their pointer shared with the "outside world very early in 448e194c0eSPaolo Bonzini //! their lifetime", for example when they create their 458e194c0eSPaolo Bonzini //! [`MemoryRegion`s](crate::bindings::MemoryRegion). Therefore, individual 460b9d05e3SPaolo Bonzini //! parts of a device must be made mutable in a controlled manner; this module 470b9d05e3SPaolo Bonzini //! provides the tools to do so. 480b9d05e3SPaolo Bonzini //! 490b9d05e3SPaolo Bonzini //! ## Cell types 508e194c0eSPaolo Bonzini //! 51c596199fSPaolo Bonzini //! [`BqlCell<T>`] and [`BqlRefCell<T>`] allow doing this via the Big QEMU Lock. 52c596199fSPaolo Bonzini //! While they are essentially the same single-threaded primitives that are 53c596199fSPaolo Bonzini //! available in `std::cell`, the BQL allows them to be used from a 54c596199fSPaolo Bonzini //! multi-threaded context and to share references across threads, while 55c596199fSPaolo Bonzini //! maintaining Rust's safety guarantees. For this reason, unlike 56c596199fSPaolo Bonzini //! their `std::cell` counterparts, `BqlCell` and `BqlRefCell` implement the 57c596199fSPaolo Bonzini //! `Sync` trait. 588e194c0eSPaolo Bonzini //! 598e194c0eSPaolo Bonzini //! BQL checks are performed in debug builds but can be optimized away in 608e194c0eSPaolo Bonzini //! release builds, providing runtime safety during development with no overhead 618e194c0eSPaolo Bonzini //! in production. 628e194c0eSPaolo Bonzini //! 63c596199fSPaolo Bonzini //! The two provide different ways of handling interior mutability. 64c596199fSPaolo Bonzini //! `BqlRefCell` is best suited for data that is primarily accessed by the 65c596199fSPaolo Bonzini //! device's own methods, where multiple reads and writes can be grouped within 66c596199fSPaolo Bonzini //! a single borrow and a mutable reference can be passed around. Instead, 67c596199fSPaolo Bonzini //! [`BqlCell`] is a better choice when sharing small pieces of data with 68c596199fSPaolo Bonzini //! external code (especially C code), because it provides simple get/set 69c596199fSPaolo Bonzini //! operations that can be used one at a time. 70c596199fSPaolo Bonzini //! 71c596199fSPaolo Bonzini //! Warning: While `BqlCell` and `BqlRefCell` are similar to their `std::cell` 72c596199fSPaolo Bonzini //! counterparts, they are not interchangeable. Using `std::cell` types in 73c596199fSPaolo Bonzini //! QEMU device implementations is usually incorrect and can lead to 74c596199fSPaolo Bonzini //! thread-safety issues. 758e194c0eSPaolo Bonzini //! 765778ce99SPaolo Bonzini //! ### Example 775778ce99SPaolo Bonzini //! 785778ce99SPaolo Bonzini //! ``` 795778ce99SPaolo Bonzini //! # use qemu_api::prelude::*; 80f117857bSPaolo Bonzini //! # use qemu_api::{cell::BqlRefCell, irq::InterruptSource, irq::IRQState}; 815778ce99SPaolo Bonzini //! # use qemu_api::{sysbus::SysBusDevice, qom::Owned, qom::ParentField}; 825778ce99SPaolo Bonzini //! # const N_GPIOS: usize = 8; 835778ce99SPaolo Bonzini //! # struct PL061Registers { /* ... */ } 845778ce99SPaolo Bonzini //! # unsafe impl ObjectType for PL061State { 855778ce99SPaolo Bonzini //! # type Class = <SysBusDevice as ObjectType>::Class; 86f117857bSPaolo Bonzini //! # const TYPE_NAME: &'static std::ffi::CStr = c"pl061"; 875778ce99SPaolo Bonzini //! # } 885778ce99SPaolo Bonzini //! struct PL061State { 895778ce99SPaolo Bonzini //! parent_obj: ParentField<SysBusDevice>, 905778ce99SPaolo Bonzini //! 915778ce99SPaolo Bonzini //! // Configuration is read-only after initialization 925778ce99SPaolo Bonzini //! pullups: u32, 935778ce99SPaolo Bonzini //! pulldowns: u32, 945778ce99SPaolo Bonzini //! 955778ce99SPaolo Bonzini //! // Single values shared with C code use BqlCell, in this case via InterruptSource 965778ce99SPaolo Bonzini //! out: [InterruptSource; N_GPIOS], 975778ce99SPaolo Bonzini //! interrupt: InterruptSource, 985778ce99SPaolo Bonzini //! 995778ce99SPaolo Bonzini //! // Larger state accessed by device methods uses BqlRefCell or Mutex 1005778ce99SPaolo Bonzini //! registers: BqlRefCell<PL061Registers>, 1015778ce99SPaolo Bonzini //! } 1025778ce99SPaolo Bonzini //! ``` 1035778ce99SPaolo Bonzini //! 1040b9d05e3SPaolo Bonzini //! ### `BqlCell<T>` 1058e194c0eSPaolo Bonzini //! 1068e194c0eSPaolo Bonzini //! [`BqlCell<T>`] implements interior mutability by moving values in and out of 1078e194c0eSPaolo Bonzini //! the cell. That is, an `&mut T` to the inner value can never be obtained as 1088e194c0eSPaolo Bonzini //! long as the cell is shared. The value itself cannot be directly obtained 1098e194c0eSPaolo Bonzini //! without copying it, cloning it, or replacing it with something else. This 1108e194c0eSPaolo Bonzini //! type provides the following methods, all of which can be called only while 1118e194c0eSPaolo Bonzini //! the BQL is held: 1128e194c0eSPaolo Bonzini //! 1138e194c0eSPaolo Bonzini //! - For types that implement [`Copy`], the [`get`](BqlCell::get) method 1148e194c0eSPaolo Bonzini //! retrieves the current interior value by duplicating it. 1158e194c0eSPaolo Bonzini //! - For types that implement [`Default`], the [`take`](BqlCell::take) method 1168e194c0eSPaolo Bonzini //! replaces the current interior value with [`Default::default()`] and 1178e194c0eSPaolo Bonzini //! returns the replaced value. 1188e194c0eSPaolo Bonzini //! - All types have: 1198e194c0eSPaolo Bonzini //! - [`replace`](BqlCell::replace): replaces the current interior value and 1208e194c0eSPaolo Bonzini //! returns the replaced value. 1218e194c0eSPaolo Bonzini //! - [`set`](BqlCell::set): this method replaces the interior value, 1228e194c0eSPaolo Bonzini //! dropping the replaced value. 123c596199fSPaolo Bonzini //! 1240b9d05e3SPaolo Bonzini //! ### `BqlRefCell<T>` 125c596199fSPaolo Bonzini //! 126c596199fSPaolo Bonzini //! [`BqlRefCell<T>`] uses Rust's lifetimes to implement "dynamic borrowing", a 127c596199fSPaolo Bonzini //! process whereby one can claim temporary, exclusive, mutable access to the 128c596199fSPaolo Bonzini //! inner value: 129c596199fSPaolo Bonzini //! 130c596199fSPaolo Bonzini //! ```ignore 131c596199fSPaolo Bonzini //! fn clear_interrupts(&self, val: u32) { 132c596199fSPaolo Bonzini //! // A mutable borrow gives read-write access to the registers 133c596199fSPaolo Bonzini //! let mut regs = self.registers.borrow_mut(); 134c596199fSPaolo Bonzini //! let old = regs.interrupt_status(); 135c596199fSPaolo Bonzini //! regs.update_interrupt_status(old & !val); 136c596199fSPaolo Bonzini //! } 137c596199fSPaolo Bonzini //! ``` 138c596199fSPaolo Bonzini //! 139c596199fSPaolo Bonzini //! Borrows for `BqlRefCell<T>`s are tracked at _runtime_, unlike Rust's native 140c596199fSPaolo Bonzini //! reference types which are entirely tracked statically, at compile time. 141c596199fSPaolo Bonzini //! Multiple immutable borrows are allowed via [`borrow`](BqlRefCell::borrow), 142c596199fSPaolo Bonzini //! or a single mutable borrow via [`borrow_mut`](BqlRefCell::borrow_mut). The 143c596199fSPaolo Bonzini //! thread will panic if these rules are violated or if the BQL is not held. 1440b9d05e3SPaolo Bonzini //! 1450b9d05e3SPaolo Bonzini //! ## Opaque wrappers 1460b9d05e3SPaolo Bonzini //! 1470b9d05e3SPaolo Bonzini //! The cell types from the previous section are useful at the boundaries 1480b9d05e3SPaolo Bonzini //! of code that requires interior mutability. When writing glue code that 1490b9d05e3SPaolo Bonzini //! interacts directly with C structs, however, it is useful to operate 1500b9d05e3SPaolo Bonzini //! at a lower level. 1510b9d05e3SPaolo Bonzini //! 1520b9d05e3SPaolo Bonzini //! C functions often violate Rust's fundamental assumptions about memory 1530b9d05e3SPaolo Bonzini //! safety by modifying memory even if it is shared. Furthermore, C structs 1540b9d05e3SPaolo Bonzini //! often start their life uninitialized and may be populated lazily. 1550b9d05e3SPaolo Bonzini //! 1560b9d05e3SPaolo Bonzini //! For this reason, this module provides the [`Opaque<T>`] type to opt out 1570b9d05e3SPaolo Bonzini //! of Rust's usual guarantees about the wrapped type. Access to the wrapped 1580b9d05e3SPaolo Bonzini //! value is always through raw pointers, obtained via methods like 1590b9d05e3SPaolo Bonzini //! [`as_mut_ptr()`](Opaque::as_mut_ptr) and [`as_ptr()`](Opaque::as_ptr). These 1600b9d05e3SPaolo Bonzini //! pointers can then be passed to C functions or dereferenced; both actions 1610b9d05e3SPaolo Bonzini //! require `unsafe` blocks, making it clear where safety guarantees must be 1620b9d05e3SPaolo Bonzini //! manually verified. For example 1630b9d05e3SPaolo Bonzini //! 1640b9d05e3SPaolo Bonzini //! ```ignore 1650b9d05e3SPaolo Bonzini //! unsafe { 1660b9d05e3SPaolo Bonzini //! let state = Opaque::<MyStruct>::uninit(); 1670b9d05e3SPaolo Bonzini //! qemu_struct_init(state.as_mut_ptr()); 1680b9d05e3SPaolo Bonzini //! } 1690b9d05e3SPaolo Bonzini //! ``` 1700b9d05e3SPaolo Bonzini //! 1710b9d05e3SPaolo Bonzini //! [`Opaque<T>`] will usually be wrapped one level further, so that 1720b9d05e3SPaolo Bonzini //! bridge methods can be added to the wrapper: 1730b9d05e3SPaolo Bonzini //! 1740b9d05e3SPaolo Bonzini //! ```ignore 1750b9d05e3SPaolo Bonzini //! pub struct MyStruct(Opaque<bindings::MyStruct>); 1760b9d05e3SPaolo Bonzini //! 1770b9d05e3SPaolo Bonzini //! impl MyStruct { 1780b9d05e3SPaolo Bonzini //! fn new() -> Pin<Box<MyStruct>> { 1790b9d05e3SPaolo Bonzini //! let result = Box::pin(unsafe { Opaque::uninit() }); 1800b9d05e3SPaolo Bonzini //! unsafe { qemu_struct_init(result.as_mut_ptr()) }; 1810b9d05e3SPaolo Bonzini //! result 1820b9d05e3SPaolo Bonzini //! } 1830b9d05e3SPaolo Bonzini //! } 1840b9d05e3SPaolo Bonzini //! ``` 1850b9d05e3SPaolo Bonzini //! 1860b9d05e3SPaolo Bonzini //! This pattern of wrapping bindgen-generated types in [`Opaque<T>`] provides 1870b9d05e3SPaolo Bonzini //! several advantages: 1880b9d05e3SPaolo Bonzini //! 1890b9d05e3SPaolo Bonzini //! * The choice of traits to be implemented is not limited by the 1900b9d05e3SPaolo Bonzini //! bindgen-generated code. For example, [`Drop`] can be added without 1910b9d05e3SPaolo Bonzini //! disabling [`Copy`] on the underlying bindgen type 1920b9d05e3SPaolo Bonzini //! 1930b9d05e3SPaolo Bonzini //! * [`Send`] and [`Sync`] implementations can be controlled by the wrapper 1940b9d05e3SPaolo Bonzini //! type rather than being automatically derived from the C struct's layout 1950b9d05e3SPaolo Bonzini //! 1960b9d05e3SPaolo Bonzini //! * Methods can be implemented in a separate crate from the bindgen-generated 1970b9d05e3SPaolo Bonzini //! bindings 1980b9d05e3SPaolo Bonzini //! 1990b9d05e3SPaolo Bonzini //! * [`Debug`](std::fmt::Debug) and [`Display`](std::fmt::Display) 2000b9d05e3SPaolo Bonzini //! implementations can be customized to be more readable than the raw C 2010b9d05e3SPaolo Bonzini //! struct representation 2020b9d05e3SPaolo Bonzini //! 2030b9d05e3SPaolo Bonzini //! The [`Opaque<T>`] type does not include BQL validation; it is possible to 2040b9d05e3SPaolo Bonzini //! assert in the code that the right lock is taken, to use it together 2050b9d05e3SPaolo Bonzini //! with a custom lock guard type, or to let C code take the lock, as 2060b9d05e3SPaolo Bonzini //! appropriate. It is also possible to use it with non-thread-safe 2070b9d05e3SPaolo Bonzini //! types, since by default (unlike [`BqlCell`] and [`BqlRefCell`] 2080b9d05e3SPaolo Bonzini //! it is neither `Sync` nor `Send`. 2090b9d05e3SPaolo Bonzini //! 2100b9d05e3SPaolo Bonzini //! While [`Opaque<T>`] is necessary for C interop, it should be used sparingly 2110b9d05e3SPaolo Bonzini //! and only at FFI boundaries. For QEMU-specific types that need interior 2120b9d05e3SPaolo Bonzini //! mutability, prefer [`BqlCell`] or [`BqlRefCell`]. 2138e194c0eSPaolo Bonzini 214c596199fSPaolo Bonzini use std::{ 215c596199fSPaolo Bonzini cell::{Cell, UnsafeCell}, 216c596199fSPaolo Bonzini cmp::Ordering, 217c596199fSPaolo Bonzini fmt, 2180b9d05e3SPaolo Bonzini marker::{PhantomData, PhantomPinned}, 2190b9d05e3SPaolo Bonzini mem::{self, MaybeUninit}, 220c596199fSPaolo Bonzini ops::{Deref, DerefMut}, 221c596199fSPaolo Bonzini ptr::NonNull, 222c596199fSPaolo Bonzini }; 2238e194c0eSPaolo Bonzini 2248e194c0eSPaolo Bonzini use crate::bindings; 2258e194c0eSPaolo Bonzini 226d4873c5dSPaolo Bonzini /// An internal function that is used by doctests. 227d4873c5dSPaolo Bonzini pub fn bql_start_test() { 228d4873c5dSPaolo Bonzini // SAFETY: integration tests are run with --test-threads=1, while 229d4873c5dSPaolo Bonzini // unit tests and doctests are not multithreaded and do not have 230d4873c5dSPaolo Bonzini // any BQL-protected data. Just set bql_locked to true. 231d4873c5dSPaolo Bonzini unsafe { 232d4873c5dSPaolo Bonzini bindings::rust_bql_mock_lock(); 233d4873c5dSPaolo Bonzini } 234d4873c5dSPaolo Bonzini } 235d4873c5dSPaolo Bonzini 2368e194c0eSPaolo Bonzini pub fn bql_locked() -> bool { 2378e194c0eSPaolo Bonzini // SAFETY: the function does nothing but return a thread-local bool 238*18c9f4a1SPaolo Bonzini unsafe { bindings::bql_locked() } 2398e194c0eSPaolo Bonzini } 2408e194c0eSPaolo Bonzini 241c596199fSPaolo Bonzini fn bql_block_unlock(increase: bool) { 242c596199fSPaolo Bonzini // SAFETY: this only adjusts a counter 243c596199fSPaolo Bonzini unsafe { 244c596199fSPaolo Bonzini bindings::bql_block_unlock(increase); 245c596199fSPaolo Bonzini } 246c596199fSPaolo Bonzini } 247c596199fSPaolo Bonzini 2488e194c0eSPaolo Bonzini /// A mutable memory location that is protected by the Big QEMU Lock. 2498e194c0eSPaolo Bonzini /// 2508e194c0eSPaolo Bonzini /// # Memory layout 2518e194c0eSPaolo Bonzini /// 2528e194c0eSPaolo Bonzini /// `BqlCell<T>` has the same in-memory representation as its inner type `T`. 2538e194c0eSPaolo Bonzini #[repr(transparent)] 2548e194c0eSPaolo Bonzini pub struct BqlCell<T> { 2558e194c0eSPaolo Bonzini value: UnsafeCell<T>, 2568e194c0eSPaolo Bonzini } 2578e194c0eSPaolo Bonzini 2588e194c0eSPaolo Bonzini // SAFETY: Same as for std::sync::Mutex. In the end this *is* a Mutex, 2598e194c0eSPaolo Bonzini // except it is stored out-of-line 2608e194c0eSPaolo Bonzini unsafe impl<T: Send> Send for BqlCell<T> {} 2618e194c0eSPaolo Bonzini unsafe impl<T: Send> Sync for BqlCell<T> {} 2628e194c0eSPaolo Bonzini 2638e194c0eSPaolo Bonzini impl<T: Copy> Clone for BqlCell<T> { 2648e194c0eSPaolo Bonzini #[inline] 2658e194c0eSPaolo Bonzini fn clone(&self) -> BqlCell<T> { 2668e194c0eSPaolo Bonzini BqlCell::new(self.get()) 2678e194c0eSPaolo Bonzini } 2688e194c0eSPaolo Bonzini } 2698e194c0eSPaolo Bonzini 2708e194c0eSPaolo Bonzini impl<T: Default> Default for BqlCell<T> { 2718e194c0eSPaolo Bonzini /// Creates a `BqlCell<T>`, with the `Default` value for T. 2728e194c0eSPaolo Bonzini #[inline] 2738e194c0eSPaolo Bonzini fn default() -> BqlCell<T> { 2748e194c0eSPaolo Bonzini BqlCell::new(Default::default()) 2758e194c0eSPaolo Bonzini } 2768e194c0eSPaolo Bonzini } 2778e194c0eSPaolo Bonzini 2788e194c0eSPaolo Bonzini impl<T: PartialEq + Copy> PartialEq for BqlCell<T> { 2798e194c0eSPaolo Bonzini #[inline] 2808e194c0eSPaolo Bonzini fn eq(&self, other: &BqlCell<T>) -> bool { 2818e194c0eSPaolo Bonzini self.get() == other.get() 2828e194c0eSPaolo Bonzini } 2838e194c0eSPaolo Bonzini } 2848e194c0eSPaolo Bonzini 2858e194c0eSPaolo Bonzini impl<T: Eq + Copy> Eq for BqlCell<T> {} 2868e194c0eSPaolo Bonzini 2878e194c0eSPaolo Bonzini impl<T: PartialOrd + Copy> PartialOrd for BqlCell<T> { 2888e194c0eSPaolo Bonzini #[inline] 2898e194c0eSPaolo Bonzini fn partial_cmp(&self, other: &BqlCell<T>) -> Option<Ordering> { 2908e194c0eSPaolo Bonzini self.get().partial_cmp(&other.get()) 2918e194c0eSPaolo Bonzini } 2928e194c0eSPaolo Bonzini } 2938e194c0eSPaolo Bonzini 2948e194c0eSPaolo Bonzini impl<T: Ord + Copy> Ord for BqlCell<T> { 2958e194c0eSPaolo Bonzini #[inline] 2968e194c0eSPaolo Bonzini fn cmp(&self, other: &BqlCell<T>) -> Ordering { 2978e194c0eSPaolo Bonzini self.get().cmp(&other.get()) 2988e194c0eSPaolo Bonzini } 2998e194c0eSPaolo Bonzini } 3008e194c0eSPaolo Bonzini 3018e194c0eSPaolo Bonzini impl<T> From<T> for BqlCell<T> { 3028e194c0eSPaolo Bonzini /// Creates a new `BqlCell<T>` containing the given value. 3038e194c0eSPaolo Bonzini fn from(t: T) -> BqlCell<T> { 3048e194c0eSPaolo Bonzini BqlCell::new(t) 3058e194c0eSPaolo Bonzini } 3068e194c0eSPaolo Bonzini } 3078e194c0eSPaolo Bonzini 3088e194c0eSPaolo Bonzini impl<T: fmt::Debug + Copy> fmt::Debug for BqlCell<T> { 3098e194c0eSPaolo Bonzini fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { 3108e194c0eSPaolo Bonzini self.get().fmt(f) 3118e194c0eSPaolo Bonzini } 3128e194c0eSPaolo Bonzini } 3138e194c0eSPaolo Bonzini 3148e194c0eSPaolo Bonzini impl<T: fmt::Display + Copy> fmt::Display for BqlCell<T> { 3158e194c0eSPaolo Bonzini fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { 3168e194c0eSPaolo Bonzini self.get().fmt(f) 3178e194c0eSPaolo Bonzini } 3188e194c0eSPaolo Bonzini } 3198e194c0eSPaolo Bonzini 3208e194c0eSPaolo Bonzini impl<T> BqlCell<T> { 3218e194c0eSPaolo Bonzini /// Creates a new `BqlCell` containing the given value. 3228e194c0eSPaolo Bonzini /// 3238e194c0eSPaolo Bonzini /// # Examples 3248e194c0eSPaolo Bonzini /// 3258e194c0eSPaolo Bonzini /// ``` 3268e194c0eSPaolo Bonzini /// use qemu_api::cell::BqlCell; 327d4873c5dSPaolo Bonzini /// # qemu_api::cell::bql_start_test(); 3288e194c0eSPaolo Bonzini /// 3298e194c0eSPaolo Bonzini /// let c = BqlCell::new(5); 3308e194c0eSPaolo Bonzini /// ``` 3318e194c0eSPaolo Bonzini #[inline] 3328e194c0eSPaolo Bonzini pub const fn new(value: T) -> BqlCell<T> { 3338e194c0eSPaolo Bonzini BqlCell { 3348e194c0eSPaolo Bonzini value: UnsafeCell::new(value), 3358e194c0eSPaolo Bonzini } 3368e194c0eSPaolo Bonzini } 3378e194c0eSPaolo Bonzini 3388e194c0eSPaolo Bonzini /// Sets the contained value. 3398e194c0eSPaolo Bonzini /// 3408e194c0eSPaolo Bonzini /// # Examples 3418e194c0eSPaolo Bonzini /// 3428e194c0eSPaolo Bonzini /// ``` 3438e194c0eSPaolo Bonzini /// use qemu_api::cell::BqlCell; 344d4873c5dSPaolo Bonzini /// # qemu_api::cell::bql_start_test(); 3458e194c0eSPaolo Bonzini /// 3468e194c0eSPaolo Bonzini /// let c = BqlCell::new(5); 3478e194c0eSPaolo Bonzini /// 3488e194c0eSPaolo Bonzini /// c.set(10); 3498e194c0eSPaolo Bonzini /// ``` 3508e194c0eSPaolo Bonzini #[inline] 3518e194c0eSPaolo Bonzini pub fn set(&self, val: T) { 3528e194c0eSPaolo Bonzini self.replace(val); 3538e194c0eSPaolo Bonzini } 3548e194c0eSPaolo Bonzini 3558e194c0eSPaolo Bonzini /// Replaces the contained value with `val`, and returns the old contained 3568e194c0eSPaolo Bonzini /// value. 3578e194c0eSPaolo Bonzini /// 3588e194c0eSPaolo Bonzini /// # Examples 3598e194c0eSPaolo Bonzini /// 3608e194c0eSPaolo Bonzini /// ``` 3618e194c0eSPaolo Bonzini /// use qemu_api::cell::BqlCell; 362d4873c5dSPaolo Bonzini /// # qemu_api::cell::bql_start_test(); 3638e194c0eSPaolo Bonzini /// 3648e194c0eSPaolo Bonzini /// let cell = BqlCell::new(5); 3658e194c0eSPaolo Bonzini /// assert_eq!(cell.get(), 5); 3668e194c0eSPaolo Bonzini /// assert_eq!(cell.replace(10), 5); 3678e194c0eSPaolo Bonzini /// assert_eq!(cell.get(), 10); 3688e194c0eSPaolo Bonzini /// ``` 3698e194c0eSPaolo Bonzini #[inline] 3708e194c0eSPaolo Bonzini pub fn replace(&self, val: T) -> T { 3718e194c0eSPaolo Bonzini assert!(bql_locked()); 3728e194c0eSPaolo Bonzini // SAFETY: This can cause data races if called from multiple threads, 3738e194c0eSPaolo Bonzini // but it won't happen as long as C code accesses the value 3748e194c0eSPaolo Bonzini // under BQL protection only. 3758e194c0eSPaolo Bonzini mem::replace(unsafe { &mut *self.value.get() }, val) 3768e194c0eSPaolo Bonzini } 3778e194c0eSPaolo Bonzini 3788e194c0eSPaolo Bonzini /// Unwraps the value, consuming the cell. 3798e194c0eSPaolo Bonzini /// 3808e194c0eSPaolo Bonzini /// # Examples 3818e194c0eSPaolo Bonzini /// 3828e194c0eSPaolo Bonzini /// ``` 3838e194c0eSPaolo Bonzini /// use qemu_api::cell::BqlCell; 384d4873c5dSPaolo Bonzini /// # qemu_api::cell::bql_start_test(); 3858e194c0eSPaolo Bonzini /// 3868e194c0eSPaolo Bonzini /// let c = BqlCell::new(5); 3878e194c0eSPaolo Bonzini /// let five = c.into_inner(); 3888e194c0eSPaolo Bonzini /// 3898e194c0eSPaolo Bonzini /// assert_eq!(five, 5); 3908e194c0eSPaolo Bonzini /// ``` 3918e194c0eSPaolo Bonzini pub fn into_inner(self) -> T { 3928e194c0eSPaolo Bonzini assert!(bql_locked()); 3938e194c0eSPaolo Bonzini self.value.into_inner() 3948e194c0eSPaolo Bonzini } 3958e194c0eSPaolo Bonzini } 3968e194c0eSPaolo Bonzini 3978e194c0eSPaolo Bonzini impl<T: Copy> BqlCell<T> { 3988e194c0eSPaolo Bonzini /// Returns a copy of the contained value. 3998e194c0eSPaolo Bonzini /// 4008e194c0eSPaolo Bonzini /// # Examples 4018e194c0eSPaolo Bonzini /// 4028e194c0eSPaolo Bonzini /// ``` 4038e194c0eSPaolo Bonzini /// use qemu_api::cell::BqlCell; 404d4873c5dSPaolo Bonzini /// # qemu_api::cell::bql_start_test(); 4058e194c0eSPaolo Bonzini /// 4068e194c0eSPaolo Bonzini /// let c = BqlCell::new(5); 4078e194c0eSPaolo Bonzini /// 4088e194c0eSPaolo Bonzini /// let five = c.get(); 4098e194c0eSPaolo Bonzini /// ``` 4108e194c0eSPaolo Bonzini #[inline] 4118e194c0eSPaolo Bonzini pub fn get(&self) -> T { 4128e194c0eSPaolo Bonzini assert!(bql_locked()); 4138e194c0eSPaolo Bonzini // SAFETY: This can cause data races if called from multiple threads, 4148e194c0eSPaolo Bonzini // but it won't happen as long as C code accesses the value 4158e194c0eSPaolo Bonzini // under BQL protection only. 4168e194c0eSPaolo Bonzini unsafe { *self.value.get() } 4178e194c0eSPaolo Bonzini } 4188e194c0eSPaolo Bonzini } 4198e194c0eSPaolo Bonzini 4208e194c0eSPaolo Bonzini impl<T> BqlCell<T> { 4218e194c0eSPaolo Bonzini /// Returns a raw pointer to the underlying data in this cell. 4228e194c0eSPaolo Bonzini /// 4238e194c0eSPaolo Bonzini /// # Examples 4248e194c0eSPaolo Bonzini /// 4258e194c0eSPaolo Bonzini /// ``` 4268e194c0eSPaolo Bonzini /// use qemu_api::cell::BqlCell; 427d4873c5dSPaolo Bonzini /// # qemu_api::cell::bql_start_test(); 4288e194c0eSPaolo Bonzini /// 4298e194c0eSPaolo Bonzini /// let c = BqlCell::new(5); 4308e194c0eSPaolo Bonzini /// 4318e194c0eSPaolo Bonzini /// let ptr = c.as_ptr(); 4328e194c0eSPaolo Bonzini /// ``` 4338e194c0eSPaolo Bonzini #[inline] 4348e194c0eSPaolo Bonzini pub const fn as_ptr(&self) -> *mut T { 4358e194c0eSPaolo Bonzini self.value.get() 4368e194c0eSPaolo Bonzini } 4378e194c0eSPaolo Bonzini } 4388e194c0eSPaolo Bonzini 4398e194c0eSPaolo Bonzini impl<T: Default> BqlCell<T> { 4408e194c0eSPaolo Bonzini /// Takes the value of the cell, leaving `Default::default()` in its place. 4418e194c0eSPaolo Bonzini /// 4428e194c0eSPaolo Bonzini /// # Examples 4438e194c0eSPaolo Bonzini /// 4448e194c0eSPaolo Bonzini /// ``` 4458e194c0eSPaolo Bonzini /// use qemu_api::cell::BqlCell; 446d4873c5dSPaolo Bonzini /// # qemu_api::cell::bql_start_test(); 4478e194c0eSPaolo Bonzini /// 4488e194c0eSPaolo Bonzini /// let c = BqlCell::new(5); 4498e194c0eSPaolo Bonzini /// let five = c.take(); 4508e194c0eSPaolo Bonzini /// 4518e194c0eSPaolo Bonzini /// assert_eq!(five, 5); 4528e194c0eSPaolo Bonzini /// assert_eq!(c.into_inner(), 0); 4538e194c0eSPaolo Bonzini /// ``` 4548e194c0eSPaolo Bonzini pub fn take(&self) -> T { 4558e194c0eSPaolo Bonzini self.replace(Default::default()) 4568e194c0eSPaolo Bonzini } 4578e194c0eSPaolo Bonzini } 458c596199fSPaolo Bonzini 459c596199fSPaolo Bonzini /// A mutable memory location with dynamically checked borrow rules, 460c596199fSPaolo Bonzini /// protected by the Big QEMU Lock. 461c596199fSPaolo Bonzini /// 462c596199fSPaolo Bonzini /// See the [module-level documentation](self) for more. 463c596199fSPaolo Bonzini /// 464c596199fSPaolo Bonzini /// # Memory layout 465c596199fSPaolo Bonzini /// 466c596199fSPaolo Bonzini /// `BqlRefCell<T>` starts with the same in-memory representation as its 467c596199fSPaolo Bonzini /// inner type `T`. 468c596199fSPaolo Bonzini #[repr(C)] 469c596199fSPaolo Bonzini pub struct BqlRefCell<T> { 470c596199fSPaolo Bonzini // It is important that this is the first field (which is not the case 471c596199fSPaolo Bonzini // for std::cell::BqlRefCell), so that we can use offset_of! on it. 472c596199fSPaolo Bonzini // UnsafeCell and repr(C) both prevent usage of niches. 473c596199fSPaolo Bonzini value: UnsafeCell<T>, 474c596199fSPaolo Bonzini borrow: Cell<BorrowFlag>, 475c596199fSPaolo Bonzini // Stores the location of the earliest currently active borrow. 476c596199fSPaolo Bonzini // This gets updated whenever we go from having zero borrows 477c596199fSPaolo Bonzini // to having a single borrow. When a borrow occurs, this gets included 478c596199fSPaolo Bonzini // in the panic message 479c596199fSPaolo Bonzini #[cfg(feature = "debug_cell")] 480c596199fSPaolo Bonzini borrowed_at: Cell<Option<&'static std::panic::Location<'static>>>, 481c596199fSPaolo Bonzini } 482c596199fSPaolo Bonzini 483c596199fSPaolo Bonzini // Positive values represent the number of `BqlRef` active. Negative values 484c596199fSPaolo Bonzini // represent the number of `BqlRefMut` active. Right now QEMU's implementation 485c596199fSPaolo Bonzini // does not allow to create `BqlRefMut`s that refer to distinct, nonoverlapping 486c596199fSPaolo Bonzini // components of a `BqlRefCell` (e.g., different ranges of a slice). 487c596199fSPaolo Bonzini // 488c596199fSPaolo Bonzini // `BqlRef` and `BqlRefMut` are both two words in size, and so there will likely 489c596199fSPaolo Bonzini // never be enough `BqlRef`s or `BqlRefMut`s in existence to overflow half of 490c596199fSPaolo Bonzini // the `usize` range. Thus, a `BorrowFlag` will probably never overflow or 491c596199fSPaolo Bonzini // underflow. However, this is not a guarantee, as a pathological program could 492c596199fSPaolo Bonzini // repeatedly create and then mem::forget `BqlRef`s or `BqlRefMut`s. Thus, all 493c596199fSPaolo Bonzini // code must explicitly check for overflow and underflow in order to avoid 494c596199fSPaolo Bonzini // unsafety, or at least behave correctly in the event that overflow or 495c596199fSPaolo Bonzini // underflow happens (e.g., see BorrowRef::new). 496c596199fSPaolo Bonzini type BorrowFlag = isize; 497c596199fSPaolo Bonzini const UNUSED: BorrowFlag = 0; 498c596199fSPaolo Bonzini 499c596199fSPaolo Bonzini #[inline(always)] 500c596199fSPaolo Bonzini const fn is_writing(x: BorrowFlag) -> bool { 501c596199fSPaolo Bonzini x < UNUSED 502c596199fSPaolo Bonzini } 503c596199fSPaolo Bonzini 504c596199fSPaolo Bonzini #[inline(always)] 505c596199fSPaolo Bonzini const fn is_reading(x: BorrowFlag) -> bool { 506c596199fSPaolo Bonzini x > UNUSED 507c596199fSPaolo Bonzini } 508c596199fSPaolo Bonzini 509c596199fSPaolo Bonzini impl<T> BqlRefCell<T> { 510c596199fSPaolo Bonzini /// Creates a new `BqlRefCell` containing `value`. 511c596199fSPaolo Bonzini /// 512c596199fSPaolo Bonzini /// # Examples 513c596199fSPaolo Bonzini /// 514c596199fSPaolo Bonzini /// ``` 515c596199fSPaolo Bonzini /// use qemu_api::cell::BqlRefCell; 516c596199fSPaolo Bonzini /// 517c596199fSPaolo Bonzini /// let c = BqlRefCell::new(5); 518c596199fSPaolo Bonzini /// ``` 519c596199fSPaolo Bonzini #[inline] 520c596199fSPaolo Bonzini pub const fn new(value: T) -> BqlRefCell<T> { 521c596199fSPaolo Bonzini BqlRefCell { 522c596199fSPaolo Bonzini value: UnsafeCell::new(value), 523c596199fSPaolo Bonzini borrow: Cell::new(UNUSED), 524c596199fSPaolo Bonzini #[cfg(feature = "debug_cell")] 525c596199fSPaolo Bonzini borrowed_at: Cell::new(None), 526c596199fSPaolo Bonzini } 527c596199fSPaolo Bonzini } 528c596199fSPaolo Bonzini } 529c596199fSPaolo Bonzini 530c596199fSPaolo Bonzini // This ensures the panicking code is outlined from `borrow_mut` for 531c596199fSPaolo Bonzini // `BqlRefCell`. 532c596199fSPaolo Bonzini #[inline(never)] 533c596199fSPaolo Bonzini #[cold] 534c596199fSPaolo Bonzini #[cfg(feature = "debug_cell")] 535c596199fSPaolo Bonzini fn panic_already_borrowed(source: &Cell<Option<&'static std::panic::Location<'static>>>) -> ! { 536c596199fSPaolo Bonzini // If a borrow occurred, then we must already have an outstanding borrow, 537c596199fSPaolo Bonzini // so `borrowed_at` will be `Some` 538c596199fSPaolo Bonzini panic!("already borrowed at {:?}", source.take().unwrap()) 539c596199fSPaolo Bonzini } 540c596199fSPaolo Bonzini 541c596199fSPaolo Bonzini #[inline(never)] 542c596199fSPaolo Bonzini #[cold] 543c596199fSPaolo Bonzini #[cfg(not(feature = "debug_cell"))] 544c596199fSPaolo Bonzini fn panic_already_borrowed() -> ! { 545c596199fSPaolo Bonzini panic!("already borrowed") 546c596199fSPaolo Bonzini } 547c596199fSPaolo Bonzini 548c596199fSPaolo Bonzini impl<T> BqlRefCell<T> { 549c596199fSPaolo Bonzini #[inline] 550c596199fSPaolo Bonzini #[allow(clippy::unused_self)] 551c596199fSPaolo Bonzini fn panic_already_borrowed(&self) -> ! { 552c596199fSPaolo Bonzini #[cfg(feature = "debug_cell")] 553c596199fSPaolo Bonzini { 554c596199fSPaolo Bonzini panic_already_borrowed(&self.borrowed_at) 555c596199fSPaolo Bonzini } 556c596199fSPaolo Bonzini #[cfg(not(feature = "debug_cell"))] 557c596199fSPaolo Bonzini { 558c596199fSPaolo Bonzini panic_already_borrowed() 559c596199fSPaolo Bonzini } 560c596199fSPaolo Bonzini } 561c596199fSPaolo Bonzini 562c596199fSPaolo Bonzini /// Immutably borrows the wrapped value. 563c596199fSPaolo Bonzini /// 564c596199fSPaolo Bonzini /// The borrow lasts until the returned `BqlRef` exits scope. Multiple 565c596199fSPaolo Bonzini /// immutable borrows can be taken out at the same time. 566c596199fSPaolo Bonzini /// 567c596199fSPaolo Bonzini /// # Panics 568c596199fSPaolo Bonzini /// 569c596199fSPaolo Bonzini /// Panics if the value is currently mutably borrowed. 570c596199fSPaolo Bonzini /// 571c596199fSPaolo Bonzini /// # Examples 572c596199fSPaolo Bonzini /// 573c596199fSPaolo Bonzini /// ``` 574c596199fSPaolo Bonzini /// use qemu_api::cell::BqlRefCell; 575d4873c5dSPaolo Bonzini /// # qemu_api::cell::bql_start_test(); 576c596199fSPaolo Bonzini /// 577c596199fSPaolo Bonzini /// let c = BqlRefCell::new(5); 578c596199fSPaolo Bonzini /// 579c596199fSPaolo Bonzini /// let borrowed_five = c.borrow(); 580c596199fSPaolo Bonzini /// let borrowed_five2 = c.borrow(); 581c596199fSPaolo Bonzini /// ``` 582c596199fSPaolo Bonzini /// 583c596199fSPaolo Bonzini /// An example of panic: 584c596199fSPaolo Bonzini /// 585c596199fSPaolo Bonzini /// ```should_panic 586c596199fSPaolo Bonzini /// use qemu_api::cell::BqlRefCell; 587d4873c5dSPaolo Bonzini /// # qemu_api::cell::bql_start_test(); 588c596199fSPaolo Bonzini /// 589c596199fSPaolo Bonzini /// let c = BqlRefCell::new(5); 590c596199fSPaolo Bonzini /// 591c596199fSPaolo Bonzini /// let m = c.borrow_mut(); 592c596199fSPaolo Bonzini /// let b = c.borrow(); // this causes a panic 593c596199fSPaolo Bonzini /// ``` 594c596199fSPaolo Bonzini #[inline] 595c596199fSPaolo Bonzini #[track_caller] 596c596199fSPaolo Bonzini pub fn borrow(&self) -> BqlRef<'_, T> { 597c596199fSPaolo Bonzini if let Some(b) = BorrowRef::new(&self.borrow) { 598c596199fSPaolo Bonzini // `borrowed_at` is always the *first* active borrow 599c596199fSPaolo Bonzini if b.borrow.get() == 1 { 600c596199fSPaolo Bonzini #[cfg(feature = "debug_cell")] 601c596199fSPaolo Bonzini self.borrowed_at.set(Some(std::panic::Location::caller())); 602c596199fSPaolo Bonzini } 603c596199fSPaolo Bonzini 604c596199fSPaolo Bonzini bql_block_unlock(true); 605c596199fSPaolo Bonzini 606c596199fSPaolo Bonzini // SAFETY: `BorrowRef` ensures that there is only immutable access 607c596199fSPaolo Bonzini // to the value while borrowed. 608c596199fSPaolo Bonzini let value = unsafe { NonNull::new_unchecked(self.value.get()) }; 609c596199fSPaolo Bonzini BqlRef { value, borrow: b } 610c596199fSPaolo Bonzini } else { 611c596199fSPaolo Bonzini self.panic_already_borrowed() 612c596199fSPaolo Bonzini } 613c596199fSPaolo Bonzini } 614c596199fSPaolo Bonzini 615c596199fSPaolo Bonzini /// Mutably borrows the wrapped value. 616c596199fSPaolo Bonzini /// 617c596199fSPaolo Bonzini /// The borrow lasts until the returned `BqlRefMut` or all `BqlRefMut`s 618c596199fSPaolo Bonzini /// derived from it exit scope. The value cannot be borrowed while this 619c596199fSPaolo Bonzini /// borrow is active. 620c596199fSPaolo Bonzini /// 621c596199fSPaolo Bonzini /// # Panics 622c596199fSPaolo Bonzini /// 623c596199fSPaolo Bonzini /// Panics if the value is currently borrowed. 624c596199fSPaolo Bonzini /// 625c596199fSPaolo Bonzini /// # Examples 626c596199fSPaolo Bonzini /// 627c596199fSPaolo Bonzini /// ``` 628c596199fSPaolo Bonzini /// use qemu_api::cell::BqlRefCell; 629d4873c5dSPaolo Bonzini /// # qemu_api::cell::bql_start_test(); 630c596199fSPaolo Bonzini /// 631c596199fSPaolo Bonzini /// let c = BqlRefCell::new("hello".to_owned()); 632c596199fSPaolo Bonzini /// 633c596199fSPaolo Bonzini /// *c.borrow_mut() = "bonjour".to_owned(); 634c596199fSPaolo Bonzini /// 635c596199fSPaolo Bonzini /// assert_eq!(&*c.borrow(), "bonjour"); 636c596199fSPaolo Bonzini /// ``` 637c596199fSPaolo Bonzini /// 638c596199fSPaolo Bonzini /// An example of panic: 639c596199fSPaolo Bonzini /// 640c596199fSPaolo Bonzini /// ```should_panic 641c596199fSPaolo Bonzini /// use qemu_api::cell::BqlRefCell; 642d4873c5dSPaolo Bonzini /// # qemu_api::cell::bql_start_test(); 643c596199fSPaolo Bonzini /// 644c596199fSPaolo Bonzini /// let c = BqlRefCell::new(5); 645c596199fSPaolo Bonzini /// let m = c.borrow(); 646c596199fSPaolo Bonzini /// 647c596199fSPaolo Bonzini /// let b = c.borrow_mut(); // this causes a panic 648c596199fSPaolo Bonzini /// ``` 649c596199fSPaolo Bonzini #[inline] 650c596199fSPaolo Bonzini #[track_caller] 651c596199fSPaolo Bonzini pub fn borrow_mut(&self) -> BqlRefMut<'_, T> { 652c596199fSPaolo Bonzini if let Some(b) = BorrowRefMut::new(&self.borrow) { 653c596199fSPaolo Bonzini #[cfg(feature = "debug_cell")] 654c596199fSPaolo Bonzini { 655c596199fSPaolo Bonzini self.borrowed_at.set(Some(std::panic::Location::caller())); 656c596199fSPaolo Bonzini } 657c596199fSPaolo Bonzini 658c596199fSPaolo Bonzini // SAFETY: this only adjusts a counter 659c596199fSPaolo Bonzini bql_block_unlock(true); 660c596199fSPaolo Bonzini 661c596199fSPaolo Bonzini // SAFETY: `BorrowRefMut` guarantees unique access. 662c596199fSPaolo Bonzini let value = unsafe { NonNull::new_unchecked(self.value.get()) }; 663c596199fSPaolo Bonzini BqlRefMut { 664c596199fSPaolo Bonzini value, 665c596199fSPaolo Bonzini _borrow: b, 666c596199fSPaolo Bonzini marker: PhantomData, 667c596199fSPaolo Bonzini } 668c596199fSPaolo Bonzini } else { 669c596199fSPaolo Bonzini self.panic_already_borrowed() 670c596199fSPaolo Bonzini } 671c596199fSPaolo Bonzini } 672c596199fSPaolo Bonzini 673c596199fSPaolo Bonzini /// Returns a raw pointer to the underlying data in this cell. 674c596199fSPaolo Bonzini /// 675c596199fSPaolo Bonzini /// # Examples 676c596199fSPaolo Bonzini /// 677c596199fSPaolo Bonzini /// ``` 678c596199fSPaolo Bonzini /// use qemu_api::cell::BqlRefCell; 679c596199fSPaolo Bonzini /// 680c596199fSPaolo Bonzini /// let c = BqlRefCell::new(5); 681c596199fSPaolo Bonzini /// 682c596199fSPaolo Bonzini /// let ptr = c.as_ptr(); 683c596199fSPaolo Bonzini /// ``` 684c596199fSPaolo Bonzini #[inline] 685c596199fSPaolo Bonzini pub const fn as_ptr(&self) -> *mut T { 686c596199fSPaolo Bonzini self.value.get() 687c596199fSPaolo Bonzini } 688c596199fSPaolo Bonzini } 689c596199fSPaolo Bonzini 690c596199fSPaolo Bonzini // SAFETY: Same as for std::sync::Mutex. In the end this is a Mutex that is 691c596199fSPaolo Bonzini // stored out-of-line. Even though BqlRefCell includes Cells, they are 692c596199fSPaolo Bonzini // themselves protected by the Big QEMU Lock. Furtheremore, the Big QEMU 693c596199fSPaolo Bonzini // Lock cannot be released while any borrows is active. 694c596199fSPaolo Bonzini unsafe impl<T> Send for BqlRefCell<T> where T: Send {} 695c596199fSPaolo Bonzini unsafe impl<T> Sync for BqlRefCell<T> {} 696c596199fSPaolo Bonzini 697c596199fSPaolo Bonzini impl<T: Clone> Clone for BqlRefCell<T> { 698c596199fSPaolo Bonzini /// # Panics 699c596199fSPaolo Bonzini /// 700c596199fSPaolo Bonzini /// Panics if the value is currently mutably borrowed. 701c596199fSPaolo Bonzini #[inline] 702c596199fSPaolo Bonzini #[track_caller] 703c596199fSPaolo Bonzini fn clone(&self) -> BqlRefCell<T> { 704c596199fSPaolo Bonzini BqlRefCell::new(self.borrow().clone()) 705c596199fSPaolo Bonzini } 706c596199fSPaolo Bonzini 707c596199fSPaolo Bonzini /// # Panics 708c596199fSPaolo Bonzini /// 709c596199fSPaolo Bonzini /// Panics if `source` is currently mutably borrowed. 710c596199fSPaolo Bonzini #[inline] 711c596199fSPaolo Bonzini #[track_caller] 712c596199fSPaolo Bonzini fn clone_from(&mut self, source: &Self) { 713c596199fSPaolo Bonzini self.value.get_mut().clone_from(&source.borrow()) 714c596199fSPaolo Bonzini } 715c596199fSPaolo Bonzini } 716c596199fSPaolo Bonzini 717c596199fSPaolo Bonzini impl<T: Default> Default for BqlRefCell<T> { 718c596199fSPaolo Bonzini /// Creates a `BqlRefCell<T>`, with the `Default` value for T. 719c596199fSPaolo Bonzini #[inline] 720c596199fSPaolo Bonzini fn default() -> BqlRefCell<T> { 721c596199fSPaolo Bonzini BqlRefCell::new(Default::default()) 722c596199fSPaolo Bonzini } 723c596199fSPaolo Bonzini } 724c596199fSPaolo Bonzini 725c596199fSPaolo Bonzini impl<T: PartialEq> PartialEq for BqlRefCell<T> { 726c596199fSPaolo Bonzini /// # Panics 727c596199fSPaolo Bonzini /// 728c596199fSPaolo Bonzini /// Panics if the value in either `BqlRefCell` is currently mutably 729c596199fSPaolo Bonzini /// borrowed. 730c596199fSPaolo Bonzini #[inline] 731c596199fSPaolo Bonzini fn eq(&self, other: &BqlRefCell<T>) -> bool { 732c596199fSPaolo Bonzini *self.borrow() == *other.borrow() 733c596199fSPaolo Bonzini } 734c596199fSPaolo Bonzini } 735c596199fSPaolo Bonzini 736c596199fSPaolo Bonzini impl<T: Eq> Eq for BqlRefCell<T> {} 737c596199fSPaolo Bonzini 738c596199fSPaolo Bonzini impl<T: PartialOrd> PartialOrd for BqlRefCell<T> { 739c596199fSPaolo Bonzini /// # Panics 740c596199fSPaolo Bonzini /// 741c596199fSPaolo Bonzini /// Panics if the value in either `BqlRefCell` is currently mutably 742c596199fSPaolo Bonzini /// borrowed. 743c596199fSPaolo Bonzini #[inline] 744c596199fSPaolo Bonzini fn partial_cmp(&self, other: &BqlRefCell<T>) -> Option<Ordering> { 745c596199fSPaolo Bonzini self.borrow().partial_cmp(&*other.borrow()) 746c596199fSPaolo Bonzini } 747c596199fSPaolo Bonzini } 748c596199fSPaolo Bonzini 749c596199fSPaolo Bonzini impl<T: Ord> Ord for BqlRefCell<T> { 750c596199fSPaolo Bonzini /// # Panics 751c596199fSPaolo Bonzini /// 752c596199fSPaolo Bonzini /// Panics if the value in either `BqlRefCell` is currently mutably 753c596199fSPaolo Bonzini /// borrowed. 754c596199fSPaolo Bonzini #[inline] 755c596199fSPaolo Bonzini fn cmp(&self, other: &BqlRefCell<T>) -> Ordering { 756c596199fSPaolo Bonzini self.borrow().cmp(&*other.borrow()) 757c596199fSPaolo Bonzini } 758c596199fSPaolo Bonzini } 759c596199fSPaolo Bonzini 760c596199fSPaolo Bonzini impl<T> From<T> for BqlRefCell<T> { 761c596199fSPaolo Bonzini /// Creates a new `BqlRefCell<T>` containing the given value. 762c596199fSPaolo Bonzini fn from(t: T) -> BqlRefCell<T> { 763c596199fSPaolo Bonzini BqlRefCell::new(t) 764c596199fSPaolo Bonzini } 765c596199fSPaolo Bonzini } 766c596199fSPaolo Bonzini 767c596199fSPaolo Bonzini struct BorrowRef<'b> { 768c596199fSPaolo Bonzini borrow: &'b Cell<BorrowFlag>, 769c596199fSPaolo Bonzini } 770c596199fSPaolo Bonzini 771c596199fSPaolo Bonzini impl<'b> BorrowRef<'b> { 772c596199fSPaolo Bonzini #[inline] 773c596199fSPaolo Bonzini fn new(borrow: &'b Cell<BorrowFlag>) -> Option<BorrowRef<'b>> { 774c596199fSPaolo Bonzini let b = borrow.get().wrapping_add(1); 775c596199fSPaolo Bonzini if !is_reading(b) { 776c596199fSPaolo Bonzini // Incrementing borrow can result in a non-reading value (<= 0) in these cases: 777c596199fSPaolo Bonzini // 1. It was < 0, i.e. there are writing borrows, so we can't allow a read 778c596199fSPaolo Bonzini // borrow due to Rust's reference aliasing rules 779c596199fSPaolo Bonzini // 2. It was isize::MAX (the max amount of reading borrows) and it overflowed 780c596199fSPaolo Bonzini // into isize::MIN (the max amount of writing borrows) so we can't allow an 781c596199fSPaolo Bonzini // additional read borrow because isize can't represent so many read borrows 782c596199fSPaolo Bonzini // (this can only happen if you mem::forget more than a small constant amount 783c596199fSPaolo Bonzini // of `BqlRef`s, which is not good practice) 784c596199fSPaolo Bonzini None 785c596199fSPaolo Bonzini } else { 786c596199fSPaolo Bonzini // Incrementing borrow can result in a reading value (> 0) in these cases: 787c596199fSPaolo Bonzini // 1. It was = 0, i.e. it wasn't borrowed, and we are taking the first read 788c596199fSPaolo Bonzini // borrow 789c596199fSPaolo Bonzini // 2. It was > 0 and < isize::MAX, i.e. there were read borrows, and isize is 790c596199fSPaolo Bonzini // large enough to represent having one more read borrow 791c596199fSPaolo Bonzini borrow.set(b); 792c596199fSPaolo Bonzini Some(BorrowRef { borrow }) 793c596199fSPaolo Bonzini } 794c596199fSPaolo Bonzini } 795c596199fSPaolo Bonzini } 796c596199fSPaolo Bonzini 797c596199fSPaolo Bonzini impl Drop for BorrowRef<'_> { 798c596199fSPaolo Bonzini #[inline] 799c596199fSPaolo Bonzini fn drop(&mut self) { 800c596199fSPaolo Bonzini let borrow = self.borrow.get(); 801c596199fSPaolo Bonzini debug_assert!(is_reading(borrow)); 802c596199fSPaolo Bonzini self.borrow.set(borrow - 1); 803c596199fSPaolo Bonzini bql_block_unlock(false) 804c596199fSPaolo Bonzini } 805c596199fSPaolo Bonzini } 806c596199fSPaolo Bonzini 807c596199fSPaolo Bonzini impl Clone for BorrowRef<'_> { 808c596199fSPaolo Bonzini #[inline] 809c596199fSPaolo Bonzini fn clone(&self) -> Self { 810c596199fSPaolo Bonzini BorrowRef::new(self.borrow).unwrap() 811c596199fSPaolo Bonzini } 812c596199fSPaolo Bonzini } 813c596199fSPaolo Bonzini 814c596199fSPaolo Bonzini /// Wraps a borrowed reference to a value in a `BqlRefCell` box. 815c596199fSPaolo Bonzini /// A wrapper type for an immutably borrowed value from a `BqlRefCell<T>`. 816c596199fSPaolo Bonzini /// 817c596199fSPaolo Bonzini /// See the [module-level documentation](self) for more. 818c596199fSPaolo Bonzini pub struct BqlRef<'b, T: 'b> { 819c596199fSPaolo Bonzini // NB: we use a pointer instead of `&'b T` to avoid `noalias` violations, because a 820c596199fSPaolo Bonzini // `BqlRef` argument doesn't hold immutability for its whole scope, only until it drops. 821c596199fSPaolo Bonzini // `NonNull` is also covariant over `T`, just like we would have with `&T`. 822c596199fSPaolo Bonzini value: NonNull<T>, 823c596199fSPaolo Bonzini borrow: BorrowRef<'b>, 824c596199fSPaolo Bonzini } 825c596199fSPaolo Bonzini 826c596199fSPaolo Bonzini impl<T> Deref for BqlRef<'_, T> { 827c596199fSPaolo Bonzini type Target = T; 828c596199fSPaolo Bonzini 829c596199fSPaolo Bonzini #[inline] 830c596199fSPaolo Bonzini fn deref(&self) -> &T { 831c596199fSPaolo Bonzini // SAFETY: the value is accessible as long as we hold our borrow. 832c596199fSPaolo Bonzini unsafe { self.value.as_ref() } 833c596199fSPaolo Bonzini } 834c596199fSPaolo Bonzini } 835c596199fSPaolo Bonzini 836c596199fSPaolo Bonzini impl<'b, T> BqlRef<'b, T> { 837c596199fSPaolo Bonzini /// Copies a `BqlRef`. 838c596199fSPaolo Bonzini /// 839c596199fSPaolo Bonzini /// The `BqlRefCell` is already immutably borrowed, so this cannot fail. 840c596199fSPaolo Bonzini /// 841c596199fSPaolo Bonzini /// This is an associated function that needs to be used as 842c596199fSPaolo Bonzini /// `BqlRef::clone(...)`. A `Clone` implementation or a method would 843c596199fSPaolo Bonzini /// interfere with the widespread use of `r.borrow().clone()` to clone 844c596199fSPaolo Bonzini /// the contents of a `BqlRefCell`. 845c596199fSPaolo Bonzini #[must_use] 846c596199fSPaolo Bonzini #[inline] 847c596199fSPaolo Bonzini #[allow(clippy::should_implement_trait)] 848c596199fSPaolo Bonzini pub fn clone(orig: &BqlRef<'b, T>) -> BqlRef<'b, T> { 849c596199fSPaolo Bonzini BqlRef { 850c596199fSPaolo Bonzini value: orig.value, 851c596199fSPaolo Bonzini borrow: orig.borrow.clone(), 852c596199fSPaolo Bonzini } 853c596199fSPaolo Bonzini } 854c596199fSPaolo Bonzini } 855c596199fSPaolo Bonzini 856c596199fSPaolo Bonzini impl<T: fmt::Debug> fmt::Debug for BqlRef<'_, T> { 857c596199fSPaolo Bonzini fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { 858c596199fSPaolo Bonzini (**self).fmt(f) 859c596199fSPaolo Bonzini } 860c596199fSPaolo Bonzini } 861c596199fSPaolo Bonzini 862c596199fSPaolo Bonzini impl<T: fmt::Display> fmt::Display for BqlRef<'_, T> { 863c596199fSPaolo Bonzini fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { 864c596199fSPaolo Bonzini (**self).fmt(f) 865c596199fSPaolo Bonzini } 866c596199fSPaolo Bonzini } 867c596199fSPaolo Bonzini 868c596199fSPaolo Bonzini struct BorrowRefMut<'b> { 869c596199fSPaolo Bonzini borrow: &'b Cell<BorrowFlag>, 870c596199fSPaolo Bonzini } 871c596199fSPaolo Bonzini 872c596199fSPaolo Bonzini impl<'b> BorrowRefMut<'b> { 873c596199fSPaolo Bonzini #[inline] 874c596199fSPaolo Bonzini fn new(borrow: &'b Cell<BorrowFlag>) -> Option<BorrowRefMut<'b>> { 875c596199fSPaolo Bonzini // There must currently be no existing references when borrow_mut() is 876c596199fSPaolo Bonzini // called, so we explicitly only allow going from UNUSED to UNUSED - 1. 877c596199fSPaolo Bonzini match borrow.get() { 878c596199fSPaolo Bonzini UNUSED => { 879c596199fSPaolo Bonzini borrow.set(UNUSED - 1); 880c596199fSPaolo Bonzini Some(BorrowRefMut { borrow }) 881c596199fSPaolo Bonzini } 882c596199fSPaolo Bonzini _ => None, 883c596199fSPaolo Bonzini } 884c596199fSPaolo Bonzini } 885c596199fSPaolo Bonzini } 886c596199fSPaolo Bonzini 887c596199fSPaolo Bonzini impl Drop for BorrowRefMut<'_> { 888c596199fSPaolo Bonzini #[inline] 889c596199fSPaolo Bonzini fn drop(&mut self) { 890c596199fSPaolo Bonzini let borrow = self.borrow.get(); 891c596199fSPaolo Bonzini debug_assert!(is_writing(borrow)); 892c596199fSPaolo Bonzini self.borrow.set(borrow + 1); 893c596199fSPaolo Bonzini bql_block_unlock(false) 894c596199fSPaolo Bonzini } 895c596199fSPaolo Bonzini } 896c596199fSPaolo Bonzini 897c596199fSPaolo Bonzini /// A wrapper type for a mutably borrowed value from a `BqlRefCell<T>`. 898c596199fSPaolo Bonzini /// 899c596199fSPaolo Bonzini /// See the [module-level documentation](self) for more. 900c596199fSPaolo Bonzini pub struct BqlRefMut<'b, T: 'b> { 901c596199fSPaolo Bonzini // NB: we use a pointer instead of `&'b mut T` to avoid `noalias` violations, because a 902c596199fSPaolo Bonzini // `BqlRefMut` argument doesn't hold exclusivity for its whole scope, only until it drops. 903c596199fSPaolo Bonzini value: NonNull<T>, 904c596199fSPaolo Bonzini _borrow: BorrowRefMut<'b>, 905c596199fSPaolo Bonzini // `NonNull` is covariant over `T`, so we need to reintroduce invariance. 906c596199fSPaolo Bonzini marker: PhantomData<&'b mut T>, 907c596199fSPaolo Bonzini } 908c596199fSPaolo Bonzini 909c596199fSPaolo Bonzini impl<T> Deref for BqlRefMut<'_, T> { 910c596199fSPaolo Bonzini type Target = T; 911c596199fSPaolo Bonzini 912c596199fSPaolo Bonzini #[inline] 913c596199fSPaolo Bonzini fn deref(&self) -> &T { 914c596199fSPaolo Bonzini // SAFETY: the value is accessible as long as we hold our borrow. 915c596199fSPaolo Bonzini unsafe { self.value.as_ref() } 916c596199fSPaolo Bonzini } 917c596199fSPaolo Bonzini } 918c596199fSPaolo Bonzini 919c596199fSPaolo Bonzini impl<T> DerefMut for BqlRefMut<'_, T> { 920c596199fSPaolo Bonzini #[inline] 921c596199fSPaolo Bonzini fn deref_mut(&mut self) -> &mut T { 922c596199fSPaolo Bonzini // SAFETY: the value is accessible as long as we hold our borrow. 923c596199fSPaolo Bonzini unsafe { self.value.as_mut() } 924c596199fSPaolo Bonzini } 925c596199fSPaolo Bonzini } 926c596199fSPaolo Bonzini 927c596199fSPaolo Bonzini impl<T: fmt::Debug> fmt::Debug for BqlRefMut<'_, T> { 928c596199fSPaolo Bonzini fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { 929c596199fSPaolo Bonzini (**self).fmt(f) 930c596199fSPaolo Bonzini } 931c596199fSPaolo Bonzini } 932c596199fSPaolo Bonzini 933c596199fSPaolo Bonzini impl<T: fmt::Display> fmt::Display for BqlRefMut<'_, T> { 934c596199fSPaolo Bonzini fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { 935c596199fSPaolo Bonzini (**self).fmt(f) 936c596199fSPaolo Bonzini } 937c596199fSPaolo Bonzini } 9380b9d05e3SPaolo Bonzini 9390b9d05e3SPaolo Bonzini /// Stores an opaque value that is shared with C code. 9400b9d05e3SPaolo Bonzini /// 9410b9d05e3SPaolo Bonzini /// Often, C structs can changed when calling a C function even if they are 9420b9d05e3SPaolo Bonzini /// behind a shared Rust reference, or they can be initialized lazily and have 9430b9d05e3SPaolo Bonzini /// invalid bit patterns (e.g. `3` for a [`bool`]). This goes against Rust's 9440b9d05e3SPaolo Bonzini /// strict aliasing rules, which normally prevent mutation through shared 9450b9d05e3SPaolo Bonzini /// references. 9460b9d05e3SPaolo Bonzini /// 9470b9d05e3SPaolo Bonzini /// Wrapping the struct with `Opaque<T>` ensures that the Rust compiler does not 9480b9d05e3SPaolo Bonzini /// assume the usual constraints that Rust structs require, and allows using 9490b9d05e3SPaolo Bonzini /// shared references on the Rust side. 9500b9d05e3SPaolo Bonzini /// 9510b9d05e3SPaolo Bonzini /// `Opaque<T>` is `#[repr(transparent)]`, so that it matches the memory layout 9520b9d05e3SPaolo Bonzini /// of `T`. 9530b9d05e3SPaolo Bonzini #[repr(transparent)] 9540b9d05e3SPaolo Bonzini pub struct Opaque<T> { 9550b9d05e3SPaolo Bonzini value: UnsafeCell<MaybeUninit<T>>, 9560b9d05e3SPaolo Bonzini // PhantomPinned also allows multiple references to the `Opaque<T>`, i.e. 9570b9d05e3SPaolo Bonzini // one `&mut Opaque<T>` can coexist with a `&mut T` or any number of `&T`; 9580b9d05e3SPaolo Bonzini // see https://docs.rs/pinned-aliasable/latest/pinned_aliasable/. 9590b9d05e3SPaolo Bonzini _pin: PhantomPinned, 9600b9d05e3SPaolo Bonzini } 9610b9d05e3SPaolo Bonzini 9620b9d05e3SPaolo Bonzini impl<T> Opaque<T> { 9630b9d05e3SPaolo Bonzini /// Creates a new shared reference from a C pointer 9640b9d05e3SPaolo Bonzini /// 9650b9d05e3SPaolo Bonzini /// # Safety 9660b9d05e3SPaolo Bonzini /// 9670b9d05e3SPaolo Bonzini /// The pointer must be valid, though it need not point to a valid value. 9680b9d05e3SPaolo Bonzini pub unsafe fn from_raw<'a>(ptr: *mut T) -> &'a Self { 9690b9d05e3SPaolo Bonzini let ptr = NonNull::new(ptr).unwrap().cast::<Self>(); 9700b9d05e3SPaolo Bonzini // SAFETY: Self is a transparent wrapper over T 9710b9d05e3SPaolo Bonzini unsafe { ptr.as_ref() } 9720b9d05e3SPaolo Bonzini } 9730b9d05e3SPaolo Bonzini 9740b9d05e3SPaolo Bonzini /// Creates a new opaque object with uninitialized contents. 9750b9d05e3SPaolo Bonzini /// 9760b9d05e3SPaolo Bonzini /// # Safety 9770b9d05e3SPaolo Bonzini /// 9780b9d05e3SPaolo Bonzini /// Ultimately the pointer to the returned value will be dereferenced 9790b9d05e3SPaolo Bonzini /// in another `unsafe` block, for example when passing it to a C function, 9800b9d05e3SPaolo Bonzini /// but the functions containing the dereference are usually safe. The 9810b9d05e3SPaolo Bonzini /// value returned from `uninit()` must be initialized and pinned before 9820b9d05e3SPaolo Bonzini /// calling them. 9830b9d05e3SPaolo Bonzini #[allow(clippy::missing_const_for_fn)] 9840b9d05e3SPaolo Bonzini pub unsafe fn uninit() -> Self { 9850b9d05e3SPaolo Bonzini Self { 9860b9d05e3SPaolo Bonzini value: UnsafeCell::new(MaybeUninit::uninit()), 9870b9d05e3SPaolo Bonzini _pin: PhantomPinned, 9880b9d05e3SPaolo Bonzini } 9890b9d05e3SPaolo Bonzini } 9900b9d05e3SPaolo Bonzini 9910b9d05e3SPaolo Bonzini /// Creates a new opaque object with zeroed contents. 9920b9d05e3SPaolo Bonzini /// 9930b9d05e3SPaolo Bonzini /// # Safety 9940b9d05e3SPaolo Bonzini /// 9950b9d05e3SPaolo Bonzini /// Ultimately the pointer to the returned value will be dereferenced 9960b9d05e3SPaolo Bonzini /// in another `unsafe` block, for example when passing it to a C function, 9970b9d05e3SPaolo Bonzini /// but the functions containing the dereference are usually safe. The 9980b9d05e3SPaolo Bonzini /// value returned from `uninit()` must be pinned (and possibly initialized) 9990b9d05e3SPaolo Bonzini /// before calling them. 10000b9d05e3SPaolo Bonzini #[allow(clippy::missing_const_for_fn)] 10010b9d05e3SPaolo Bonzini pub unsafe fn zeroed() -> Self { 10020b9d05e3SPaolo Bonzini Self { 10030b9d05e3SPaolo Bonzini value: UnsafeCell::new(MaybeUninit::zeroed()), 10040b9d05e3SPaolo Bonzini _pin: PhantomPinned, 10050b9d05e3SPaolo Bonzini } 10060b9d05e3SPaolo Bonzini } 10070b9d05e3SPaolo Bonzini 10080b9d05e3SPaolo Bonzini /// Returns a raw mutable pointer to the opaque data. 10090b9d05e3SPaolo Bonzini pub const fn as_mut_ptr(&self) -> *mut T { 10100b9d05e3SPaolo Bonzini UnsafeCell::get(&self.value).cast() 10110b9d05e3SPaolo Bonzini } 10120b9d05e3SPaolo Bonzini 10130b9d05e3SPaolo Bonzini /// Returns a raw pointer to the opaque data. 10140b9d05e3SPaolo Bonzini pub const fn as_ptr(&self) -> *const T { 10155df3fe06SPaolo Bonzini self.as_mut_ptr().cast_const() 10160b9d05e3SPaolo Bonzini } 10170b9d05e3SPaolo Bonzini 10180b9d05e3SPaolo Bonzini /// Returns a raw pointer to the opaque data that can be passed to a 10190b9d05e3SPaolo Bonzini /// C function as `void *`. 10200b9d05e3SPaolo Bonzini pub const fn as_void_ptr(&self) -> *mut std::ffi::c_void { 10210b9d05e3SPaolo Bonzini UnsafeCell::get(&self.value).cast() 10220b9d05e3SPaolo Bonzini } 10230b9d05e3SPaolo Bonzini 10240b9d05e3SPaolo Bonzini /// Converts a raw pointer to the wrapped type. 10250b9d05e3SPaolo Bonzini pub const fn raw_get(slot: *mut Self) -> *mut T { 10260b9d05e3SPaolo Bonzini // Compare with Linux's raw_get method, which goes through an UnsafeCell 10270b9d05e3SPaolo Bonzini // because it takes a *const Self instead. 10280b9d05e3SPaolo Bonzini slot.cast() 10290b9d05e3SPaolo Bonzini } 10300b9d05e3SPaolo Bonzini } 10310b9d05e3SPaolo Bonzini 10320b9d05e3SPaolo Bonzini impl<T> fmt::Debug for Opaque<T> { 10330b9d05e3SPaolo Bonzini fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { 10340b9d05e3SPaolo Bonzini let mut name: String = "Opaque<".to_string(); 10350b9d05e3SPaolo Bonzini name += std::any::type_name::<T>(); 10360b9d05e3SPaolo Bonzini name += ">"; 10370b9d05e3SPaolo Bonzini f.debug_tuple(&name).field(&self.as_ptr()).finish() 10380b9d05e3SPaolo Bonzini } 10390b9d05e3SPaolo Bonzini } 10400b9d05e3SPaolo Bonzini 10410b9d05e3SPaolo Bonzini impl<T: Default> Opaque<T> { 10420b9d05e3SPaolo Bonzini /// Creates a new opaque object with default contents. 10430b9d05e3SPaolo Bonzini /// 10440b9d05e3SPaolo Bonzini /// # Safety 10450b9d05e3SPaolo Bonzini /// 10460b9d05e3SPaolo Bonzini /// Ultimately the pointer to the returned value will be dereferenced 10470b9d05e3SPaolo Bonzini /// in another `unsafe` block, for example when passing it to a C function, 10480b9d05e3SPaolo Bonzini /// but the functions containing the dereference are usually safe. The 10490b9d05e3SPaolo Bonzini /// value returned from `uninit()` must be pinned before calling them. 10500b9d05e3SPaolo Bonzini pub unsafe fn new() -> Self { 10510b9d05e3SPaolo Bonzini Self { 10520b9d05e3SPaolo Bonzini value: UnsafeCell::new(MaybeUninit::new(T::default())), 10530b9d05e3SPaolo Bonzini _pin: PhantomPinned, 10540b9d05e3SPaolo Bonzini } 10550b9d05e3SPaolo Bonzini } 10560b9d05e3SPaolo Bonzini } 1057f07a5674SPaolo Bonzini 1058f07a5674SPaolo Bonzini /// Annotates [`Self`] as a transparent wrapper for another type. 1059f07a5674SPaolo Bonzini /// 1060f07a5674SPaolo Bonzini /// Usually defined via the [`qemu_api_macros::Wrapper`] derive macro. 1061f07a5674SPaolo Bonzini /// 1062f07a5674SPaolo Bonzini /// # Examples 1063f07a5674SPaolo Bonzini /// 1064f07a5674SPaolo Bonzini /// ``` 1065f07a5674SPaolo Bonzini /// # use std::mem::ManuallyDrop; 1066f07a5674SPaolo Bonzini /// # use qemu_api::cell::Wrapper; 1067f07a5674SPaolo Bonzini /// #[repr(transparent)] 1068f07a5674SPaolo Bonzini /// pub struct Example { 1069f07a5674SPaolo Bonzini /// inner: ManuallyDrop<String>, 1070f07a5674SPaolo Bonzini /// } 1071f07a5674SPaolo Bonzini /// 1072f07a5674SPaolo Bonzini /// unsafe impl Wrapper for Example { 1073f07a5674SPaolo Bonzini /// type Wrapped = String; 1074f07a5674SPaolo Bonzini /// } 1075f07a5674SPaolo Bonzini /// ``` 1076f07a5674SPaolo Bonzini /// 1077f07a5674SPaolo Bonzini /// # Safety 1078f07a5674SPaolo Bonzini /// 1079f07a5674SPaolo Bonzini /// `Self` must be a `#[repr(transparent)]` wrapper for the `Wrapped` type, 1080f07a5674SPaolo Bonzini /// whether directly or indirectly. 1081f07a5674SPaolo Bonzini /// 1082f07a5674SPaolo Bonzini /// # Methods 1083f07a5674SPaolo Bonzini /// 1084f07a5674SPaolo Bonzini /// By convention, types that implement Wrapper also implement the following 1085f07a5674SPaolo Bonzini /// methods: 1086f07a5674SPaolo Bonzini /// 1087f07a5674SPaolo Bonzini /// ```ignore 1088f07a5674SPaolo Bonzini /// pub const unsafe fn from_raw<'a>(value: *mut Self::Wrapped) -> &'a Self; 1089f07a5674SPaolo Bonzini /// pub const unsafe fn as_mut_ptr(&self) -> *mut Self::Wrapped; 1090f07a5674SPaolo Bonzini /// pub const unsafe fn as_ptr(&self) -> *const Self::Wrapped; 1091f07a5674SPaolo Bonzini /// pub const unsafe fn raw_get(slot: *mut Self) -> *const Self::Wrapped; 1092f07a5674SPaolo Bonzini /// ``` 1093f07a5674SPaolo Bonzini /// 1094f07a5674SPaolo Bonzini /// They are not defined here to allow them to be `const`. 1095f07a5674SPaolo Bonzini pub unsafe trait Wrapper { 1096f07a5674SPaolo Bonzini type Wrapped; 1097f07a5674SPaolo Bonzini } 1098f07a5674SPaolo Bonzini 1099f07a5674SPaolo Bonzini unsafe impl<T> Wrapper for Opaque<T> { 1100f07a5674SPaolo Bonzini type Wrapped = T; 1101f07a5674SPaolo Bonzini } 1102