// SPDX-License-Identifier: GPL-2.0 //! Devres abstraction //! //! [`Devres`] represents an abstraction for the kernel devres (device resource management) //! implementation. use crate::{ alloc::Flags, bindings, device::Device, error::{Error, Result}, ffi::c_void, prelude::*, revocable::Revocable, sync::Arc, types::ARef, }; use core::ops::Deref; #[pin_data] struct DevresInner { dev: ARef, callback: unsafe extern "C" fn(*mut c_void), #[pin] data: Revocable, } /// This abstraction is meant to be used by subsystems to containerize [`Device`] bound resources to /// manage their lifetime. /// /// [`Device`] bound resources should be freed when either the resource goes out of scope or the /// [`Device`] is unbound respectively, depending on what happens first. /// /// To achieve that [`Devres`] registers a devres callback on creation, which is called once the /// [`Device`] is unbound, revoking access to the encapsulated resource (see also [`Revocable`]). /// /// After the [`Devres`] has been unbound it is not possible to access the encapsulated resource /// anymore. /// /// [`Devres`] users should make sure to simply free the corresponding backing resource in `T`'s /// [`Drop`] implementation. /// /// # Example /// /// ```no_run /// # use kernel::{bindings, c_str, device::Device, devres::Devres, io::{Io, IoRaw}}; /// # use core::ops::Deref; /// /// // See also [`pci::Bar`] for a real example. /// struct IoMem(IoRaw); /// /// impl IoMem { /// /// # Safety /// /// /// /// [`paddr`, `paddr` + `SIZE`) must be a valid MMIO region that is mappable into the CPUs /// /// virtual address space. /// unsafe fn new(paddr: usize) -> Result{ /// // SAFETY: By the safety requirements of this function [`paddr`, `paddr` + `SIZE`) is /// // valid for `ioremap`. /// let addr = unsafe { bindings::ioremap(paddr as _, SIZE as _) }; /// if addr.is_null() { /// return Err(ENOMEM); /// } /// /// Ok(IoMem(IoRaw::new(addr as _, SIZE)?)) /// } /// } /// /// impl Drop for IoMem { /// fn drop(&mut self) { /// // SAFETY: `self.0.addr()` is guaranteed to be properly mapped by `Self::new`. /// unsafe { bindings::iounmap(self.0.addr() as _); }; /// } /// } /// /// impl Deref for IoMem { /// type Target = Io; /// /// fn deref(&self) -> &Self::Target { /// // SAFETY: The memory range stored in `self` has been properly mapped in `Self::new`. /// unsafe { Io::from_raw(&self.0) } /// } /// } /// # fn no_run() -> Result<(), Error> { /// # // SAFETY: Invalid usage; just for the example to get an `ARef` instance. /// # let dev = unsafe { Device::get_device(core::ptr::null_mut()) }; /// /// // SAFETY: Invalid usage for example purposes. /// let iomem = unsafe { IoMem::<{ core::mem::size_of::() }>::new(0xBAAAAAAD)? }; /// let devres = Devres::new(&dev, iomem, GFP_KERNEL)?; /// /// let res = devres.try_access().ok_or(ENXIO)?; /// res.writel(0x42, 0x0); /// # Ok(()) /// # } /// ``` pub struct Devres(Arc>); impl DevresInner { fn new(dev: &Device, data: T, flags: Flags) -> Result>> { let inner = Arc::pin_init( pin_init!( DevresInner { dev: dev.into(), callback: Self::devres_callback, data <- Revocable::new(data), }), flags, )?; // Convert `Arc` into a raw pointer and make devres own this reference until // `Self::devres_callback` is called. let data = inner.clone().into_raw(); // SAFETY: `devm_add_action` guarantees to call `Self::devres_callback` once `dev` is // detached. let ret = unsafe { bindings::devm_add_action(dev.as_raw(), Some(inner.callback), data as _) }; if ret != 0 { // SAFETY: We just created another reference to `inner` in order to pass it to // `bindings::devm_add_action`. If `bindings::devm_add_action` fails, we have to drop // this reference accordingly. let _ = unsafe { Arc::from_raw(data) }; return Err(Error::from_errno(ret)); } Ok(inner) } fn as_ptr(&self) -> *const Self { self as _ } fn remove_action(this: &Arc) { // SAFETY: // - `self.inner.dev` is a valid `Device`, // - the `action` and `data` pointers are the exact same ones as given to devm_add_action() // previously, // - `self` is always valid, even if the action has been released already. let ret = unsafe { bindings::devm_remove_action_nowarn( this.dev.as_raw(), Some(this.callback), this.as_ptr() as _, ) }; if ret == 0 { // SAFETY: We leaked an `Arc` reference to devm_add_action() in `DevresInner::new`; if // devm_remove_action_nowarn() was successful we can (and have to) claim back ownership // of this reference. let _ = unsafe { Arc::from_raw(this.as_ptr()) }; } } #[allow(clippy::missing_safety_doc)] unsafe extern "C" fn devres_callback(ptr: *mut kernel::ffi::c_void) { let ptr = ptr as *mut DevresInner; // Devres owned this memory; now that we received the callback, drop the `Arc` and hence the // reference. // SAFETY: Safe, since we leaked an `Arc` reference to devm_add_action() in // `DevresInner::new`. let inner = unsafe { Arc::from_raw(ptr) }; inner.data.revoke(); } } impl Devres { /// Creates a new [`Devres`] instance of the given `data`. The `data` encapsulated within the /// returned `Devres` instance' `data` will be revoked once the device is detached. pub fn new(dev: &Device, data: T, flags: Flags) -> Result { let inner = DevresInner::new(dev, data, flags)?; Ok(Devres(inner)) } /// Same as [`Devres::new`], but does not return a `Devres` instance. Instead the given `data` /// is owned by devres and will be revoked / dropped, once the device is detached. pub fn new_foreign_owned(dev: &Device, data: T, flags: Flags) -> Result { let _ = DevresInner::new(dev, data, flags)?; Ok(()) } } impl Deref for Devres { type Target = Revocable; fn deref(&self) -> &Self::Target { &self.0.data } } impl Drop for Devres { fn drop(&mut self) { DevresInner::remove_action(&self.0); } }