// SPDX-License-Identifier: GPL-2.0 //! Firmware abstraction //! //! C header: [`include/linux/firmware.h`](srctree/include/linux/firmware.h) use crate::{bindings, device::Device, error::Error, error::Result, str::CStr}; use core::ptr::NonNull; /// # Invariants /// /// One of the following: `bindings::request_firmware`, `bindings::firmware_request_nowarn`, /// `bindings::firmware_request_platform`, `bindings::request_firmware_direct`. struct FwFunc( unsafe extern "C" fn(*mut *const bindings::firmware, *const i8, *mut bindings::device) -> i32, ); impl FwFunc { fn request() -> Self { Self(bindings::request_firmware) } fn request_nowarn() -> Self { Self(bindings::firmware_request_nowarn) } } /// Abstraction around a C `struct firmware`. /// /// This is a simple abstraction around the C firmware API. Just like with the C API, firmware can /// be requested. Once requested the abstraction provides direct access to the firmware buffer as /// `&[u8]`. The firmware is released once [`Firmware`] is dropped. /// /// # Invariants /// /// The pointer is valid, and has ownership over the instance of `struct firmware`. /// /// The `Firmware`'s backing buffer is not modified. /// /// # Examples /// /// ```no_run /// # use kernel::{c_str, device::Device, firmware::Firmware}; /// /// # fn no_run() -> Result<(), Error> { /// # // SAFETY: *NOT* safe, just for the example to get an `ARef` instance /// # let dev = unsafe { Device::get_device(core::ptr::null_mut()) }; /// /// let fw = Firmware::request(c_str!("path/to/firmware.bin"), &dev)?; /// let blob = fw.data(); /// /// # Ok(()) /// # } /// ``` pub struct Firmware(NonNull); impl Firmware { fn request_internal(name: &CStr, dev: &Device, func: FwFunc) -> Result { let mut fw: *mut bindings::firmware = core::ptr::null_mut(); let pfw: *mut *mut bindings::firmware = &mut fw; // SAFETY: `pfw` is a valid pointer to a NULL initialized `bindings::firmware` pointer. // `name` and `dev` are valid as by their type invariants. let ret = unsafe { func.0(pfw as _, name.as_char_ptr(), dev.as_raw()) }; if ret != 0 { return Err(Error::from_errno(ret)); } // SAFETY: `func` not bailing out with a non-zero error code, guarantees that `fw` is a // valid pointer to `bindings::firmware`. Ok(Firmware(unsafe { NonNull::new_unchecked(fw) })) } /// Send a firmware request and wait for it. See also `bindings::request_firmware`. pub fn request(name: &CStr, dev: &Device) -> Result { Self::request_internal(name, dev, FwFunc::request()) } /// Send a request for an optional firmware module. See also /// `bindings::firmware_request_nowarn`. pub fn request_nowarn(name: &CStr, dev: &Device) -> Result { Self::request_internal(name, dev, FwFunc::request_nowarn()) } fn as_raw(&self) -> *mut bindings::firmware { self.0.as_ptr() } /// Returns the size of the requested firmware in bytes. pub fn size(&self) -> usize { // SAFETY: `self.as_raw()` is valid by the type invariant. unsafe { (*self.as_raw()).size } } /// Returns the requested firmware as `&[u8]`. pub fn data(&self) -> &[u8] { // SAFETY: `self.as_raw()` is valid by the type invariant. Additionally, // `bindings::firmware` guarantees, if successfully requested, that // `bindings::firmware::data` has a size of `bindings::firmware::size` bytes. unsafe { core::slice::from_raw_parts((*self.as_raw()).data, self.size()) } } } impl Drop for Firmware { fn drop(&mut self) { // SAFETY: `self.as_raw()` is valid by the type invariant. unsafe { bindings::release_firmware(self.as_raw()) }; } } // SAFETY: `Firmware` only holds a pointer to a C `struct firmware`, which is safe to be used from // any thread. unsafe impl Send for Firmware {} // SAFETY: `Firmware` only holds a pointer to a C `struct firmware`, references to which are safe to // be used from any thread. unsafe impl Sync for Firmware {}