rust/kernel/device_id.rs - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0

 //! Generic implementation of device IDs.
 //!
 //! Each bus / subsystem that matches device and driver through a bus / subsystem specific ID is
 //! expected to implement [`RawDeviceId`].

 use core::mem::MaybeUninit;

 /// Marker trait to indicate a Rust device ID type represents a corresponding C device ID type.
 ///
 /// This is meant to be implemented by buses/subsystems so that they can use [`IdTable`] to
 /// guarantee (at compile-time) zero-termination of device id tables provided by drivers.
 ///
 /// # Safety
 ///
 /// Implementers must ensure that `Self` is layout-compatible with [`RawDeviceId::RawType`];
 /// i.e. it's safe to transmute to `RawDeviceId`.
 ///
 /// This requirement is needed so `IdArray::new` can convert `Self` to `RawType` when building
 /// the ID table.
 ///
 /// Ideally, this should be achieved using a const function that does conversion instead of
 /// transmute; however, const trait functions relies on `const_trait_impl` unstable feature,
 /// which is broken/gone in Rust 1.73.
 pub unsafe trait RawDeviceId {
     /// The raw type that holds the device id.
     ///
     /// Id tables created from [`Self`] are going to hold this type in its zero-terminated array.
     type RawType: Copy;
 }

 /// Extension trait for [`RawDeviceId`] for devices that embed an index or context value.
 ///
 /// This is typically used when the device ID struct includes a field like `driver_data`
 /// that is used to store a pointer-sized value (e.g., an index or context pointer).
 ///
 /// # Safety
 ///
 /// Implementers must ensure that `DRIVER_DATA_OFFSET` is the correct offset (in bytes) to
 /// the context/data field (e.g., the `driver_data` field) within the raw device ID structure.
 /// This field must be correctly sized to hold a `usize`.
 ///
 /// Ideally, the data should be added during `Self` to `RawType` conversion,
 /// but there's currently no way to do it when using traits in const.
 pub unsafe trait RawDeviceIdIndex: RawDeviceId {
     /// The offset (in bytes) to the context/data field in the raw device ID.
     const DRIVER_DATA_OFFSET: usize;

     /// The index stored at `DRIVER_DATA_OFFSET` of the implementor of the [`RawDeviceIdIndex`]
     /// trait.
     fn index(&self) -> usize;
 }

 /// A zero-terminated device id array.
 #[repr(C)]
 pub struct RawIdArray<T: RawDeviceId, const N: usize> {
     ids: [T::RawType; N],
     sentinel: MaybeUninit<T::RawType>,
 }

 impl<T: RawDeviceId, const N: usize> RawIdArray<T, N> {
     #[doc(hidden)]
     pub const fn size(&self) -> usize {
         core::mem::size_of::<Self>()
     }
 }

 /// A zero-terminated device id array, followed by context data.
 #[repr(C)]
 pub struct IdArray<T: RawDeviceId, U, const N: usize> {
     raw_ids: RawIdArray<T, N>,
     id_infos: [U; N],
 }

 impl<T: RawDeviceId, U, const N: usize> IdArray<T, U, N> {
     /// Creates a new instance of the array.
     ///
     /// The contents are derived from the given identifiers and context information.
     ///
     /// # Safety
     ///
     /// `data_offset` as `None` is always safe.
     /// If `data_offset` is `Some(data_offset)`, then:
     /// - `data_offset` must be the correct offset (in bytes) to the context/data field
     ///   (e.g., the `driver_data` field) within the raw device ID structure.
     /// - The field at `data_offset` must be correctly sized to hold a `usize`.
     const unsafe fn build(ids: [(T, U); N], data_offset: Option<usize>) -> Self {
         let mut raw_ids = [const { MaybeUninit::<T::RawType>::uninit() }; N];
         let mut infos = [const { MaybeUninit::uninit() }; N];

         let mut i = 0usize;
         while i < N {
             // SAFETY: by the safety requirement of `RawDeviceId`, we're guaranteed that `T` is
             // layout-wise compatible with `RawType`.
             raw_ids[i] = unsafe { core::mem::transmute_copy(&ids[i].0) };
             if let Some(data_offset) = data_offset {
                 // SAFETY: by the safety requirement of this function, this would be effectively
                 // `raw_ids[i].driver_data = i;`.
                 unsafe {
                     raw_ids[i]
                         .as_mut_ptr()
                         .byte_add(data_offset)
                         .cast::<usize>()
                         .write(i);
                 }
             }

             // SAFETY: this is effectively a move: `infos[i] = ids[i].1`. We make a copy here but
             // later forget `ids`.
             infos[i] = MaybeUninit::new(unsafe { core::ptr::read(&ids[i].1) });
             i += 1;
         }

         core::mem::forget(ids);

         Self {
             raw_ids: RawIdArray {
                 // SAFETY: this is effectively `array_assume_init`, which is unstable, so we use
                 // `transmute_copy` instead. We have initialized all elements of `raw_ids` so this
                 // `array_assume_init` is safe.
                 ids: unsafe { core::mem::transmute_copy(&raw_ids) },
                 sentinel: MaybeUninit::zeroed(),
             },
             // SAFETY: We have initialized all elements of `infos` so this `array_assume_init` is
             // safe.
             id_infos: unsafe { core::mem::transmute_copy(&infos) },
         }
     }

     /// Creates a new instance of the array without writing index values.
     ///
     /// The contents are derived from the given identifiers and context information.
     /// If the device implements [`RawDeviceIdIndex`], consider using [`IdArray::new`] instead.
     pub const fn new_without_index(ids: [(T, U); N]) -> Self {
         // SAFETY: Calling `Self::build` with `offset = None` is always safe,
         // because no raw memory writes are performed in this case.
         unsafe { Self::build(ids, None) }
     }

     /// Reference to the contained [`RawIdArray`].
     pub const fn raw_ids(&self) -> &RawIdArray<T, N> {
         &self.raw_ids
     }
 }

 impl<T: RawDeviceId + RawDeviceIdIndex, U, const N: usize> IdArray<T, U, N> {
     /// Creates a new instance of the array.
     ///
     /// The contents are derived from the given identifiers and context information.
     pub const fn new(ids: [(T, U); N]) -> Self {
         // SAFETY: by the safety requirement of `RawDeviceIdIndex`,
         // `T::DRIVER_DATA_OFFSET` is guaranteed to be the correct offset (in bytes) to
         // a field within `T::RawType`.
         unsafe { Self::build(ids, Some(T::DRIVER_DATA_OFFSET)) }
     }
 }

 /// A device id table.
 ///
 /// This trait is only implemented by `IdArray`.
 ///
 /// The purpose of this trait is to allow `&'static dyn IdArray<T, U>` to be in context when `N` in
 /// `IdArray` doesn't matter.
 pub trait IdTable<T: RawDeviceId, U> {
     /// Obtain the pointer to the ID table.
     fn as_ptr(&self) -> *const T::RawType;

     /// Obtain the pointer to the bus specific device ID from an index.
     fn id(&self, index: usize) -> &T::RawType;

     /// Obtain the pointer to the driver-specific information from an index.
     fn info(&self, index: usize) -> &U;
 }

 impl<T: RawDeviceId, U, const N: usize> IdTable<T, U> for IdArray<T, U, N> {
     fn as_ptr(&self) -> *const T::RawType {
         // This cannot be `self.ids.as_ptr()`, as the return pointer must have correct provenance
         // to access the sentinel.
         core::ptr::from_ref(self).cast()
     }

     fn id(&self, index: usize) -> &T::RawType {
         &self.raw_ids.ids[index]
     }

     fn info(&self, index: usize) -> &U {
         &self.id_infos[index]
     }
 }

 /// Create device table alias for modpost.
 #[macro_export]
 macro_rules! module_device_table {
     ($table_type: literal, $module_table_name:ident, $table_name:ident) => {
         #[rustfmt::skip]
         #[export_name =
             concat!("__mod_device_table__", $table_type,
                     "__", module_path!(),
                     "_", line!(),
                     "_", stringify!($table_name))
         ]
         static $module_table_name: [::core::mem::MaybeUninit<u8>; $table_name.raw_ids().size()] =
             unsafe { ::core::mem::transmute_copy($table_name.raw_ids()) };
     };
 }
	// SPDX-License-Identifier: GPL-2.0

	//! Generic implementation of device IDs.
	//!
	//! Each bus / subsystem that matches device and driver through a bus / subsystem specific ID is
	//! expected to implement [`RawDeviceId`].

	use core::mem::MaybeUninit;

	/// Marker trait to indicate a Rust device ID type represents a corresponding C device ID type.
	///
	/// This is meant to be implemented by buses/subsystems so that they can use [`IdTable`] to
	/// guarantee (at compile-time) zero-termination of device id tables provided by drivers.
	///
	/// # Safety
	///
	/// Implementers must ensure that `Self` is layout-compatible with [`RawDeviceId::RawType`];
	/// i.e. it's safe to transmute to `RawDeviceId`.
	///
	/// This requirement is needed so `IdArray::new` can convert `Self` to `RawType` when building
	/// the ID table.
	///
	/// Ideally, this should be achieved using a const function that does conversion instead of
	/// transmute; however, const trait functions relies on `const_trait_impl` unstable feature,
	/// which is broken/gone in Rust 1.73.
	pub unsafe trait RawDeviceId {
	/// The raw type that holds the device id.
	///
	/// Id tables created from [`Self`] are going to hold this type in its zero-terminated array.
	type RawType: Copy;
	}

	/// Extension trait for [`RawDeviceId`] for devices that embed an index or context value.
	///
	/// This is typically used when the device ID struct includes a field like `driver_data`
	/// that is used to store a pointer-sized value (e.g., an index or context pointer).
	///
	/// # Safety
	///
	/// Implementers must ensure that `DRIVER_DATA_OFFSET` is the correct offset (in bytes) to
	/// the context/data field (e.g., the `driver_data` field) within the raw device ID structure.
	/// This field must be correctly sized to hold a `usize`.
	///
	/// Ideally, the data should be added during `Self` to `RawType` conversion,
	/// but there's currently no way to do it when using traits in const.
	pub unsafe trait RawDeviceIdIndex: RawDeviceId {
	/// The offset (in bytes) to the context/data field in the raw device ID.
	const DRIVER_DATA_OFFSET: usize;

	/// The index stored at `DRIVER_DATA_OFFSET` of the implementor of the [`RawDeviceIdIndex`]
	/// trait.
	fn index(&self) -> usize;
	}

	/// A zero-terminated device id array.
	#[repr(C)]
	pub struct RawIdArray<T: RawDeviceId, const N: usize> {
	ids: [T::RawType; N],
	sentinel: MaybeUninit<T::RawType>,
	}

	impl<T: RawDeviceId, const N: usize> RawIdArray<T, N> {
	#[doc(hidden)]
	pub const fn size(&self) -> usize {
	core::mem::size_of::<Self>()
	}
	}

	/// A zero-terminated device id array, followed by context data.
	#[repr(C)]
	pub struct IdArray<T: RawDeviceId, U, const N: usize> {
	raw_ids: RawIdArray<T, N>,
	id_infos: [U; N],
	}

	impl<T: RawDeviceId, U, const N: usize> IdArray<T, U, N> {
	/// Creates a new instance of the array.
	///
	/// The contents are derived from the given identifiers and context information.
	///
	/// # Safety
	///
	/// `data_offset` as `None` is always safe.
	/// If `data_offset` is `Some(data_offset)`, then:
	/// - `data_offset` must be the correct offset (in bytes) to the context/data field
	/// (e.g., the `driver_data` field) within the raw device ID structure.
	/// - The field at `data_offset` must be correctly sized to hold a `usize`.
	const unsafe fn build(ids: [(T, U); N], data_offset: Option<usize>) -> Self {
	let mut raw_ids = [const { MaybeUninit::<T::RawType>::uninit() }; N];
	let mut infos = [const { MaybeUninit::uninit() }; N];

	let mut i = 0usize;
	while i < N {
	// SAFETY: by the safety requirement of `RawDeviceId`, we're guaranteed that `T` is
	// layout-wise compatible with `RawType`.
	raw_ids[i] = unsafe { core::mem::transmute_copy(&ids[i].0) };
	if let Some(data_offset) = data_offset {
	// SAFETY: by the safety requirement of this function, this would be effectively
	// `raw_ids[i].driver_data = i;`.
	unsafe {
	raw_ids[i]
	.as_mut_ptr()
	.byte_add(data_offset)
	.cast::<usize>()
	.write(i);
	}
	}

	// SAFETY: this is effectively a move: `infos[i] = ids[i].1`. We make a copy here but
	// later forget `ids`.
	infos[i] = MaybeUninit::new(unsafe { core::ptr::read(&ids[i].1) });
	i += 1;
	}

	core::mem::forget(ids);

	Self {
	raw_ids: RawIdArray {
	// SAFETY: this is effectively `array_assume_init`, which is unstable, so we use
	// `transmute_copy` instead. We have initialized all elements of `raw_ids` so this
	// `array_assume_init` is safe.
	ids: unsafe { core::mem::transmute_copy(&raw_ids) },
	sentinel: MaybeUninit::zeroed(),
	},
	// SAFETY: We have initialized all elements of `infos` so this `array_assume_init` is
	// safe.
	id_infos: unsafe { core::mem::transmute_copy(&infos) },
	}
	}

	/// Creates a new instance of the array without writing index values.
	///
	/// The contents are derived from the given identifiers and context information.
	/// If the device implements [`RawDeviceIdIndex`], consider using [`IdArray::new`] instead.
	pub const fn new_without_index(ids: [(T, U); N]) -> Self {
	// SAFETY: Calling `Self::build` with `offset = None` is always safe,
	// because no raw memory writes are performed in this case.
	unsafe { Self::build(ids, None) }
	}

	/// Reference to the contained [`RawIdArray`].
	pub const fn raw_ids(&self) -> &RawIdArray<T, N> {
	&self.raw_ids
	}
	}

	impl<T: RawDeviceId + RawDeviceIdIndex, U, const N: usize> IdArray<T, U, N> {
	/// Creates a new instance of the array.
	///
	/// The contents are derived from the given identifiers and context information.
	pub const fn new(ids: [(T, U); N]) -> Self {
	// SAFETY: by the safety requirement of `RawDeviceIdIndex`,
	// `T::DRIVER_DATA_OFFSET` is guaranteed to be the correct offset (in bytes) to
	// a field within `T::RawType`.
	unsafe { Self::build(ids, Some(T::DRIVER_DATA_OFFSET)) }
	}
	}

	/// A device id table.
	///
	/// This trait is only implemented by `IdArray`.
	///
	/// The purpose of this trait is to allow `&'static dyn IdArray<T, U>` to be in context when `N` in
	/// `IdArray` doesn't matter.
	pub trait IdTable<T: RawDeviceId, U> {
	/// Obtain the pointer to the ID table.
	fn as_ptr(&self) -> *const T::RawType;

	/// Obtain the pointer to the bus specific device ID from an index.
	fn id(&self, index: usize) -> &T::RawType;

	/// Obtain the pointer to the driver-specific information from an index.
	fn info(&self, index: usize) -> &U;
	}

	impl<T: RawDeviceId, U, const N: usize> IdTable<T, U> for IdArray<T, U, N> {
	fn as_ptr(&self) -> *const T::RawType {
	// This cannot be `self.ids.as_ptr()`, as the return pointer must have correct provenance
	// to access the sentinel.
	core::ptr::from_ref(self).cast()
	}

	fn id(&self, index: usize) -> &T::RawType {
	&self.raw_ids.ids[index]
	}

	fn info(&self, index: usize) -> &U {
	&self.id_infos[index]
	}
	}

	/// Create device table alias for modpost.
	#[macro_export]
	macro_rules! module_device_table {
	($table_type: literal, $module_table_name:ident, $table_name:ident) => {
	#[rustfmt::skip]
	#[export_name =
	concat!("__mod_device_table__", $table_type,
	"__", module_path!(),
	"_", line!(),
	"_", stringify!($table_name))
	]
	static $module_table_name: [::core::mem::MaybeUninit<u8>; $table_name.raw_ids().size()] =
	unsafe { ::core::mem::transmute_copy($table_name.raw_ids()) };
	};
	}