| // SPDX-License-Identifier: GPL-2.0 |
| |
| //! Crate for all kernel procedural macros. |
| |
| // When fixdep scans this, it will find this string `CONFIG_RUSTC_VERSION_TEXT` |
| // and thus add a dependency on `include/config/RUSTC_VERSION_TEXT`, which is |
| // touched by Kconfig when the version string from the compiler changes. |
| |
| #[macro_use] |
| mod quote; |
| mod concat_idents; |
| mod helpers; |
| mod module; |
| mod paste; |
| mod pin_data; |
| mod pinned_drop; |
| mod vtable; |
| mod zeroable; |
| |
| use proc_macro::TokenStream; |
| |
| /// Declares a kernel module. |
| /// |
| /// The `type` argument should be a type which implements the [`Module`] |
| /// trait. Also accepts various forms of kernel metadata. |
| /// |
| /// C header: [`include/linux/moduleparam.h`](srctree/include/linux/moduleparam.h) |
| /// |
| /// [`Module`]: ../kernel/trait.Module.html |
| /// |
| /// # Examples |
| /// |
| /// ```ignore |
| /// use kernel::prelude::*; |
| /// |
| /// module!{ |
| /// type: MyModule, |
| /// name: "my_kernel_module", |
| /// author: "Rust for Linux Contributors", |
| /// description: "My very own kernel module!", |
| /// license: "GPL", |
| /// alias: ["alternate_module_name"], |
| /// } |
| /// |
| /// struct MyModule; |
| /// |
| /// impl kernel::Module for MyModule { |
| /// fn init() -> Result<Self> { |
| /// // If the parameter is writeable, then the kparam lock must be |
| /// // taken to read the parameter: |
| /// { |
| /// let lock = THIS_MODULE.kernel_param_lock(); |
| /// pr_info!("i32 param is: {}\n", writeable_i32.read(&lock)); |
| /// } |
| /// // If the parameter is read only, it can be read without locking |
| /// // the kernel parameters: |
| /// pr_info!("i32 param is: {}\n", my_i32.read()); |
| /// Ok(Self) |
| /// } |
| /// } |
| /// ``` |
| /// |
| /// ## Firmware |
| /// |
| /// The following example shows how to declare a kernel module that needs |
| /// to load binary firmware files. You need to specify the file names of |
| /// the firmware in the `firmware` field. The information is embedded |
| /// in the `modinfo` section of the kernel module. For example, a tool to |
| /// build an initramfs uses this information to put the firmware files into |
| /// the initramfs image. |
| /// |
| /// ```ignore |
| /// use kernel::prelude::*; |
| /// |
| /// module!{ |
| /// type: MyDeviceDriverModule, |
| /// name: "my_device_driver_module", |
| /// author: "Rust for Linux Contributors", |
| /// description: "My device driver requires firmware", |
| /// license: "GPL", |
| /// firmware: ["my_device_firmware1.bin", "my_device_firmware2.bin"], |
| /// } |
| /// |
| /// struct MyDeviceDriverModule; |
| /// |
| /// impl kernel::Module for MyDeviceDriverModule { |
| /// fn init() -> Result<Self> { |
| /// Ok(Self) |
| /// } |
| /// } |
| /// ``` |
| /// |
| /// # Supported argument types |
| /// - `type`: type which implements the [`Module`] trait (required). |
| /// - `name`: ASCII string literal of the name of the kernel module (required). |
| /// - `author`: string literal of the author of the kernel module. |
| /// - `description`: string literal of the description of the kernel module. |
| /// - `license`: ASCII string literal of the license of the kernel module (required). |
| /// - `alias`: array of ASCII string literals of the alias names of the kernel module. |
| /// - `firmware`: array of ASCII string literals of the firmware files of |
| /// the kernel module. |
| #[proc_macro] |
| pub fn module(ts: TokenStream) -> TokenStream { |
| module::module(ts) |
| } |
| |
| /// Declares or implements a vtable trait. |
| /// |
| /// Linux's use of pure vtables is very close to Rust traits, but they differ |
| /// in how unimplemented functions are represented. In Rust, traits can provide |
| /// default implementation for all non-required methods (and the default |
| /// implementation could just return `Error::EINVAL`); Linux typically use C |
| /// `NULL` pointers to represent these functions. |
| /// |
| /// This attribute closes that gap. A trait can be annotated with the |
| /// `#[vtable]` attribute. Implementers of the trait will then also have to |
| /// annotate the trait with `#[vtable]`. This attribute generates a `HAS_*` |
| /// associated constant bool for each method in the trait that is set to true if |
| /// the implementer has overridden the associated method. |
| /// |
| /// For a trait method to be optional, it must have a default implementation. |
| /// This is also the case for traits annotated with `#[vtable]`, but in this |
| /// case the default implementation will never be executed. The reason for this |
| /// is that the functions will be called through function pointers installed in |
| /// C side vtables. When an optional method is not implemented on a `#[vtable]` |
| /// trait, a NULL entry is installed in the vtable. Thus the default |
| /// implementation is never called. Since these traits are not designed to be |
| /// used on the Rust side, it should not be possible to call the default |
| /// implementation. This is done to ensure that we call the vtable methods |
| /// through the C vtable, and not through the Rust vtable. Therefore, the |
| /// default implementation should call `kernel::build_error`, which prevents |
| /// calls to this function at compile time: |
| /// |
| /// ```compile_fail |
| /// # use kernel::error::VTABLE_DEFAULT_ERROR; |
| /// kernel::build_error(VTABLE_DEFAULT_ERROR) |
| /// ``` |
| /// |
| /// Note that you might need to import [`kernel::error::VTABLE_DEFAULT_ERROR`]. |
| /// |
| /// This macro should not be used when all functions are required. |
| /// |
| /// # Examples |
| /// |
| /// ```ignore |
| /// use kernel::error::VTABLE_DEFAULT_ERROR; |
| /// use kernel::prelude::*; |
| /// |
| /// // Declares a `#[vtable]` trait |
| /// #[vtable] |
| /// pub trait Operations: Send + Sync + Sized { |
| /// fn foo(&self) -> Result<()> { |
| /// kernel::build_error(VTABLE_DEFAULT_ERROR) |
| /// } |
| /// |
| /// fn bar(&self) -> Result<()> { |
| /// kernel::build_error(VTABLE_DEFAULT_ERROR) |
| /// } |
| /// } |
| /// |
| /// struct Foo; |
| /// |
| /// // Implements the `#[vtable]` trait |
| /// #[vtable] |
| /// impl Operations for Foo { |
| /// fn foo(&self) -> Result<()> { |
| /// # Err(EINVAL) |
| /// // ... |
| /// } |
| /// } |
| /// |
| /// assert_eq!(<Foo as Operations>::HAS_FOO, true); |
| /// assert_eq!(<Foo as Operations>::HAS_BAR, false); |
| /// ``` |
| /// |
| /// [`kernel::error::VTABLE_DEFAULT_ERROR`]: ../kernel/error/constant.VTABLE_DEFAULT_ERROR.html |
| #[proc_macro_attribute] |
| pub fn vtable(attr: TokenStream, ts: TokenStream) -> TokenStream { |
| vtable::vtable(attr, ts) |
| } |
| |
| /// Concatenate two identifiers. |
| /// |
| /// This is useful in macros that need to declare or reference items with names |
| /// starting with a fixed prefix and ending in a user specified name. The resulting |
| /// identifier has the span of the second argument. |
| /// |
| /// # Examples |
| /// |
| /// ```ignore |
| /// use kernel::macro::concat_idents; |
| /// |
| /// macro_rules! pub_no_prefix { |
| /// ($prefix:ident, $($newname:ident),+) => { |
| /// $(pub(crate) const $newname: u32 = kernel::macros::concat_idents!($prefix, $newname);)+ |
| /// }; |
| /// } |
| /// |
| /// pub_no_prefix!( |
| /// binder_driver_return_protocol_, |
| /// BR_OK, |
| /// BR_ERROR, |
| /// BR_TRANSACTION, |
| /// BR_REPLY, |
| /// BR_DEAD_REPLY, |
| /// BR_TRANSACTION_COMPLETE, |
| /// BR_INCREFS, |
| /// BR_ACQUIRE, |
| /// BR_RELEASE, |
| /// BR_DECREFS, |
| /// BR_NOOP, |
| /// BR_SPAWN_LOOPER, |
| /// BR_DEAD_BINDER, |
| /// BR_CLEAR_DEATH_NOTIFICATION_DONE, |
| /// BR_FAILED_REPLY |
| /// ); |
| /// |
| /// assert_eq!(BR_OK, binder_driver_return_protocol_BR_OK); |
| /// ``` |
| #[proc_macro] |
| pub fn concat_idents(ts: TokenStream) -> TokenStream { |
| concat_idents::concat_idents(ts) |
| } |
| |
| /// Used to specify the pinning information of the fields of a struct. |
| /// |
| /// This is somewhat similar in purpose as |
| /// [pin-project-lite](https://crates.io/crates/pin-project-lite). |
| /// Place this macro on a struct definition and then `#[pin]` in front of the attributes of each |
| /// field you want to structurally pin. |
| /// |
| /// This macro enables the use of the [`pin_init!`] macro. When pin-initializing a `struct`, |
| /// then `#[pin]` directs the type of initializer that is required. |
| /// |
| /// If your `struct` implements `Drop`, then you need to add `PinnedDrop` as arguments to this |
| /// macro, and change your `Drop` implementation to `PinnedDrop` annotated with |
| /// `#[`[`macro@pinned_drop`]`]`, since dropping pinned values requires extra care. |
| /// |
| /// # Examples |
| /// |
| /// ```rust,ignore |
| /// #[pin_data] |
| /// struct DriverData { |
| /// #[pin] |
| /// queue: Mutex<Vec<Command>>, |
| /// buf: Box<[u8; 1024 * 1024]>, |
| /// } |
| /// ``` |
| /// |
| /// ```rust,ignore |
| /// #[pin_data(PinnedDrop)] |
| /// struct DriverData { |
| /// #[pin] |
| /// queue: Mutex<Vec<Command>>, |
| /// buf: Box<[u8; 1024 * 1024]>, |
| /// raw_info: *mut Info, |
| /// } |
| /// |
| /// #[pinned_drop] |
| /// impl PinnedDrop for DriverData { |
| /// fn drop(self: Pin<&mut Self>) { |
| /// unsafe { bindings::destroy_info(self.raw_info) }; |
| /// } |
| /// } |
| /// ``` |
| /// |
| /// [`pin_init!`]: ../kernel/macro.pin_init.html |
| // ^ cannot use direct link, since `kernel` is not a dependency of `macros`. |
| #[proc_macro_attribute] |
| pub fn pin_data(inner: TokenStream, item: TokenStream) -> TokenStream { |
| pin_data::pin_data(inner, item) |
| } |
| |
| /// Used to implement `PinnedDrop` safely. |
| /// |
| /// Only works on structs that are annotated via `#[`[`macro@pin_data`]`]`. |
| /// |
| /// # Examples |
| /// |
| /// ```rust,ignore |
| /// #[pin_data(PinnedDrop)] |
| /// struct DriverData { |
| /// #[pin] |
| /// queue: Mutex<Vec<Command>>, |
| /// buf: Box<[u8; 1024 * 1024]>, |
| /// raw_info: *mut Info, |
| /// } |
| /// |
| /// #[pinned_drop] |
| /// impl PinnedDrop for DriverData { |
| /// fn drop(self: Pin<&mut Self>) { |
| /// unsafe { bindings::destroy_info(self.raw_info) }; |
| /// } |
| /// } |
| /// ``` |
| #[proc_macro_attribute] |
| pub fn pinned_drop(args: TokenStream, input: TokenStream) -> TokenStream { |
| pinned_drop::pinned_drop(args, input) |
| } |
| |
| /// Paste identifiers together. |
| /// |
| /// Within the `paste!` macro, identifiers inside `[<` and `>]` are concatenated together to form a |
| /// single identifier. |
| /// |
| /// This is similar to the [`paste`] crate, but with pasting feature limited to identifiers and |
| /// literals (lifetimes and documentation strings are not supported). There is a difference in |
| /// supported modifiers as well. |
| /// |
| /// # Example |
| /// |
| /// ```ignore |
| /// use kernel::macro::paste; |
| /// |
| /// macro_rules! pub_no_prefix { |
| /// ($prefix:ident, $($newname:ident),+) => { |
| /// paste! { |
| /// $(pub(crate) const $newname: u32 = [<$prefix $newname>];)+ |
| /// } |
| /// }; |
| /// } |
| /// |
| /// pub_no_prefix!( |
| /// binder_driver_return_protocol_, |
| /// BR_OK, |
| /// BR_ERROR, |
| /// BR_TRANSACTION, |
| /// BR_REPLY, |
| /// BR_DEAD_REPLY, |
| /// BR_TRANSACTION_COMPLETE, |
| /// BR_INCREFS, |
| /// BR_ACQUIRE, |
| /// BR_RELEASE, |
| /// BR_DECREFS, |
| /// BR_NOOP, |
| /// BR_SPAWN_LOOPER, |
| /// BR_DEAD_BINDER, |
| /// BR_CLEAR_DEATH_NOTIFICATION_DONE, |
| /// BR_FAILED_REPLY |
| /// ); |
| /// |
| /// assert_eq!(BR_OK, binder_driver_return_protocol_BR_OK); |
| /// ``` |
| /// |
| /// # Modifiers |
| /// |
| /// For each identifier, it is possible to attach one or multiple modifiers to |
| /// it. |
| /// |
| /// Currently supported modifiers are: |
| /// * `span`: change the span of concatenated identifier to the span of the specified token. By |
| /// default the span of the `[< >]` group is used. |
| /// * `lower`: change the identifier to lower case. |
| /// * `upper`: change the identifier to upper case. |
| /// |
| /// ```ignore |
| /// use kernel::macro::paste; |
| /// |
| /// macro_rules! pub_no_prefix { |
| /// ($prefix:ident, $($newname:ident),+) => { |
| /// kernel::macros::paste! { |
| /// $(pub(crate) const fn [<$newname:lower:span>]: u32 = [<$prefix $newname:span>];)+ |
| /// } |
| /// }; |
| /// } |
| /// |
| /// pub_no_prefix!( |
| /// binder_driver_return_protocol_, |
| /// BR_OK, |
| /// BR_ERROR, |
| /// BR_TRANSACTION, |
| /// BR_REPLY, |
| /// BR_DEAD_REPLY, |
| /// BR_TRANSACTION_COMPLETE, |
| /// BR_INCREFS, |
| /// BR_ACQUIRE, |
| /// BR_RELEASE, |
| /// BR_DECREFS, |
| /// BR_NOOP, |
| /// BR_SPAWN_LOOPER, |
| /// BR_DEAD_BINDER, |
| /// BR_CLEAR_DEATH_NOTIFICATION_DONE, |
| /// BR_FAILED_REPLY |
| /// ); |
| /// |
| /// assert_eq!(br_ok(), binder_driver_return_protocol_BR_OK); |
| /// ``` |
| /// |
| /// # Literals |
| /// |
| /// Literals can also be concatenated with other identifiers: |
| /// |
| /// ```ignore |
| /// macro_rules! create_numbered_fn { |
| /// ($name:literal, $val:literal) => { |
| /// kernel::macros::paste! { |
| /// fn [<some_ $name _fn $val>]() -> u32 { $val } |
| /// } |
| /// }; |
| /// } |
| /// |
| /// create_numbered_fn!("foo", 100); |
| /// |
| /// assert_eq!(some_foo_fn100(), 100) |
| /// ``` |
| /// |
| /// [`paste`]: https://docs.rs/paste/ |
| #[proc_macro] |
| pub fn paste(input: TokenStream) -> TokenStream { |
| let mut tokens = input.into_iter().collect(); |
| paste::expand(&mut tokens); |
| tokens.into_iter().collect() |
| } |
| |
| /// Derives the [`Zeroable`] trait for the given struct. |
| /// |
| /// This can only be used for structs where every field implements the [`Zeroable`] trait. |
| /// |
| /// # Examples |
| /// |
| /// ```rust,ignore |
| /// #[derive(Zeroable)] |
| /// pub struct DriverData { |
| /// id: i64, |
| /// buf_ptr: *mut u8, |
| /// len: usize, |
| /// } |
| /// ``` |
| #[proc_macro_derive(Zeroable)] |
| pub fn derive_zeroable(input: TokenStream) -> TokenStream { |
| zeroable::derive(input) |
| } |