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linux/rust/macros/module.rs
Linus Torvalds 5701725692 Merge tag 'rust-6.12' of https://github.com/Rust-for-Linux/linux 
Pull Rust updates from Miguel Ojeda:
 "Toolchain and infrastructure:

   - Support 'MITIGATION_{RETHUNK,RETPOLINE,SLS}' (which cleans up
     objtool warnings), teach objtool about 'noreturn' Rust symbols and
     mimic '___ADDRESSABLE()' for 'module_{init,exit}'. With that, we
     should be objtool-warning-free, so enable it to run for all Rust
     object files.

   - KASAN (no 'SW_TAGS'), KCFI and shadow call sanitizer support.

   - Support 'RUSTC_VERSION', including re-config and re-build on
     change.

   - Split helpers file into several files in a folder, to avoid
     conflicts in it. Eventually those files will be moved to the right
     places with the new build system. In addition, remove the need to
     manually export the symbols defined there, reusing existing
     machinery for that.

   - Relax restriction on configurations with Rust + GCC plugins to just
     the RANDSTRUCT plugin.

  'kernel' crate:

   - New 'list' module: doubly-linked linked list for use with reference
     counted values, which is heavily used by the upcoming Rust Binder.

     This includes 'ListArc' (a wrapper around 'Arc' that is guaranteed
     unique for the given ID), 'AtomicTracker' (tracks whether a
     'ListArc' exists using an atomic), 'ListLinks' (the prev/next
     pointers for an item in a linked list), 'List' (the linked list
     itself), 'Iter' (an iterator over a 'List'), 'Cursor' (a cursor
     into a 'List' that allows to remove elements), 'ListArcField' (a
     field exclusively owned by a 'ListArc'), as well as support for
     heterogeneous lists.

   - New 'rbtree' module: red-black tree abstractions used by the
     upcoming Rust Binder.

     This includes 'RBTree' (the red-black tree itself), 'RBTreeNode' (a
     node), 'RBTreeNodeReservation' (a memory reservation for a node),
     'Iter' and 'IterMut' (immutable and mutable iterators), 'Cursor'
     (bidirectional cursor that allows to remove elements), as well as
     an entry API similar to the Rust standard library one.

   - 'init' module: add 'write_[pin_]init' methods and the
     'InPlaceWrite' trait. Add the 'assert_pinned!' macro.

   - 'sync' module: implement the 'InPlaceInit' trait for 'Arc' by
     introducing an associated type in the trait.

   - 'alloc' module: add 'drop_contents' method to 'BoxExt'.

   - 'types' module: implement the 'ForeignOwnable' trait for
     'Pin<Box<T>>' and improve the trait's documentation. In addition,
     add the 'into_raw' method to the 'ARef' type.

   - 'error' module: in preparation for the upcoming Rust support for
     32-bit architectures, like arm, locally allow Clippy lint for
     those.

  Documentation:

   - https://rust.docs.kernel.org has been announced, so link to it.

   - Enable rustdoc's "jump to definition" feature, making its output a
     bit closer to the experience in a cross-referencer.

   - Debian Testing now also provides recent Rust releases (outside of
     the freeze period), so add it to the list.

  MAINTAINERS:

   - Trevor is joining as reviewer of the "RUST" entry.

  And a few other small bits"

* tag 'rust-6.12' of https://github.com/Rust-for-Linux/linux: (54 commits)
  kasan: rust: Add KASAN smoke test via UAF
  kbuild: rust: Enable KASAN support
  rust: kasan: Rust does not support KHWASAN
  kbuild: rust: Define probing macros for rustc
  kasan: simplify and clarify Makefile
  rust: cfi: add support for CFI_CLANG with Rust
  cfi: add CONFIG_CFI_ICALL_NORMALIZE_INTEGERS
  rust: support for shadow call stack sanitizer
  docs: rust: include other expressions in conditional compilation section
  kbuild: rust: replace proc macros dependency on `core.o` with the version text
  kbuild: rust: rebuild if the version text changes
  kbuild: rust: re-run Kconfig if the version text changes
  kbuild: rust: add `CONFIG_RUSTC_VERSION`
  rust: avoid `box_uninit_write` feature
  MAINTAINERS: add Trevor Gross as Rust reviewer
  rust: rbtree: add `RBTree::entry`
  rust: rbtree: add cursor
  rust: rbtree: add mutable iterator
  rust: rbtree: add iterator
  rust: rbtree: add red-black tree implementation backed by the C version
  ...
2024-09-25 10:25:40 -07:00

378 lines
14 KiB
Rust
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// SPDX-License-Identifier: GPL-2.0
use crate::helpers::*;
use proc_macro::{token_stream, Delimiter, Literal, TokenStream, TokenTree};
use std::fmt::Write;
fn expect_string_array(it: &mut token_stream::IntoIter) -> Vec<String> {
let group = expect_group(it);
assert_eq!(group.delimiter(), Delimiter::Bracket);
let mut values = Vec::new();
let mut it = group.stream().into_iter();
while let Some(val) = try_string(&mut it) {
assert!(val.is_ascii(), "Expected ASCII string");
values.push(val);
match it.next() {
Some(TokenTree::Punct(punct)) => assert_eq!(punct.as_char(), ','),
None => break,
_ => panic!("Expected ',' or end of array"),
}
}
values
}
struct ModInfoBuilder<'a> {
module: &'a str,
counter: usize,
buffer: String,
}
impl<'a> ModInfoBuilder<'a> {
fn new(module: &'a str) -> Self {
ModInfoBuilder {
module,
counter: 0,
buffer: String::new(),
}
}
fn emit_base(&mut self, field: &str, content: &str, builtin: bool) {
let string = if builtin {
// Built-in modules prefix their modinfo strings by `module.`.
format!(
"{module}.{field}={content}\0",
module = self.module,
field = field,
content = content
)
} else {
// Loadable modules' modinfo strings go as-is.
format!("{field}={content}\0", field = field, content = content)
};
write!(
&mut self.buffer,
"
{cfg}
#[doc(hidden)]
#[link_section = \".modinfo\"]
#[used]
pub static __{module}_{counter}: [u8; {length}] = *{string};
",
cfg = if builtin {
"#[cfg(not(MODULE))]"
} else {
"#[cfg(MODULE)]"
},
module = self.module.to_uppercase(),
counter = self.counter,
length = string.len(),
string = Literal::byte_string(string.as_bytes()),
)
.unwrap();
self.counter += 1;
}
fn emit_only_builtin(&mut self, field: &str, content: &str) {
self.emit_base(field, content, true)
}
fn emit_only_loadable(&mut self, field: &str, content: &str) {
self.emit_base(field, content, false)
}
fn emit(&mut self, field: &str, content: &str) {
self.emit_only_builtin(field, content);
self.emit_only_loadable(field, content);
}
}
#[derive(Debug, Default)]
struct ModuleInfo {
type_: String,
license: String,
name: String,
author: Option<String>,
description: Option<String>,
alias: Option<Vec<String>>,
firmware: Option<Vec<String>>,
}
impl ModuleInfo {
fn parse(it: &mut token_stream::IntoIter) -> Self {
let mut info = ModuleInfo::default();
const EXPECTED_KEYS: &[&str] = &[
"type",
"name",
"author",
"description",
"license",
"alias",
"firmware",
];
const REQUIRED_KEYS: &[&str] = &["type", "name", "license"];
let mut seen_keys = Vec::new();
loop {
let key = match it.next() {
Some(TokenTree::Ident(ident)) => ident.to_string(),
Some(_) => panic!("Expected Ident or end"),
None => break,
};
if seen_keys.contains(&key) {
panic!(
"Duplicated key \"{}\". Keys can only be specified once.",
key
);
}
assert_eq!(expect_punct(it), ':');
match key.as_str() {
"type" => info.type_ = expect_ident(it),
"name" => info.name = expect_string_ascii(it),
"author" => info.author = Some(expect_string(it)),
"description" => info.description = Some(expect_string(it)),
"license" => info.license = expect_string_ascii(it),
"alias" => info.alias = Some(expect_string_array(it)),
"firmware" => info.firmware = Some(expect_string_array(it)),
_ => panic!(
"Unknown key \"{}\". Valid keys are: {:?}.",
key, EXPECTED_KEYS
),
}
assert_eq!(expect_punct(it), ',');
seen_keys.push(key);
}
expect_end(it);
for key in REQUIRED_KEYS {
if !seen_keys.iter().any(|e| e == key) {
panic!("Missing required key \"{}\".", key);
}
}
let mut ordered_keys: Vec<&str> = Vec::new();
for key in EXPECTED_KEYS {
if seen_keys.iter().any(|e| e == key) {
ordered_keys.push(key);
}
}
if seen_keys != ordered_keys {
panic!(
"Keys are not ordered as expected. Order them like: {:?}.",
ordered_keys
);
}
info
}
}
pub(crate) fn module(ts: TokenStream) -> TokenStream {
let mut it = ts.into_iter();
let info = ModuleInfo::parse(&mut it);
let mut modinfo = ModInfoBuilder::new(info.name.as_ref());
if let Some(author) = info.author {
modinfo.emit("author", &author);
}
if let Some(description) = info.description {
modinfo.emit("description", &description);
}
modinfo.emit("license", &info.license);
if let Some(aliases) = info.alias {
for alias in aliases {
modinfo.emit("alias", &alias);
}
}
if let Some(firmware) = info.firmware {
for fw in firmware {
modinfo.emit("firmware", &fw);
}
}
// Built-in modules also export the `file` modinfo string.
let file =
std::env::var("RUST_MODFILE").expect("Unable to fetch RUST_MODFILE environmental variable");
modinfo.emit_only_builtin("file", &file);
format!(
"
/// The module name.
///
/// Used by the printing macros, e.g. [`info!`].
const __LOG_PREFIX: &[u8] = b\"{name}\\0\";
// SAFETY: `__this_module` is constructed by the kernel at load time and will not be
// freed until the module is unloaded.
#[cfg(MODULE)]
static THIS_MODULE: kernel::ThisModule = unsafe {{
extern \"C\" {{
static __this_module: kernel::types::Opaque<kernel::bindings::module>;
}}
kernel::ThisModule::from_ptr(__this_module.get())
}};
#[cfg(not(MODULE))]
static THIS_MODULE: kernel::ThisModule = unsafe {{
kernel::ThisModule::from_ptr(core::ptr::null_mut())
}};
// Double nested modules, since then nobody can access the public items inside.
mod __module_init {{
mod __module_init {{
use super::super::{type_};
/// The \"Rust loadable module\" mark.
//
// This may be best done another way later on, e.g. as a new modinfo
// key or a new section. For the moment, keep it simple.
#[cfg(MODULE)]
#[doc(hidden)]
#[used]
static __IS_RUST_MODULE: () = ();
static mut __MOD: Option<{type_}> = None;
// Loadable modules need to export the `{{init,cleanup}}_module` identifiers.
/// # Safety
///
/// This function must not be called after module initialization, because it may be
/// freed after that completes.
#[cfg(MODULE)]
#[doc(hidden)]
#[no_mangle]
#[link_section = \".init.text\"]
pub unsafe extern \"C\" fn init_module() -> core::ffi::c_int {{
// SAFETY: This function is inaccessible to the outside due to the double
// module wrapping it. It is called exactly once by the C side via its
// unique name.
unsafe {{ __init() }}
}}
#[cfg(MODULE)]
#[doc(hidden)]
#[used]
#[link_section = \".init.data\"]
static __UNIQUE_ID___addressable_init_module: unsafe extern \"C\" fn() -> i32 = init_module;
#[cfg(MODULE)]
#[doc(hidden)]
#[no_mangle]
pub extern \"C\" fn cleanup_module() {{
// SAFETY:
// - This function is inaccessible to the outside due to the double
// module wrapping it. It is called exactly once by the C side via its
// unique name,
// - furthermore it is only called after `init_module` has returned `0`
// (which delegates to `__init`).
unsafe {{ __exit() }}
}}
#[cfg(MODULE)]
#[doc(hidden)]
#[used]
#[link_section = \".exit.data\"]
static __UNIQUE_ID___addressable_cleanup_module: extern \"C\" fn() = cleanup_module;
// Built-in modules are initialized through an initcall pointer
// and the identifiers need to be unique.
#[cfg(not(MODULE))]
#[cfg(not(CONFIG_HAVE_ARCH_PREL32_RELOCATIONS))]
#[doc(hidden)]
#[link_section = \"{initcall_section}\"]
#[used]
pub static __{name}_initcall: extern \"C\" fn() -> core::ffi::c_int = __{name}_init;
#[cfg(not(MODULE))]
#[cfg(CONFIG_HAVE_ARCH_PREL32_RELOCATIONS)]
core::arch::global_asm!(
r#\".section \"{initcall_section}\", \"a\"
__{name}_initcall:
.long __{name}_init - .
.previous
\"#
);
#[cfg(not(MODULE))]
#[doc(hidden)]
#[no_mangle]
pub extern \"C\" fn __{name}_init() -> core::ffi::c_int {{
// SAFETY: This function is inaccessible to the outside due to the double
// module wrapping it. It is called exactly once by the C side via its
// placement above in the initcall section.
unsafe {{ __init() }}
}}
#[cfg(not(MODULE))]
#[doc(hidden)]
#[no_mangle]
pub extern \"C\" fn __{name}_exit() {{
// SAFETY:
// - This function is inaccessible to the outside due to the double
// module wrapping it. It is called exactly once by the C side via its
// unique name,
// - furthermore it is only called after `__{name}_init` has returned `0`
// (which delegates to `__init`).
unsafe {{ __exit() }}
}}
/// # Safety
///
/// This function must only be called once.
unsafe fn __init() -> core::ffi::c_int {{
match <{type_} as kernel::Module>::init(&super::super::THIS_MODULE) {{
Ok(m) => {{
// SAFETY: No data race, since `__MOD` can only be accessed by this
// module and there only `__init` and `__exit` access it. These
// functions are only called once and `__exit` cannot be called
// before or during `__init`.
unsafe {{
__MOD = Some(m);
}}
return 0;
}}
Err(e) => {{
return e.to_errno();
}}
}}
}}
/// # Safety
///
/// This function must
/// - only be called once,
/// - be called after `__init` has been called and returned `0`.
unsafe fn __exit() {{
// SAFETY: No data race, since `__MOD` can only be accessed by this module
// and there only `__init` and `__exit` access it. These functions are only
// called once and `__init` was already called.
unsafe {{
// Invokes `drop()` on `__MOD`, which should be used for cleanup.
__MOD = None;
}}
}}
{modinfo}
}}
}}
",
type_ = info.type_,
name = info.name,
modinfo = modinfo.buffer,
initcall_section = ".initcall6.init"
)
.parse()
.expect("Error parsing formatted string into token stream.")
}
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