| // Implementation derived from `weak` in Rust's |
| // library/std/src/sys/unix/weak.rs at revision |
| // fd0cb0cdc21dd9c06025277d772108f8d42cb25f. |
| |
| //! Support for "weak linkage" to symbols on Unix |
| //! |
| //! Some I/O operations we do in libstd require newer versions of OSes but we |
| //! need to maintain binary compatibility with older releases for now. In order |
| //! to use the new functionality when available we use this module for |
| //! detection. |
| //! |
| //! One option to use here is weak linkage, but that is unfortunately only |
| //! really workable on Linux. Hence, use dlsym to get the symbol value at |
| //! runtime. This is also done for compatibility with older versions of glibc, |
| //! and to avoid creating dependencies on `GLIBC_PRIVATE` symbols. It assumes |
| //! that we've been dynamically linked to the library the symbol comes from, |
| //! but that is currently always the case for things like libpthread/libc. |
| //! |
| //! A long time ago this used weak linkage for the `__pthread_get_minstack` |
| //! symbol, but that caused Debian to detect an unnecessarily strict versioned |
| //! dependency on libc6 (#23628). |
| |
| // There are a variety of `#[cfg]`s controlling which targets are involved in |
| // each instance of `weak!` and `syscall!`. Rather than trying to unify all of |
| // that, we'll just allow that some unix targets don't use this module at all. |
| #![allow(dead_code, unused_macros)] |
| #![allow(clippy::doc_markdown)] |
| |
| use crate::ffi::CStr; |
| use core::ffi::c_void; |
| use core::ptr::null_mut; |
| use core::sync::atomic::{self, AtomicPtr, Ordering}; |
| use core::{marker, mem}; |
| |
| const NULL: *mut c_void = null_mut(); |
| const INVALID: *mut c_void = 1 as *mut c_void; |
| |
| macro_rules! weak { |
| ($vis:vis fn $name:ident($($t:ty),*) -> $ret:ty) => ( |
| #[allow(non_upper_case_globals)] |
| $vis static $name: $crate::backend::weak::Weak<unsafe extern fn($($t),*) -> $ret> = |
| $crate::backend::weak::Weak::new(concat!(stringify!($name), '\0')); |
| ) |
| } |
| |
| pub(crate) struct Weak<F> { |
| name: &'static str, |
| addr: AtomicPtr<c_void>, |
| _marker: marker::PhantomData<F>, |
| } |
| |
| impl<F> Weak<F> { |
| pub(crate) const fn new(name: &'static str) -> Self { |
| Self { |
| name, |
| addr: AtomicPtr::new(INVALID), |
| _marker: marker::PhantomData, |
| } |
| } |
| |
| pub(crate) fn get(&self) -> Option<F> { |
| assert_eq!(mem::size_of::<F>(), mem::size_of::<usize>()); |
| unsafe { |
| // Relaxed is fine here because we fence before reading through the |
| // pointer (see the comment below). |
| match self.addr.load(Ordering::Relaxed) { |
| INVALID => self.initialize(), |
| NULL => None, |
| addr => { |
| let func = mem::transmute_copy::<*mut c_void, F>(&addr); |
| // The caller is presumably going to read through this value |
| // (by calling the function we've dlsymed). This means we'd |
| // need to have loaded it with at least C11's consume |
| // ordering in order to be guaranteed that the data we read |
| // from the pointer isn't from before the pointer was |
| // stored. Rust has no equivalent to memory_order_consume, |
| // so we use an acquire fence (sorry, ARM). |
| // |
| // Now, in practice this likely isn't needed even on CPUs |
| // where relaxed and consume mean different things. The |
| // symbols we're loading are probably present (or not) at |
| // init, and even if they aren't the runtime dynamic loader |
| // is extremely likely have sufficient barriers internally |
| // (possibly implicitly, for example the ones provided by |
| // invoking `mprotect`). |
| // |
| // That said, none of that's *guaranteed*, and so we fence. |
| atomic::fence(Ordering::Acquire); |
| Some(func) |
| } |
| } |
| } |
| } |
| |
| // Cold because it should only happen during first-time initialization. |
| #[cold] |
| unsafe fn initialize(&self) -> Option<F> { |
| let val = fetch(self.name); |
| // This synchronizes with the acquire fence in `get`. |
| self.addr.store(val, Ordering::Release); |
| |
| match val { |
| NULL => None, |
| addr => Some(mem::transmute_copy::<*mut c_void, F>(&addr)), |
| } |
| } |
| } |
| |
| unsafe fn fetch(name: &str) -> *mut c_void { |
| let name = match CStr::from_bytes_with_nul(name.as_bytes()) { |
| Ok(c_str) => c_str, |
| Err(..) => return null_mut(), |
| }; |
| libc::dlsym(libc::RTLD_DEFAULT, name.as_ptr()) |
| } |
| |
| #[cfg(not(any(target_os = "android", target_os = "linux")))] |
| macro_rules! syscall { |
| (fn $name:ident($($arg_name:ident: $t:ty),*) via $_sys_name:ident -> $ret:ty) => ( |
| unsafe fn $name($($arg_name: $t),*) -> $ret { |
| weak! { fn $name($($t),*) -> $ret } |
| |
| if let Some(fun) = $name.get() { |
| fun($($arg_name),*) |
| } else { |
| libc_errno::set_errno(libc_errno::Errno(libc::ENOSYS)); |
| -1 |
| } |
| } |
| ) |
| } |
| |
| #[cfg(any(target_os = "android", target_os = "linux"))] |
| macro_rules! syscall { |
| (fn $name:ident($($arg_name:ident: $t:ty),*) via $sys_name:ident -> $ret:ty) => ( |
| unsafe fn $name($($arg_name:$t),*) -> $ret { |
| // This looks like a hack, but concat_idents only accepts idents |
| // (not paths). |
| use libc::*; |
| |
| trait AsSyscallArg { |
| type SyscallArgType; |
| fn into_syscall_arg(self) -> Self::SyscallArgType; |
| } |
| |
| // Pass pointer types as pointers, to preserve provenance. |
| impl<T> AsSyscallArg for *mut T { |
| type SyscallArgType = *mut T; |
| fn into_syscall_arg(self) -> Self::SyscallArgType { self } |
| } |
| impl<T> AsSyscallArg for *const T { |
| type SyscallArgType = *const T; |
| fn into_syscall_arg(self) -> Self::SyscallArgType { self } |
| } |
| |
| // Pass `BorrowedFd` values as the integer value. |
| impl AsSyscallArg for $crate::fd::BorrowedFd<'_> { |
| type SyscallArgType = c::c_long; |
| fn into_syscall_arg(self) -> Self::SyscallArgType { |
| $crate::fd::AsRawFd::as_raw_fd(&self) as _ |
| } |
| } |
| |
| // Coerce integer values into `c_long`. |
| impl AsSyscallArg for i32 { |
| type SyscallArgType = c::c_long; |
| fn into_syscall_arg(self) -> Self::SyscallArgType { self as _ } |
| } |
| impl AsSyscallArg for u32 { |
| type SyscallArgType = c::c_long; |
| fn into_syscall_arg(self) -> Self::SyscallArgType { self as _ } |
| } |
| impl AsSyscallArg for usize { |
| type SyscallArgType = c::c_long; |
| fn into_syscall_arg(self) -> Self::SyscallArgType { self as _ } |
| } |
| |
| // `concat_idents is unstable, so we take an extra `sys_name` |
| // parameter and have our users do the concat for us for now. |
| /* |
| syscall( |
| concat_idents!(SYS_, $name), |
| $($arg_name.into_syscall_arg()),* |
| ) as $ret |
| */ |
| |
| syscall($sys_name, $($arg_name.into_syscall_arg()),*) as $ret |
| } |
| ) |
| } |
| |
| macro_rules! weakcall { |
| ($vis:vis fn $name:ident($($arg_name:ident: $t:ty),*) -> $ret:ty) => ( |
| $vis unsafe fn $name($($arg_name: $t),*) -> $ret { |
| weak! { fn $name($($t),*) -> $ret } |
| |
| // Use a weak symbol from libc when possible, allowing `LD_PRELOAD` |
| // interposition, but if it's not found just fail. |
| if let Some(fun) = $name.get() { |
| fun($($arg_name),*) |
| } else { |
| libc_errno::set_errno(libc_errno::Errno(libc::ENOSYS)); |
| -1 |
| } |
| } |
| ) |
| } |
| |
| /// A combination of `weakcall` and `syscall`. Use the libc function if it's |
| /// available, and fall back to `libc::syscall` otherwise. |
| macro_rules! weak_or_syscall { |
| ($vis:vis fn $name:ident($($arg_name:ident: $t:ty),*) via $sys_name:ident -> $ret:ty) => ( |
| $vis unsafe fn $name($($arg_name: $t),*) -> $ret { |
| weak! { fn $name($($t),*) -> $ret } |
| |
| // Use a weak symbol from libc when possible, allowing `LD_PRELOAD` |
| // interposition, but if it's not found just fail. |
| if let Some(fun) = $name.get() { |
| fun($($arg_name),*) |
| } else { |
| syscall! { fn $name($($arg_name: $t),*) via $sys_name -> $ret } |
| $name($($arg_name),*) |
| } |
| } |
| ) |
| } |
