// Copyright 2019 Developers of the Rand project. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. #![allow(dead_code)] use crate::Error; use core::{ cmp::min, mem::MaybeUninit, num::NonZeroU32, ptr::NonNull, sync::atomic::{fence, AtomicPtr, Ordering}, }; use libc::c_void; cfg_if! { if #[cfg(any(target_os = "netbsd", target_os = "openbsd", target_os = "android"))] { use libc::__errno as errno_location; } else if #[cfg(any(target_os = "linux", target_os = "emscripten", target_os = "redox"))] { use libc::__errno_location as errno_location; } else if #[cfg(any(target_os = "solaris", target_os = "illumos"))] { use libc::___errno as errno_location; } else if #[cfg(any(target_os = "macos", target_os = "freebsd"))] { use libc::__error as errno_location; } else if #[cfg(target_os = "haiku")] { use libc::_errnop as errno_location; } else if #[cfg(target_os = "nto")] { use libc::__get_errno_ptr as errno_location; } else if #[cfg(all(target_os = "horizon", target_arch = "arm"))] { extern "C" { // Not provided by libc: https://github.com/rust-lang/libc/issues/1995 fn __errno() -> *mut libc::c_int; } use __errno as errno_location; } else if #[cfg(target_os = "aix")] { use libc::_Errno as errno_location; } } cfg_if! { if #[cfg(target_os = "vxworks")] { use libc::errnoGet as get_errno; } else if #[cfg(target_os = "dragonfly")] { // Until rust-lang/rust#29594 is stable, we cannot get the errno value // on DragonFlyBSD. So we just return an out-of-range errno. unsafe fn get_errno() -> libc::c_int { -1 } } else { unsafe fn get_errno() -> libc::c_int { *errno_location() } } } pub fn last_os_error() -> Error { let errno = unsafe { get_errno() }; if errno > 0 { Error::from(NonZeroU32::new(errno as u32).unwrap()) } else { Error::ERRNO_NOT_POSITIVE } } // Fill a buffer by repeatedly invoking a system call. The `sys_fill` function: // - should return -1 and set errno on failure // - should return the number of bytes written on success pub fn sys_fill_exact( mut buf: &mut [MaybeUninit], sys_fill: impl Fn(&mut [MaybeUninit]) -> libc::ssize_t, ) -> Result<(), Error> { while !buf.is_empty() { let res = sys_fill(buf); if res < 0 { let err = last_os_error(); // We should try again if the call was interrupted. if err.raw_os_error() != Some(libc::EINTR) { return Err(err); } } else { // We don't check for EOF (ret = 0) as the data we are reading // should be an infinite stream of random bytes. let len = min(res as usize, buf.len()); buf = &mut buf[len..]; } } Ok(()) } // A "weak" binding to a C function that may or may not be present at runtime. // Used for supporting newer OS features while still building on older systems. // Based off of the DlsymWeak struct in libstd: // https://github.com/rust-lang/rust/blob/1.61.0/library/std/src/sys/unix/weak.rs#L84 // except that the caller must manually cast self.ptr() to a function pointer. pub struct Weak { name: &'static str, addr: AtomicPtr, } impl Weak { // A non-null pointer value which indicates we are uninitialized. This // constant should ideally not be a valid address of a function pointer. // However, if by chance libc::dlsym does return UNINIT, there will not // be undefined behavior. libc::dlsym will just be called each time ptr() // is called. This would be inefficient, but correct. // TODO: Replace with core::ptr::invalid_mut(1) when that is stable. const UNINIT: *mut c_void = 1 as *mut c_void; // Construct a binding to a C function with a given name. This function is // unsafe because `name` _must_ be null terminated. pub const unsafe fn new(name: &'static str) -> Self { Self { name, addr: AtomicPtr::new(Self::UNINIT), } } // Return the address of a function if present at runtime. Otherwise, // return None. Multiple callers can call ptr() concurrently. It will // always return _some_ value returned by libc::dlsym. However, the // dlsym function may be called multiple times. pub fn ptr(&self) -> Option> { // Despite having only a single atomic variable (self.addr), we still // cannot always use Ordering::Relaxed, as we need to make sure a // successful call to dlsym() is "ordered before" any data read through // the returned pointer (which occurs when the function is called). // Our implementation mirrors that of the one in libstd, meaning that // the use of non-Relaxed operations is probably unnecessary. match self.addr.load(Ordering::Relaxed) { Self::UNINIT => { let symbol = self.name.as_ptr() as *const _; let addr = unsafe { libc::dlsym(libc::RTLD_DEFAULT, symbol) }; // Synchronizes with the Acquire fence below self.addr.store(addr, Ordering::Release); NonNull::new(addr) } addr => { let func = NonNull::new(addr)?; fence(Ordering::Acquire); Some(func) } } } } // SAFETY: path must be null terminated, FD must be manually closed. pub unsafe fn open_readonly(path: &str) -> Result { debug_assert_eq!(path.as_bytes().last(), Some(&0)); loop { let fd = libc::open(path.as_ptr() as *const _, libc::O_RDONLY | libc::O_CLOEXEC); if fd >= 0 { return Ok(fd); } let err = last_os_error(); // We should try again if open() was interrupted. if err.raw_os_error() != Some(libc::EINTR) { return Err(err); } } }