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diff --git a/vendor/rustix/src/runtime.rs b/vendor/rustix/src/runtime.rs
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--- a/vendor/rustix/src/runtime.rs
+++ /dev/null
@@ -1,581 +0,0 @@
-//! Experimental low-level implementation details for libc-like runtime
-//! libraries such as [Origin].
-//!
-//! Do not use the functions in this module unless you've read all of their
-//! code. They don't always behave the same way as functions with similar names
-//! in `libc`. Sometimes information about the differences is included in the
-//! Linux documentation under “C library/kernel differences” sections. And, if
-//! there is a libc in the process, these functions may have surprising
-//! interactions with it.
-//!
-//! These functions are for implementing thread-local storage (TLS), managing
-//! threads, loaded libraries, and other process-wide resources. Most of
-//! `rustix` doesn't care about what other libraries are linked into the
-//! program or what they're doing, but the features in this module generally
-//! can only be used by one entity within a process.
-//!
-//! The API for these functions is not stable, and this module is
-//! `doc(hidden)`.
-//!
-//! [Origin]: https://github.com/sunfishcode/origin#readme
-//!
-//! # Safety
-//!
-//! This module is intended to be used for implementing a runtime library such
-//! as libc. Use of these features for any other purpose is likely to create
-//! serious problems.
-#![allow(unsafe_code)]
-
-use crate::backend;
-#[cfg(linux_raw)]
-use crate::ffi::CStr;
-#[cfg(linux_raw)]
-#[cfg(feature = "fs")]
-use crate::fs::AtFlags;
-#[cfg(linux_raw)]
-use crate::io;
-#[cfg(linux_raw)]
-use crate::pid::Pid;
-#[cfg(linux_raw)]
-#[cfg(feature = "fs")]
-use backend::fd::AsFd;
-#[cfg(linux_raw)]
-use core::ffi::c_void;
-
-#[cfg(linux_raw)]
-pub use crate::signal::Signal;
-
-/// `sigaction`
-#[cfg(linux_raw)]
-pub type Sigaction = linux_raw_sys::general::kernel_sigaction;
-
-/// `stack_t`
-#[cfg(linux_raw)]
-pub type Stack = linux_raw_sys::general::stack_t;
-
-/// `sigset_t`
-#[cfg(linux_raw)]
-pub type Sigset = linux_raw_sys::general::kernel_sigset_t;
-
-/// `siginfo_t`
-#[cfg(linux_raw)]
-pub type Siginfo = linux_raw_sys::general::siginfo_t;
-
-pub use crate::timespec::{Nsecs, Secs, Timespec};
-
-/// `SIG_*` constants for use with [`sigprocmask`].
-#[cfg(linux_raw)]
-#[repr(u32)]
-pub enum How {
-    /// `SIG_BLOCK`
-    BLOCK = linux_raw_sys::general::SIG_BLOCK,
-
-    /// `SIG_UNBLOCK`
-    UNBLOCK = linux_raw_sys::general::SIG_UNBLOCK,
-
-    /// `SIG_SETMASK`
-    SETMASK = linux_raw_sys::general::SIG_SETMASK,
-}
-
-#[cfg(target_arch = "x86")]
-#[inline]
-pub unsafe fn set_thread_area(u_info: &mut UserDesc) -> io::Result<()> {
-    backend::runtime::syscalls::tls::set_thread_area(u_info)
-}
-
-#[cfg(target_arch = "arm")]
-#[inline]
-pub unsafe fn arm_set_tls(data: *mut c_void) -> io::Result<()> {
-    backend::runtime::syscalls::tls::arm_set_tls(data)
-}
-
-/// `prctl(PR_SET_FS, data)`—Set the x86-64 `fs` register.
-///
-/// # Safety
-///
-/// This is a very low-level feature for implementing threading libraries.
-/// See the references links above.
-#[cfg(target_arch = "x86_64")]
-#[inline]
-pub unsafe fn set_fs(data: *mut c_void) {
-    backend::runtime::syscalls::tls::set_fs(data)
-}
-
-/// Set the x86-64 thread ID address.
-///
-/// # Safety
-///
-/// This is a very low-level feature for implementing threading libraries.
-/// See the references links above.
-#[inline]
-pub unsafe fn set_tid_address(data: *mut c_void) -> Pid {
-    backend::runtime::syscalls::tls::set_tid_address(data)
-}
-
-#[cfg(linux_raw)]
-#[cfg(target_arch = "x86")]
-pub use backend::runtime::tls::UserDesc;
-
-/// `syscall(SYS_exit, status)`—Exit the current thread.
-///
-/// # Safety
-///
-/// This is a very low-level feature for implementing threading libraries.
-#[inline]
-pub unsafe fn exit_thread(status: i32) -> ! {
-    backend::runtime::syscalls::tls::exit_thread(status)
-}
-
-/// Exit all the threads in the current process' thread group.
-///
-/// This is equivalent to `_exit` and `_Exit` in libc.
-///
-/// This does not call any `__cxa_atexit`, `atexit`, or any other destructors.
-/// Most programs should use [`std::process::exit`] instead of calling this
-/// directly.
-///
-/// # References
-///  - [POSIX `_Exit`]
-///  - [Linux `exit_group`]
-///  - [Linux `_Exit`]
-///
-/// [POSIX `_Exit`]: https://pubs.opengroup.org/onlinepubs/9699919799/functions/_Exit.html
-/// [Linux `exit_group`]: https://man7.org/linux/man-pages/man2/exit_group.2.html
-/// [Linux `_Exit`]: https://man7.org/linux/man-pages/man2/_Exit.2.html
-#[doc(alias = "_exit")]
-#[doc(alias = "_Exit")]
-#[inline]
-pub fn exit_group(status: i32) -> ! {
-    backend::runtime::syscalls::exit_group(status)
-}
-
-/// `EXIT_SUCCESS` for use with [`exit_group`].
-///
-/// # References
-///  - [POSIX]
-///  - [Linux]
-///
-/// [POSIX]: https://pubs.opengroup.org/onlinepubs/9699919799/basedefs/stdlib.h.html
-/// [Linux]: https://man7.org/linux/man-pages/man3/exit.3.html
-pub const EXIT_SUCCESS: i32 = backend::c::EXIT_SUCCESS;
-
-/// `EXIT_FAILURE` for use with [`exit_group`].
-///
-/// # References
-///  - [POSIX]
-///  - [Linux]
-///
-/// [POSIX]: https://pubs.opengroup.org/onlinepubs/9699919799/basedefs/stdlib.h.html
-/// [Linux]: https://man7.org/linux/man-pages/man3/exit.3.html
-pub const EXIT_FAILURE: i32 = backend::c::EXIT_FAILURE;
-
-/// Return fields from the main executable segment headers ("phdrs") relevant
-/// to initializing TLS provided to the program at startup.
-///
-/// `addr` will always be non-null, even when the TLS data is absent, so that
-/// the `addr` and `file_size` parameters are suitable for creating a slice
-/// with `slice::from_raw_parts`.
-#[inline]
-pub fn startup_tls_info() -> StartupTlsInfo {
-    backend::runtime::tls::startup_tls_info()
-}
-
-/// `(getauxval(AT_PHDR), getauxval(AT_PHENT), getauxval(AT_PHNUM))`—Returns
-/// the address, ELF segment header size, and number of ELF segment headers for
-/// the main executable.
-///
-/// # References
-///  - [Linux]
-///
-/// [Linux]: https://man7.org/linux/man-pages/man3/getauxval.3.html
-#[inline]
-pub fn exe_phdrs() -> (*const c_void, usize, usize) {
-    backend::param::auxv::exe_phdrs()
-}
-
-/// `getauxval(AT_ENTRY)`—Returns the address of the program entrypoint.
-///
-/// Most code interested in the program entrypoint address should instead use a
-/// symbol reference to `_start`. That will be properly PC-relative or
-/// relocated if needed, and will come with appropriate pointer type and
-/// pointer provenance.
-///
-/// This function is intended only for use in code that implements those
-/// relocations, to compute the ASLR offset. It has type `usize`, so it doesn't
-/// carry any provenance, and it shouldn't be used to dereference memory.
-///
-/// # References
-///  - [Linux]
-///
-/// [Linux]: https://man7.org/linux/man-pages/man3/getauxval.3.html
-#[inline]
-pub fn entry() -> usize {
-    backend::param::auxv::entry()
-}
-
-/// `getauxval(AT_RANDOM)`—Returns the address of 16 pseudorandom bytes.
-///
-/// These bytes are for use by libc. For anything else, use the `rand` crate.
-///
-/// # References
-///  - [Linux]
-///
-/// [Linux]: https://man7.org/linux/man-pages/man3/getauxval.3.html
-#[inline]
-pub fn random() -> *const [u8; 16] {
-    backend::param::auxv::random()
-}
-
-#[cfg(linux_raw)]
-pub use backend::runtime::tls::StartupTlsInfo;
-
-/// `fork()`—Creates a new process by duplicating the calling process.
-///
-/// On success, the pid of the child process is returned in the parent, and
-/// `None` is returned in the child.
-///
-/// Unlike its POSIX and libc counterparts, this `fork` does not invoke any
-/// handlers (such as those registered with `pthread_atfork`).
-///
-/// The program environment in the child after a `fork` and before an `execve`
-/// is very special. All code that executes in this environment must avoid:
-///
-///  - Acquiring any other locks that are held in other threads on the parent
-///    at the time of the `fork`, as the child only contains one thread, and
-///    attempting to acquire such locks will deadlock (though this is [not
-///    considered unsafe]).
-///
-///  - Performing any dynamic allocation using the global allocator, since
-///    global allocators may use locks to ensure thread safety, and their locks
-///    may not be released in the child process, so attempts to allocate may
-///    deadlock (as described in the previous point).
-///
-///  - Accessing any external state which the parent assumes it has exclusive
-///    access to, such as a file protected by a file lock, as this could
-///    corrupt the external state.
-///
-///  - Accessing any random-number-generator state inherited from the parent,
-///    as the parent may have the same state and generate the same random
-///    numbers, which may violate security invariants.
-///
-///  - Accessing any thread runtime state, since this function does not update
-///    the thread id in the thread runtime, so thread runtime functions could
-///    cause undefined behavior.
-///
-///  - Accessing any memory shared with the parent, such as a [`MAP_SHARED`]
-///    mapping, even with anonymous or [`memfd_create`] mappings, as this could
-///    cause undefined behavior.
-///
-///  - Calling any C function which isn't known to be [async-signal-safe], as
-///    that could cause undefined behavior. The extent to which this also
-///    applies to Rust functions is unclear at this time.
-///
-///  - And more.
-///
-/// # Safety
-///
-/// The child must avoid accessing any memory shared with the parent in a
-/// way that invokes undefined behavior. It must avoid accessing any threading
-/// runtime functions in a way that invokes undefined behavior. And it must
-/// avoid invoking any undefined behavior through any function that is not
-/// guaranteed to be async-signal-safe. But, what does async-signal-safe even
-/// mean in a Rust program? This documentation does not have all the answers.
-///
-/// So you're on your own. And on top of all the troubles with `fork` in
-/// general, this wrapper implementation is highly experimental.
-///
-/// # References
-///  - [POSIX]
-///  - [Linux]
-///
-/// # Literary interlude
-///
-/// > Do not jump on ancient uncles.
-/// > Do not yell at average mice.
-/// > Do not wear a broom to breakfast.
-/// > Do not ask a snake’s advice.
-/// > Do not bathe in chocolate pudding.
-/// > Do not talk to bearded bears.
-/// > Do not smoke cigars on sofas.
-/// > Do not dance on velvet chairs.
-/// > Do not take a whale to visit
-/// > Russell’s mother’s cousin’s yacht.
-/// > And whatever else you do do
-/// > It is better you
-/// > Do not.
-///
-/// - “Rules”, by Karla Kuskin
-///
-/// [`MAP_SHARED`]: https://pubs.opengroup.org/onlinepubs/9699919799/functions/mmap.html
-/// [not considered unsafe]: https://doc.rust-lang.org/reference/behavior-not-considered-unsafe.html#deadlocks
-/// [`memfd_create`]: https://man7.org/linux/man-pages/man2/memfd_create.2.html
-/// [POSIX]: https://pubs.opengroup.org/onlinepubs/9699919799/functions/fork.html
-/// [Linux]: https://man7.org/linux/man-pages/man2/fork.2.html
-/// [async-signal-safe]: https://pubs.opengroup.org/onlinepubs/9699919799/functions/V2_chap02.html#tag_15_04_03
-pub unsafe fn fork() -> io::Result<Fork> {
-    backend::runtime::syscalls::fork()
-}
-
-/// Regular Unix `fork` doesn't tell the child its own PID because it assumes
-/// the child can just do `getpid`. That's true, but it's more fun if it
-/// doesn't have to.
-pub enum Fork {
-    Child(Pid),
-    Parent(Pid),
-}
-
-/// `execveat(dirfd, path.as_c_str(), argv, envp, flags)`—Execute a new
-/// command using the current process.
-///
-/// # Safety
-///
-/// The `argv` and `envp` pointers must point to NUL-terminated arrays, and
-/// their contents must be pointers to NUL-terminated byte arrays.
-///
-/// # References
-///  - [Linux]
-///
-/// [Linux]: https://man7.org/linux/man-pages/man2/execveat.2.html
-#[inline]
-#[cfg(feature = "fs")]
-#[cfg_attr(doc_cfg, doc(cfg(feature = "fs")))]
-pub unsafe fn execveat<Fd: AsFd>(
-    dirfd: Fd,
-    path: &CStr,
-    argv: *const *const u8,
-    envp: *const *const u8,
-    flags: AtFlags,
-) -> io::Errno {
-    backend::runtime::syscalls::execveat(dirfd.as_fd(), path, argv, envp, flags)
-}
-
-/// `execve(path.as_c_str(), argv, envp)`—Execute a new command using the
-/// current process.
-///
-/// # Safety
-///
-/// The `argv` and `envp` pointers must point to NUL-terminated arrays, and
-/// their contents must be pointers to NUL-terminated byte arrays.
-///
-/// # References
-///  - [Linux]
-///
-/// [Linux]: https://man7.org/linux/man-pages/man2/execve.2.html
-#[inline]
-pub unsafe fn execve(path: &CStr, argv: *const *const u8, envp: *const *const u8) -> io::Errno {
-    backend::runtime::syscalls::execve(path, argv, envp)
-}
-
-/// `sigaction(signal, &new, &old)`—Modify or query a signal handler.
-///
-/// # Safety
-///
-/// You're on your own. And on top of all the troubles with signal handlers,
-/// this implementation is highly experimental. Even further, it differs from
-/// the libc `sigaction` in several non-obvious and unsafe ways.
-///
-/// # References
-///  - [POSIX]
-///  - [Linux]
-///
-/// [POSIX]: https://pubs.opengroup.org/onlinepubs/9699919799/functions/sigaction.html
-/// [Linux]: https://man7.org/linux/man-pages/man2/sigaction.2.html
-#[inline]
-pub unsafe fn sigaction(signal: Signal, new: Option<Sigaction>) -> io::Result<Sigaction> {
-    backend::runtime::syscalls::sigaction(signal, new)
-}
-
-/// `sigaltstack(new, old)`—Modify or query a signal stack.
-///
-/// # Safety
-///
-/// You're on your own. And on top of all the troubles with signal handlers,
-/// this implementation is highly experimental.
-///
-/// # References
-///  - [POSIX]
-///  - [Linux]
-///
-/// [POSIX]: https://pubs.opengroup.org/onlinepubs/9699919799/functions/sigaltstack.html
-/// [Linux]: https://man7.org/linux/man-pages/man2/sigaltstack.2.html
-#[inline]
-pub unsafe fn sigaltstack(new: Option<Stack>) -> io::Result<Stack> {
-    backend::runtime::syscalls::sigaltstack(new)
-}
-
-/// `tkill(tid, sig)`—Send a signal to a thread.
-///
-/// # Safety
-///
-/// You're on your own. And on top of all the troubles with signal handlers,
-/// this implementation is highly experimental. The warning about the hazard
-/// of recycled thread ID's applies.
-///
-/// # References
-///  - [Linux]
-///
-/// [Linux]: https://man7.org/linux/man-pages/man2/tkill.2.html
-#[inline]
-pub unsafe fn tkill(tid: Pid, sig: Signal) -> io::Result<()> {
-    backend::runtime::syscalls::tkill(tid, sig)
-}
-
-/// `sigprocmask(how, set, oldset)`—Adjust the process signal mask.
-///
-/// # Safety
-///
-/// You're on your own. And on top of all the troubles with signal handlers,
-/// this implementation is highly experimental. Even further, it differs from
-/// the libc `sigprocmask` in several non-obvious and unsafe ways.
-///
-/// # References
-///  - [Linux `sigprocmask`]
-///  - [Linux `pthread_sigmask`]
-///
-/// [Linux `sigprocmask`]: https://man7.org/linux/man-pages/man2/sigprocmask.2.html
-/// [Linux `pthread_sigmask`]: https://man7.org/linux/man-pages/man3/pthread_sigmask.3.html
-#[inline]
-#[doc(alias = "pthread_sigmask")]
-pub unsafe fn sigprocmask(how: How, set: Option<&Sigset>) -> io::Result<Sigset> {
-    backend::runtime::syscalls::sigprocmask(how, set)
-}
-
-/// `sigpending()`—Query the pending signals.
-///
-/// # References
-///  - [Linux `sigpending`]
-///
-/// [Linux `sigpending`]: https://man7.org/linux/man-pages/man2/sigpending.2.html
-#[inline]
-pub fn sigpending() -> Sigset {
-    backend::runtime::syscalls::sigpending()
-}
-
-/// `sigsuspend(set)`—Suspend the calling thread and wait for signals.
-///
-/// # References
-///  - [Linux `sigsuspend`]
-///
-/// [Linux `sigsuspend`]: https://man7.org/linux/man-pages/man2/sigsuspend.2.html
-#[inline]
-pub fn sigsuspend(set: &Sigset) -> io::Result<()> {
-    backend::runtime::syscalls::sigsuspend(set)
-}
-
-/// `sigwait(set)`—Wait for signals.
-///
-/// # Safety
-///
-/// If code elsewhere in the process is depending on delivery of a signal to
-/// prevent it from executing some code, this could cause it to miss that
-/// signal and execute that code.
-///
-/// # References
-///  - [Linux]
-///
-/// [Linux]: https://man7.org/linux/man-pages/man3/sigwait.3.html
-#[inline]
-pub unsafe fn sigwait(set: &Sigset) -> io::Result<Signal> {
-    backend::runtime::syscalls::sigwait(set)
-}
-
-/// `sigwaitinfo(set)`—Wait for signals, returning a [`Siginfo`].
-///
-/// # Safety
-///
-/// If code elsewhere in the process is depending on delivery of a signal to
-/// prevent it from executing some code, this could cause it to miss that
-/// signal and execute that code.
-///
-/// # References
-///  - [Linux]
-///
-/// [Linux]: https://man7.org/linux/man-pages/man2/sigwaitinfo.2.html
-#[inline]
-pub unsafe fn sigwaitinfo(set: &Sigset) -> io::Result<Siginfo> {
-    backend::runtime::syscalls::sigwaitinfo(set)
-}
-
-/// `sigtimedwait(set)`—Wait for signals, optionally with a timeout.
-///
-/// # Safety
-///
-/// If code elsewhere in the process is depending on delivery of a signal to
-/// prevent it from executing some code, this could cause it to miss that
-/// signal and execute that code.
-///
-/// # References
-///  - [Linux]
-///
-/// [Linux]: https://man7.org/linux/man-pages/man2/sigtimedwait.2.html
-#[inline]
-pub unsafe fn sigtimedwait(set: &Sigset, timeout: Option<Timespec>) -> io::Result<Siginfo> {
-    backend::runtime::syscalls::sigtimedwait(set, timeout)
-}
-
-/// `getauxval(AT_SECURE)`—Returns the Linux “secure execution” mode.
-///
-/// Return a boolean value indicating whether “secure execution” mode was
-/// requested, due to the process having elevated privileges. This includes
-/// whether the `AT_SECURE` AUX value is set, and whether the initial real UID
-/// and GID differ from the initial effective UID and GID.
-///
-/// The meaning of “secure execution” mode is beyond the scope of this
-/// comment.
-///
-/// # References
-///  - [Linux]
-///
-/// [Linux]: https://man7.org/linux/man-pages/man3/getauxval.3.html
-#[cfg(any(
-    linux_raw,
-    any(
-        all(target_os = "android", target_pointer_width = "64"),
-        target_os = "linux",
-    )
-))]
-#[inline]
-pub fn linux_secure() -> bool {
-    backend::param::auxv::linux_secure()
-}
-
-/// `brk(addr)`—Change the location of the “program break”.
-///
-/// # Safety
-///
-/// This is not identical to `brk` in libc. libc `brk` may have bookkeeping
-/// that needs to be kept up to date that this doesn't keep up to date, so
-/// don't use it unless you are implementing libc.
-#[cfg(linux_raw)]
-#[inline]
-pub unsafe fn brk(addr: *mut c_void) -> io::Result<*mut c_void> {
-    backend::runtime::syscalls::brk(addr)
-}
-
-/// `__SIGRTMIN`—The start of the realtime signal range.
-///
-/// This is the raw `SIGRTMIN` value from the OS, which is not the same as the
-/// `SIGRTMIN` macro provided by libc. Don't use this unless you are
-/// implementing libc.
-#[cfg(linux_raw)]
-pub const SIGRTMIN: u32 = linux_raw_sys::general::SIGRTMIN;
-
-/// `__SIGRTMAX`—The last of the realtime signal range.
-///
-/// This is the raw `SIGRTMAX` value from the OS, which is not the same as the
-/// `SIGRTMAX` macro provided by libc. Don't use this unless you are
-/// implementing libc.
-#[cfg(linux_raw)]
-pub const SIGRTMAX: u32 = {
-    // Use the actual `SIGRTMAX` value on platforms which define it.
-    #[cfg(not(any(target_arch = "arm", target_arch = "x86", target_arch = "x86_64")))]
-    {
-        linux_raw_sys::general::SIGRTMAX
-    }
-
-    // On platfoms that don't, derive it from `_NSIG`.
-    #[cfg(any(target_arch = "arm", target_arch = "x86", target_arch = "x86_64"))]
-    {
-        linux_raw_sys::general::_NSIG - 1
-    }
-};