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process_unix.rs
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process_unix.rs
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use crate::convert::{TryFrom, TryInto};
use crate::fmt;
use crate::io::{self, Error, ErrorKind};
use crate::mem;
use crate::num::NonZeroI32;
use crate::os::raw::NonZero_c_int;
use crate::ptr;
use crate::sys;
use crate::sys::cvt;
use crate::sys::process::process_common::*;
#[cfg(target_os = "linux")]
use crate::os::linux::process::PidFd;
#[cfg(target_os = "linux")]
use crate::sys::weak::syscall;
#[cfg(any(
target_os = "macos",
target_os = "freebsd",
all(target_os = "linux", target_env = "gnu"),
all(target_os = "linux", target_env = "musl"),
))]
use crate::sys::weak::weak;
#[cfg(target_os = "vxworks")]
use libc::RTP_ID as pid_t;
#[cfg(not(target_os = "vxworks"))]
use libc::{c_int, gid_t, pid_t, uid_t};
////////////////////////////////////////////////////////////////////////////////
// Command
////////////////////////////////////////////////////////////////////////////////
impl Command {
pub fn spawn(
&mut self,
default: Stdio,
needs_stdin: bool,
) -> io::Result<(Process, StdioPipes)> {
const CLOEXEC_MSG_FOOTER: [u8; 4] = *b"NOEX";
let envp = self.capture_env();
if self.saw_nul() {
return Err(io::Error::new_const(
ErrorKind::InvalidInput,
&"nul byte found in provided data",
));
}
let (ours, theirs) = self.setup_io(default, needs_stdin)?;
if let Some(ret) = self.posix_spawn(&theirs, envp.as_ref())? {
return Ok((ret, ours));
}
let (input, output) = sys::pipe::anon_pipe()?;
// Whatever happens after the fork is almost for sure going to touch or
// look at the environment in one way or another (PATH in `execvp` or
// accessing the `environ` pointer ourselves). Make sure no other thread
// is accessing the environment when we do the fork itself.
//
// Note that as soon as we're done with the fork there's no need to hold
// a lock any more because the parent won't do anything and the child is
// in its own process. Thus the parent drops the lock guard while the child
// forgets it to avoid unlocking it on a new thread, which would be invalid.
let env_lock = sys::os::env_read_lock();
let (pid, pidfd) = unsafe { self.do_fork()? };
if pid == 0 {
crate::panic::always_abort();
mem::forget(env_lock);
drop(input);
let Err(err) = unsafe { self.do_exec(theirs, envp.as_ref()) };
let errno = err.raw_os_error().unwrap_or(libc::EINVAL) as u32;
let errno = errno.to_be_bytes();
let bytes = [
errno[0],
errno[1],
errno[2],
errno[3],
CLOEXEC_MSG_FOOTER[0],
CLOEXEC_MSG_FOOTER[1],
CLOEXEC_MSG_FOOTER[2],
CLOEXEC_MSG_FOOTER[3],
];
// pipe I/O up to PIPE_BUF bytes should be atomic, and then
// we want to be sure we *don't* run at_exit destructors as
// we're being torn down regardless
rtassert!(output.write(&bytes).is_ok());
unsafe { libc::_exit(1) }
}
drop(env_lock);
drop(output);
// Safety: We obtained the pidfd from calling `clone3` with
// `CLONE_PIDFD` so it's valid an otherwise unowned.
let mut p = unsafe { Process::new(pid, pidfd) };
let mut bytes = [0; 8];
// loop to handle EINTR
loop {
match input.read(&mut bytes) {
Ok(0) => return Ok((p, ours)),
Ok(8) => {
let (errno, footer) = bytes.split_at(4);
assert_eq!(
CLOEXEC_MSG_FOOTER, footer,
"Validation on the CLOEXEC pipe failed: {:?}",
bytes
);
let errno = i32::from_be_bytes(errno.try_into().unwrap());
assert!(p.wait().is_ok(), "wait() should either return Ok or panic");
return Err(Error::from_raw_os_error(errno));
}
Err(ref e) if e.kind() == ErrorKind::Interrupted => {}
Err(e) => {
assert!(p.wait().is_ok(), "wait() should either return Ok or panic");
panic!("the CLOEXEC pipe failed: {:?}", e)
}
Ok(..) => {
// pipe I/O up to PIPE_BUF bytes should be atomic
assert!(p.wait().is_ok(), "wait() should either return Ok or panic");
panic!("short read on the CLOEXEC pipe")
}
}
}
}
// Attempts to fork the process. If successful, returns Ok((0, -1))
// in the child, and Ok((child_pid, -1)) in the parent.
#[cfg(not(target_os = "linux"))]
unsafe fn do_fork(&mut self) -> Result<(pid_t, pid_t), io::Error> {
cvt(libc::fork()).map(|res| (res, -1))
}
// Attempts to fork the process. If successful, returns Ok((0, -1))
// in the child, and Ok((child_pid, child_pidfd)) in the parent.
#[cfg(target_os = "linux")]
unsafe fn do_fork(&mut self) -> Result<(pid_t, pid_t), io::Error> {
use crate::sync::atomic::{AtomicBool, Ordering};
static HAS_CLONE3: AtomicBool = AtomicBool::new(true);
const CLONE_PIDFD: u64 = 0x00001000;
#[repr(C)]
struct clone_args {
flags: u64,
pidfd: u64,
child_tid: u64,
parent_tid: u64,
exit_signal: u64,
stack: u64,
stack_size: u64,
tls: u64,
set_tid: u64,
set_tid_size: u64,
cgroup: u64,
}
syscall! {
fn clone3(cl_args: *mut clone_args, len: libc::size_t) -> libc::c_long
}
// If we fail to create a pidfd for any reason, this will
// stay as -1, which indicates an error.
let mut pidfd: pid_t = -1;
// Attempt to use the `clone3` syscall, which supports more arguments
// (in particular, the ability to create a pidfd). If this fails,
// we will fall through this block to a call to `fork()`
if HAS_CLONE3.load(Ordering::Relaxed) {
let mut flags = 0;
if self.get_create_pidfd() {
flags |= CLONE_PIDFD;
}
let mut args = clone_args {
flags,
pidfd: &mut pidfd as *mut pid_t as u64,
child_tid: 0,
parent_tid: 0,
exit_signal: libc::SIGCHLD as u64,
stack: 0,
stack_size: 0,
tls: 0,
set_tid: 0,
set_tid_size: 0,
cgroup: 0,
};
let args_ptr = &mut args as *mut clone_args;
let args_size = crate::mem::size_of::<clone_args>();
let res = cvt(clone3(args_ptr, args_size));
match res {
Ok(n) => return Ok((n as pid_t, pidfd)),
Err(e) => match e.raw_os_error() {
// Multiple threads can race to execute this store,
// but that's fine - that just means that multiple threads
// will have tried and failed to execute the same syscall,
// with no other side effects.
Some(libc::ENOSYS) => HAS_CLONE3.store(false, Ordering::Relaxed),
// Fallback to fork if `EPERM` is returned. (e.g. blocked by seccomp)
Some(libc::EPERM) => {}
_ => return Err(e),
},
}
}
// If we get here, the 'clone3' syscall does not exist
// or we do not have permission to call it
cvt(libc::fork()).map(|res| (res, pidfd))
}
pub fn exec(&mut self, default: Stdio) -> io::Error {
let envp = self.capture_env();
if self.saw_nul() {
return io::Error::new_const(
ErrorKind::InvalidInput,
&"nul byte found in provided data",
);
}
match self.setup_io(default, true) {
Ok((_, theirs)) => {
unsafe {
// Similar to when forking, we want to ensure that access to
// the environment is synchronized, so make sure to grab the
// environment lock before we try to exec.
let _lock = sys::os::env_read_lock();
let Err(e) = self.do_exec(theirs, envp.as_ref());
e
}
}
Err(e) => e,
}
}
// And at this point we've reached a special time in the life of the
// child. The child must now be considered hamstrung and unable to
// do anything other than syscalls really. Consider the following
// scenario:
//
// 1. Thread A of process 1 grabs the malloc() mutex
// 2. Thread B of process 1 forks(), creating thread C
// 3. Thread C of process 2 then attempts to malloc()
// 4. The memory of process 2 is the same as the memory of
// process 1, so the mutex is locked.
//
// This situation looks a lot like deadlock, right? It turns out
// that this is what pthread_atfork() takes care of, which is
// presumably implemented across platforms. The first thing that
// threads to *before* forking is to do things like grab the malloc
// mutex, and then after the fork they unlock it.
//
// Despite this information, libnative's spawn has been witnessed to
// deadlock on both macOS and FreeBSD. I'm not entirely sure why, but
// all collected backtraces point at malloc/free traffic in the
// child spawned process.
//
// For this reason, the block of code below should contain 0
// invocations of either malloc of free (or their related friends).
//
// As an example of not having malloc/free traffic, we don't close
// this file descriptor by dropping the FileDesc (which contains an
// allocation). Instead we just close it manually. This will never
// have the drop glue anyway because this code never returns (the
// child will either exec() or invoke libc::exit)
unsafe fn do_exec(
&mut self,
stdio: ChildPipes,
maybe_envp: Option<&CStringArray>,
) -> Result<!, io::Error> {
use crate::sys::{self, cvt_r};
if let Some(fd) = stdio.stdin.fd() {
cvt_r(|| libc::dup2(fd, libc::STDIN_FILENO))?;
}
if let Some(fd) = stdio.stdout.fd() {
cvt_r(|| libc::dup2(fd, libc::STDOUT_FILENO))?;
}
if let Some(fd) = stdio.stderr.fd() {
cvt_r(|| libc::dup2(fd, libc::STDERR_FILENO))?;
}
#[cfg(not(target_os = "l4re"))]
{
if let Some(_g) = self.get_groups() {
//FIXME: Redox kernel does not support setgroups yet
#[cfg(not(target_os = "redox"))]
cvt(libc::setgroups(_g.len().try_into().unwrap(), _g.as_ptr()))?;
}
if let Some(u) = self.get_gid() {
cvt(libc::setgid(u as gid_t))?;
}
if let Some(u) = self.get_uid() {
// When dropping privileges from root, the `setgroups` call
// will remove any extraneous groups. We only drop groups
// if the current uid is 0 and we weren't given an explicit
// set of groups. If we don't call this, then even though our
// uid has dropped, we may still have groups that enable us to
// do super-user things.
//FIXME: Redox kernel does not support setgroups yet
#[cfg(not(target_os = "redox"))]
if libc::getuid() == 0 && self.get_groups().is_none() {
cvt(libc::setgroups(0, ptr::null()))?;
}
cvt(libc::setuid(u as uid_t))?;
}
}
if let Some(ref cwd) = *self.get_cwd() {
cvt(libc::chdir(cwd.as_ptr()))?;
}
// emscripten has no signal support.
#[cfg(not(target_os = "emscripten"))]
{
use crate::mem::MaybeUninit;
// Reset signal handling so the child process starts in a
// standardized state. libstd ignores SIGPIPE, and signal-handling
// libraries often set a mask. Child processes inherit ignored
// signals and the signal mask from their parent, but most
// UNIX programs do not reset these things on their own, so we
// need to clean things up now to avoid confusing the program
// we're about to run.
let mut set = MaybeUninit::<libc::sigset_t>::uninit();
cvt(sigemptyset(set.as_mut_ptr()))?;
cvt(libc::pthread_sigmask(libc::SIG_SETMASK, set.as_ptr(), ptr::null_mut()))?;
let ret = sys::signal(libc::SIGPIPE, libc::SIG_DFL);
if ret == libc::SIG_ERR {
return Err(io::Error::last_os_error());
}
}
for callback in self.get_closures().iter_mut() {
callback()?;
}
// Although we're performing an exec here we may also return with an
// error from this function (without actually exec'ing) in which case we
// want to be sure to restore the global environment back to what it
// once was, ensuring that our temporary override, when free'd, doesn't
// corrupt our process's environment.
let mut _reset = None;
if let Some(envp) = maybe_envp {
struct Reset(*const *const libc::c_char);
impl Drop for Reset {
fn drop(&mut self) {
unsafe {
*sys::os::environ() = self.0;
}
}
}
_reset = Some(Reset(*sys::os::environ()));
*sys::os::environ() = envp.as_ptr();
}
libc::execvp(self.get_program_cstr().as_ptr(), self.get_argv().as_ptr());
Err(io::Error::last_os_error())
}
#[cfg(not(any(
target_os = "macos",
target_os = "freebsd",
all(target_os = "linux", target_env = "gnu"),
all(target_os = "linux", target_env = "musl"),
)))]
fn posix_spawn(
&mut self,
_: &ChildPipes,
_: Option<&CStringArray>,
) -> io::Result<Option<Process>> {
Ok(None)
}
// Only support platforms for which posix_spawn() can return ENOENT
// directly.
#[cfg(any(
target_os = "macos",
target_os = "freebsd",
all(target_os = "linux", target_env = "gnu"),
all(target_os = "linux", target_env = "musl"),
))]
fn posix_spawn(
&mut self,
stdio: &ChildPipes,
envp: Option<&CStringArray>,
) -> io::Result<Option<Process>> {
use crate::mem::MaybeUninit;
use crate::sys::{self, cvt_nz};
if self.get_gid().is_some()
|| self.get_uid().is_some()
|| (self.env_saw_path() && !self.program_is_path())
|| !self.get_closures().is_empty()
|| self.get_groups().is_some()
|| self.get_create_pidfd()
{
return Ok(None);
}
// Only glibc 2.24+ posix_spawn() supports returning ENOENT directly.
#[cfg(all(target_os = "linux", target_env = "gnu"))]
{
if let Some(version) = sys::os::glibc_version() {
if version < (2, 24) {
return Ok(None);
}
} else {
return Ok(None);
}
}
// Solaris, glibc 2.29+, and musl 1.24+ can set a new working directory,
// and maybe others will gain this non-POSIX function too. We'll check
// for this weak symbol as soon as it's needed, so we can return early
// otherwise to do a manual chdir before exec.
weak! {
fn posix_spawn_file_actions_addchdir_np(
*mut libc::posix_spawn_file_actions_t,
*const libc::c_char
) -> libc::c_int
}
let addchdir = match self.get_cwd() {
Some(cwd) => {
if cfg!(target_os = "macos") {
// There is a bug in macOS where a relative executable
// path like "../myprogram" will cause `posix_spawn` to
// successfully launch the program, but erroneously return
// ENOENT when used with posix_spawn_file_actions_addchdir_np
// which was introduced in macOS 10.15.
return Ok(None);
}
match posix_spawn_file_actions_addchdir_np.get() {
Some(f) => Some((f, cwd)),
None => return Ok(None),
}
}
None => None,
};
// Safety: -1 indicates we don't have a pidfd.
let mut p = unsafe { Process::new(0, -1) };
struct PosixSpawnFileActions<'a>(&'a mut MaybeUninit<libc::posix_spawn_file_actions_t>);
impl Drop for PosixSpawnFileActions<'_> {
fn drop(&mut self) {
unsafe {
libc::posix_spawn_file_actions_destroy(self.0.as_mut_ptr());
}
}
}
struct PosixSpawnattr<'a>(&'a mut MaybeUninit<libc::posix_spawnattr_t>);
impl Drop for PosixSpawnattr<'_> {
fn drop(&mut self) {
unsafe {
libc::posix_spawnattr_destroy(self.0.as_mut_ptr());
}
}
}
unsafe {
let mut attrs = MaybeUninit::uninit();
cvt_nz(libc::posix_spawnattr_init(attrs.as_mut_ptr()))?;
let attrs = PosixSpawnattr(&mut attrs);
let mut file_actions = MaybeUninit::uninit();
cvt_nz(libc::posix_spawn_file_actions_init(file_actions.as_mut_ptr()))?;
let file_actions = PosixSpawnFileActions(&mut file_actions);
if let Some(fd) = stdio.stdin.fd() {
cvt_nz(libc::posix_spawn_file_actions_adddup2(
file_actions.0.as_mut_ptr(),
fd,
libc::STDIN_FILENO,
))?;
}
if let Some(fd) = stdio.stdout.fd() {
cvt_nz(libc::posix_spawn_file_actions_adddup2(
file_actions.0.as_mut_ptr(),
fd,
libc::STDOUT_FILENO,
))?;
}
if let Some(fd) = stdio.stderr.fd() {
cvt_nz(libc::posix_spawn_file_actions_adddup2(
file_actions.0.as_mut_ptr(),
fd,
libc::STDERR_FILENO,
))?;
}
if let Some((f, cwd)) = addchdir {
cvt_nz(f(file_actions.0.as_mut_ptr(), cwd.as_ptr()))?;
}
let mut set = MaybeUninit::<libc::sigset_t>::uninit();
cvt(sigemptyset(set.as_mut_ptr()))?;
cvt_nz(libc::posix_spawnattr_setsigmask(attrs.0.as_mut_ptr(), set.as_ptr()))?;
cvt(sigaddset(set.as_mut_ptr(), libc::SIGPIPE))?;
cvt_nz(libc::posix_spawnattr_setsigdefault(attrs.0.as_mut_ptr(), set.as_ptr()))?;
let flags = libc::POSIX_SPAWN_SETSIGDEF | libc::POSIX_SPAWN_SETSIGMASK;
cvt_nz(libc::posix_spawnattr_setflags(attrs.0.as_mut_ptr(), flags as _))?;
// Make sure we synchronize access to the global `environ` resource
let _env_lock = sys::os::env_read_lock();
let envp = envp.map(|c| c.as_ptr()).unwrap_or_else(|| *sys::os::environ() as *const _);
cvt_nz(libc::posix_spawnp(
&mut p.pid,
self.get_program_cstr().as_ptr(),
file_actions.0.as_ptr(),
attrs.0.as_ptr(),
self.get_argv().as_ptr() as *const _,
envp as *const _,
))?;
Ok(Some(p))
}
}
}
////////////////////////////////////////////////////////////////////////////////
// Processes
////////////////////////////////////////////////////////////////////////////////
/// The unique ID of the process (this should never be negative).
pub struct Process {
pid: pid_t,
status: Option<ExitStatus>,
// On Linux, stores the pidfd created for this child.
// This is None if the user did not request pidfd creation,
// or if the pidfd could not be created for some reason
// (e.g. the `clone3` syscall was not available).
#[cfg(target_os = "linux")]
pidfd: Option<PidFd>,
}
impl Process {
#[cfg(target_os = "linux")]
unsafe fn new(pid: pid_t, pidfd: pid_t) -> Self {
use crate::os::unix::io::FromRawFd;
use crate::sys_common::FromInner;
// Safety: If `pidfd` is nonnegative, we assume it's valid and otherwise unowned.
let pidfd = (pidfd >= 0)
.then(|| PidFd::from_inner(unsafe { sys::fd::FileDesc::from_raw_fd(pidfd) }));
Process { pid, status: None, pidfd }
}
#[cfg(not(target_os = "linux"))]
unsafe fn new(pid: pid_t, _pidfd: pid_t) -> Self {
Process { pid, status: None }
}
pub fn id(&self) -> u32 {
self.pid as u32
}
pub fn kill(&mut self) -> io::Result<()> {
// If we've already waited on this process then the pid can be recycled
// and used for another process, and we probably shouldn't be killing
// random processes, so just return an error.
if self.status.is_some() {
Err(Error::new_const(
ErrorKind::InvalidInput,
&"invalid argument: can't kill an exited process",
))
} else {
cvt(unsafe { libc::kill(self.pid, libc::SIGKILL) }).map(drop)
}
}
pub fn wait(&mut self) -> io::Result<ExitStatus> {
use crate::sys::cvt_r;
if let Some(status) = self.status {
return Ok(status);
}
let mut status = 0 as c_int;
cvt_r(|| unsafe { libc::waitpid(self.pid, &mut status, 0) })?;
self.status = Some(ExitStatus::new(status));
Ok(ExitStatus::new(status))
}
pub fn try_wait(&mut self) -> io::Result<Option<ExitStatus>> {
if let Some(status) = self.status {
return Ok(Some(status));
}
let mut status = 0 as c_int;
let pid = cvt(unsafe { libc::waitpid(self.pid, &mut status, libc::WNOHANG) })?;
if pid == 0 {
Ok(None)
} else {
self.status = Some(ExitStatus::new(status));
Ok(Some(ExitStatus::new(status)))
}
}
}
/// Unix exit statuses
#[derive(PartialEq, Eq, Clone, Copy, Debug)]
pub struct ExitStatus(c_int);
impl ExitStatus {
pub fn new(status: c_int) -> ExitStatus {
ExitStatus(status)
}
fn exited(&self) -> bool {
libc::WIFEXITED(self.0)
}
pub fn exit_ok(&self) -> Result<(), ExitStatusError> {
// This assumes that WIFEXITED(status) && WEXITSTATUS==0 corresponds to status==0. This is
// true on all actual versions of Unix, is widely assumed, and is specified in SuS
// https://pubs.opengroup.org/onlinepubs/9699919799/functions/wait.html . If it is not
// true for a platform pretending to be Unix, the tests (our doctests, and also
// procsss_unix/tests.rs) will spot it. `ExitStatusError::code` assumes this too.
match NonZero_c_int::try_from(self.0) {
/* was nonzero */ Ok(failure) => Err(ExitStatusError(failure)),
/* was zero, couldn't convert */ Err(_) => Ok(()),
}
}
pub fn code(&self) -> Option<i32> {
if self.exited() { Some(libc::WEXITSTATUS(self.0)) } else { None }
}
pub fn signal(&self) -> Option<i32> {
if libc::WIFSIGNALED(self.0) { Some(libc::WTERMSIG(self.0)) } else { None }
}
pub fn core_dumped(&self) -> bool {
libc::WIFSIGNALED(self.0) && libc::WCOREDUMP(self.0)
}
pub fn stopped_signal(&self) -> Option<i32> {
if libc::WIFSTOPPED(self.0) { Some(libc::WSTOPSIG(self.0)) } else { None }
}
pub fn continued(&self) -> bool {
libc::WIFCONTINUED(self.0)
}
pub fn into_raw(&self) -> c_int {
self.0
}
}
/// Converts a raw `c_int` to a type-safe `ExitStatus` by wrapping it without copying.
impl From<c_int> for ExitStatus {
fn from(a: c_int) -> ExitStatus {
ExitStatus(a)
}
}
impl fmt::Display for ExitStatus {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
if let Some(code) = self.code() {
write!(f, "exit status: {}", code)
} else if let Some(signal) = self.signal() {
if self.core_dumped() {
write!(f, "signal: {} (core dumped)", signal)
} else {
write!(f, "signal: {}", signal)
}
} else if let Some(signal) = self.stopped_signal() {
write!(f, "stopped (not terminated) by signal: {}", signal)
} else if self.continued() {
write!(f, "continued (WIFCONTINUED)")
} else {
write!(f, "unrecognised wait status: {} {:#x}", self.0, self.0)
}
}
}
#[derive(PartialEq, Eq, Clone, Copy, Debug)]
pub struct ExitStatusError(NonZero_c_int);
impl Into<ExitStatus> for ExitStatusError {
fn into(self) -> ExitStatus {
ExitStatus(self.0.into())
}
}
impl ExitStatusError {
pub fn code(self) -> Option<NonZeroI32> {
ExitStatus(self.0.into()).code().map(|st| st.try_into().unwrap())
}
}
#[cfg(target_os = "linux")]
#[unstable(feature = "linux_pidfd", issue = "82971")]
impl crate::os::linux::process::ChildExt for crate::process::Child {
fn pidfd(&self) -> io::Result<&PidFd> {
self.handle
.pidfd
.as_ref()
.ok_or_else(|| Error::new(ErrorKind::Other, "No pidfd was created."))
}
fn take_pidfd(&mut self) -> io::Result<PidFd> {
self.handle
.pidfd
.take()
.ok_or_else(|| Error::new(ErrorKind::Other, "No pidfd was created."))
}
}
#[cfg(test)]
#[path = "process_unix/tests.rs"]
mod tests;