//! Bindings for the FreeBSD `procctl` system call.
//!
//! There are similarities (but also differences) with Linux's `prctl` system
//! call, whose interface is located in the `prctl.rs` file.
#![allow(unsafe_code)]
#[cfg(feature = "alloc")]
use alloc::{vec, vec::Vec};
use core::mem::MaybeUninit;
use core::ptr;
use bitflags::bitflags;
use crate::backend::c::{c_int, c_uint, c_void};
use crate::backend::process::syscalls;
use crate::backend::process::types::RawId;
use crate::io;
use crate::process::{Pid, RawPid};
use crate::signal::Signal;
use crate::utils::{as_mut_ptr, as_ptr};
//
// Helper functions.
//
/// Subset of `idtype_t` C enum, with only the values allowed by `procctl`.
#[repr(i32)]
pub enum IdType {
/// Process id.
Pid = 0,
/// Process group id.
Pgid = 2,
}
/// A process selector for use with the `procctl` interface.
///
/// `None` represents the current process. `Some((IdType::Pid, pid))`
/// represents the process with pid `pid`. `Some((IdType::Pgid, pgid))`
/// represents the control processes belonging to the process group with id
/// `pgid`.
pub type ProcSelector = Option<(IdType, Pid)>;
fn proc_selector_to_raw(selector: ProcSelector) -> (IdType, RawPid) {
match selector {
Some((idtype, id)) => (idtype, id.as_raw_nonzero().get()),
None => (IdType::Pid, 0),
}
}
#[inline]
pub(crate) unsafe fn procctl(
option: c_int,
process: ProcSelector,
data: *mut c_void,
) -> io::Result<()> {
let (idtype, id) = proc_selector_to_raw(process);
syscalls::procctl(idtype as c_uint, id as RawId, option, data)
}
#[inline]
pub(crate) unsafe fn procctl_set
(
option: c_int,
process: ProcSelector,
data: &P,
) -> io::Result<()> {
procctl(option, process, (as_ptr(data) as *mut P).cast())
}
#[inline]
pub(crate) unsafe fn procctl_get_optional
(
option: c_int,
process: ProcSelector,
) -> io::Result
{
let mut value: MaybeUninit
= MaybeUninit::uninit();
procctl(option, process, value.as_mut_ptr().cast())?;
Ok(value.assume_init())
}
//
// PROC_PDEATHSIG_STATUS/PROC_PDEATHSIG_CTL
//
const PROC_PDEATHSIG_STATUS: c_int = 12;
/// Get the current value of the parent process death signal.
///
/// # References
/// - [Linux: `prctl(PR_GET_PDEATHSIG,...)`]
/// - [FreeBSD: `procctl(PROC_PDEATHSIG_STATUS,...)`]
///
/// [Linux: `prctl(PR_GET_PDEATHSIG,...)`]: https://man7.org/linux/man-pages/man2/prctl.2.html
/// [FreeBSD: `procctl(PROC_PDEATHSIG_STATUS,...)`]: https://man.freebsd.org/cgi/man.cgi?query=procctl&sektion=2
#[inline]
pub fn parent_process_death_signal() -> io::Result> {
unsafe { procctl_get_optional::(PROC_PDEATHSIG_STATUS, None) }.map(Signal::from_raw)
}
const PROC_PDEATHSIG_CTL: c_int = 11;
/// Set the parent-death signal of the calling process.
///
/// # References
/// - [Linux: `prctl(PR_SET_PDEATHSIG,...)`]
/// - [FreeBSD: `procctl(PROC_PDEATHSIG_CTL,...)`]
///
/// [Linux: `prctl(PR_SET_PDEATHSIG,...)`]: https://man7.org/linux/man-pages/man2/prctl.2.html
/// [FreeBSD: `procctl(PROC_PDEATHSIG_CTL,...)`]: https://man.freebsd.org/cgi/man.cgi?query=procctl&sektion=2
#[inline]
pub fn set_parent_process_death_signal(signal: Option) -> io::Result<()> {
let signal = signal.map_or(0, |signal| signal as c_int);
unsafe { procctl_set::(PROC_PDEATHSIG_CTL, None, &signal) }
}
//
// PROC_TRACE_CTL
//
const PROC_TRACE_CTL: c_int = 7;
const PROC_TRACE_CTL_ENABLE: i32 = 1;
const PROC_TRACE_CTL_DISABLE: i32 = 2;
const PROC_TRACE_CTL_DISABLE_EXEC: i32 = 3;
/// `PROC_TRACE_CTL_*`.
#[derive(Copy, Clone, Debug, Eq, PartialEq)]
#[repr(i32)]
pub enum DumpableBehavior {
/// Not dumpable.
NotDumpable = PROC_TRACE_CTL_DISABLE,
/// Dumpable.
Dumpable = PROC_TRACE_CTL_ENABLE,
/// Not dumpable, and this behaviour is preserved across `execve` calls.
NotDumpableExecPreserved = PROC_TRACE_CTL_DISABLE_EXEC,
}
/// Set the state of the `dumpable` attribute for the process indicated by
/// `idtype` and `id`. This determines whether the process can be traced and
/// whether core dumps are produced for the process upon delivery of a signal
/// whose default behavior is to produce a core dump.
///
/// This is similar to `set_dumpable_behavior` on Linux, with the exception
/// that on FreeBSD there is an extra argument `process`. When `process` is set
/// to `None`, the operation is performed for the current process, like on
/// Linux.
///
/// # References
/// - [FreeBSD `procctl(PROC_TRACE_CTL,...)`]
///
/// [FreeBSD `procctl(PROC_TRACE_CTL,...)`]: https://man.freebsd.org/cgi/man.cgi?query=procctl&sektion=2
#[inline]
pub fn set_dumpable_behavior(process: ProcSelector, config: DumpableBehavior) -> io::Result<()> {
unsafe { procctl(PROC_TRACE_CTL, process, config as usize as *mut _) }
}
//
// PROC_TRACE_STATUS
//
const PROC_TRACE_STATUS: c_int = 8;
/// Tracing status as returned by [`trace_status`].
#[derive(Copy, Clone, Debug, Eq, PartialEq)]
pub enum TracingStatus {
/// Tracing is disabled for the process.
NotTraceble,
/// Tracing is not disabled for the process, but not debugger/tracer is
/// attached.
Tracable,
/// The process is being traced by the process whose pid is stored in the
/// first component of this variant.
BeingTraced(Pid),
}
/// Get the tracing status of the process indicated by `idtype` and `id`.
///
/// # References
/// - [FreeBSD `procctl(PROC_TRACE_STATUS,...)`]
///
/// [FreeBSD `procctl(PROC_TRACE_STATUS,...)`]: https://man.freebsd.org/cgi/man.cgi?query=procctl&sektion=2
#[inline]
pub fn trace_status(process: ProcSelector) -> io::Result {
let val = unsafe { procctl_get_optional::(PROC_TRACE_STATUS, process) }?;
match val {
-1 => Ok(TracingStatus::NotTraceble),
0 => Ok(TracingStatus::Tracable),
pid => {
let pid = Pid::from_raw(pid as RawPid).ok_or(io::Errno::RANGE)?;
Ok(TracingStatus::BeingTraced(pid))
}
}
}
//
// PROC_REAP_*
//
const PROC_REAP_ACQUIRE: c_int = 2;
const PROC_REAP_RELEASE: c_int = 3;
/// Acquire or release the reaper status of the calling process.
///
/// # References
/// - [FreeBSD: `procctl(PROC_REAP_ACQUIRE/RELEASE,...)`]
///
/// [FreeBSD: `procctl(PROC_REAP_ACQUIRE/RELEASE,...)`]: https://man.freebsd.org/cgi/man.cgi?query=procctl&sektion=2
#[inline]
pub fn set_reaper_status(reaper: bool) -> io::Result<()> {
unsafe {
procctl(
if reaper {
PROC_REAP_ACQUIRE
} else {
PROC_REAP_RELEASE
},
None,
ptr::null_mut(),
)
}
}
const PROC_REAP_STATUS: c_int = 4;
bitflags! {
/// `REAPER_STATUS_*`.
#[repr(transparent)]
#[derive(Copy, Clone, Eq, PartialEq, Hash, Debug)]
pub struct ReaperStatusFlags: c_uint {
/// The process has acquired reaper status.
const OWNED = 1;
/// The process is the root of the reaper tree (pid 1).
const REALINIT = 2;
///
const _ = !0;
}
}
#[repr(C)]
struct procctl_reaper_status {
rs_flags: c_uint,
rs_children: c_uint,
rs_descendants: c_uint,
rs_reaper: RawPid,
rs_pid: RawPid,
rs_pad0: [c_uint; 15],
}
/// Reaper status as returned by [`get_reaper_status`].
#[derive(Copy, Clone, Debug, Eq, PartialEq)]
pub struct ReaperStatus {
/// The flags.
pub flags: ReaperStatusFlags,
/// The number of children of the reaper among the descendants.
pub children: usize,
/// The total number of descendants of the reaper(s), not counting
/// descendants of the reaper in the subtree.
pub descendants: usize,
/// The pid of the reaper for the specified process id.
pub reaper: Pid,
/// The pid of one reaper child if there are any descendants.
pub pid: Option,
}
/// Get information about the reaper of the specified process (or the process
/// itself if it is a reaper).
///
/// # References
/// - [FreeBSD: `procctl(PROC_REAP_STATUS,...)`]
///
/// [FreeBSD: `procctl(PROC_REAP_STATUS,...)`]: https://man.freebsd.org/cgi/man.cgi?query=procctl&sektion=2
#[inline]
pub fn get_reaper_status(process: ProcSelector) -> io::Result {
let raw = unsafe { procctl_get_optional::(PROC_REAP_STATUS, process) }?;
Ok(ReaperStatus {
flags: ReaperStatusFlags::from_bits_retain(raw.rs_flags),
children: raw.rs_children as _,
descendants: raw.rs_descendants as _,
reaper: Pid::from_raw(raw.rs_reaper).ok_or(io::Errno::RANGE)?,
pid: if raw.rs_pid == -1 {
None
} else {
Some(Pid::from_raw(raw.rs_pid).ok_or(io::Errno::RANGE)?)
},
})
}
const PROC_REAP_GETPIDS: c_int = 5;
bitflags! {
/// `REAPER_PIDINFO_*`.
#[repr(transparent)]
#[derive(Copy, Clone, Eq, PartialEq, Hash, Debug)]
pub struct PidInfoFlags: c_uint {
/// This structure was filled by the kernel.
const VALID = 1;
/// The pid field identifies a direct child of the reaper.
const CHILD = 2;
/// The reported process is itself a reaper. Descendants of a
/// subordinate reaper are not reported.
const REAPER = 4;
/// The reported process is in the zombie state.
const ZOMBIE = 8;
/// The reported process is stopped by
/// [`Signal::Stop`]/[`Signal::Tstp`].
const STOPPED = 16;
/// The reported process is in the process of exiting.
const EXITING = 32;
}
}
#[repr(C)]
#[derive(Default, Clone)]
struct procctl_reaper_pidinfo {
pi_pid: RawPid,
pi_subtree: RawPid,
pi_flags: c_uint,
pi_pad0: [c_uint; 15],
}
#[repr(C)]
struct procctl_reaper_pids {
rp_count: c_uint,
rp_pad0: [c_uint; 15],
rp_pids: *mut procctl_reaper_pidinfo,
}
/// A child process of a reaper.
#[derive(Copy, Clone, Debug, Eq, PartialEq)]
pub struct PidInfo {
/// The flags of the process.
pub flags: PidInfoFlags,
/// The pid of the process.
pub pid: Pid,
/// The pid of the child of the reaper which is the (grand-..)parent of the
/// process.
pub subtree: Pid,
}
/// Get the list of descendants of the specified reaper process.
///
/// # References
/// - [FreeBSD: `procctl(PROC_REAP_GETPIDS,...)`]
///
/// [FreeBSD: `procctl(PROC_REAP_GETPIDS,...)`]: https://man.freebsd.org/cgi/man.cgi?query=procctl&sektion=2
#[cfg(feature = "alloc")]
pub fn get_reaper_pids(process: ProcSelector) -> io::Result> {
// Sadly no better way to guarantee that we get all the results than to
// allocate ~8MB of memory..
const PID_MAX: usize = 99999;
let mut pids: Vec = vec![Default::default(); PID_MAX];
let mut pinfo = procctl_reaper_pids {
rp_count: PID_MAX as _,
rp_pad0: [0; 15],
rp_pids: pids.as_mut_slice().as_mut_ptr(),
};
unsafe { procctl(PROC_REAP_GETPIDS, process, as_mut_ptr(&mut pinfo).cast())? };
let mut result = Vec::new();
for raw in pids.into_iter() {
let flags = PidInfoFlags::from_bits_retain(raw.pi_flags);
if !flags.contains(PidInfoFlags::VALID) {
break;
}
result.push(PidInfo {
flags,
subtree: Pid::from_raw(raw.pi_subtree).ok_or(io::Errno::RANGE)?,
pid: Pid::from_raw(raw.pi_pid).ok_or(io::Errno::RANGE)?,
});
}
Ok(result)
}
const PROC_REAP_KILL: c_int = 6;
bitflags! {
/// `REAPER_KILL_*`.
#[repr(transparent)]
#[derive(Copy, Clone, Eq, PartialEq, Hash, Debug)]
struct KillFlags: c_uint {
const CHILDREN = 1;
const SUBTREE = 2;
}
}
#[repr(C)]
struct procctl_reaper_kill {
rk_sig: c_int,
rk_flags: c_uint,
rk_subtree: RawPid,
rk_killed: c_uint,
rk_fpid: RawPid,
rk_pad0: [c_uint; 15],
}
/// Reaper status as returned by [`get_reaper_status`].
#[derive(Copy, Clone, Debug, Eq, PartialEq)]
pub struct KillResult {
/// The number of processes that were signalled.
pub killed: usize,
/// The pid of the first process that wasn't successfully signalled.
pub first_failed: Option,
}
/// Deliver a signal to some subset of
///
/// # References
/// - [FreeBSD: `procctl(PROC_REAP_KILL,...)`]
///
/// [FreeBSD: `procctl(PROC_REAP_KILL,...)`]: https://man.freebsd.org/cgi/man.cgi?query=procctl&sektion=2
pub fn reaper_kill(
process: ProcSelector,
signal: Signal,
direct_children: bool,
subtree: Option,
) -> io::Result {
let mut flags = KillFlags::empty();
flags.set(KillFlags::CHILDREN, direct_children);
flags.set(KillFlags::SUBTREE, subtree.is_some());
let mut req = procctl_reaper_kill {
rk_sig: signal as c_int,
rk_flags: flags.bits(),
rk_subtree: subtree.map(|p| p.as_raw_nonzero().into()).unwrap_or(0),
rk_killed: 0,
rk_fpid: 0,
rk_pad0: [0; 15],
};
unsafe { procctl(PROC_REAP_KILL, process, as_mut_ptr(&mut req).cast())? };
Ok(KillResult {
killed: req.rk_killed as _,
first_failed: Pid::from_raw(req.rk_fpid),
})
}
//
// PROC_TRAPCAP_STATUS/PROC_TRAPCAP_CTL
//
const PROC_TRAPCAP_CTL: c_int = 9;
const PROC_TRAPCAP_CTL_ENABLE: i32 = 1;
const PROC_TRAPCAP_CTL_DISABLE: i32 = 2;
/// `PROC_TRAPCAP_CTL_*`.
#[derive(Copy, Clone, Debug, Eq, PartialEq)]
#[repr(i32)]
pub enum TrapCapBehavior {
/// Disable the [`Signal::Trap`] signal delivery on capability mode access
/// violations.
Disable = PROC_TRAPCAP_CTL_DISABLE,
/// Enable the [`Signal::Trap`] signal delivery on capability mode access
/// violations.
Enable = PROC_TRAPCAP_CTL_ENABLE,
}
/// Set the current value of the capability mode violation trapping behavior.
/// If this behavior is enabled, the kernel would deliver a [`Signal::Trap`]
/// signal on any return from a system call that would result in a
/// [`io::Errno::NOTCAPABLE`]` or [`io::Errno::CAPMODE`] error.
///
/// This behavior is inherited by the children of the process and is kept
/// across `execve` calls.
///
/// # References
/// - [FreeBSD: `procctl(PROC_TRAPCAP_CTL,...)`]
///
/// [FreeBSD: `procctl(PROC_TRAPCAP_CTL,...)`]: https://man.freebsd.org/cgi/man.cgi?query=procctl&sektion=2
#[inline]
pub fn set_trap_cap_behavior(process: ProcSelector, config: TrapCapBehavior) -> io::Result<()> {
let config = config as c_int;
unsafe { procctl_set::(PROC_TRAPCAP_CTL, process, &config) }
}
const PROC_TRAPCAP_STATUS: c_int = 10;
/// Get the current value of the capability mode violation trapping behavior.
///
/// # References
/// - [FreeBSD: `procctl(PROC_TRAPCAP_STATUS,...)`]
///
/// [FreeBSD: `procctl(PROC_TRAPCAP_STATUS,...)`]: https://man.freebsd.org/cgi/man.cgi?query=procctl&sektion=2
#[inline]
pub fn trap_cap_behavior(process: ProcSelector) -> io::Result {
let val = unsafe { procctl_get_optional::(PROC_TRAPCAP_STATUS, process) }?;
match val {
PROC_TRAPCAP_CTL_DISABLE => Ok(TrapCapBehavior::Disable),
PROC_TRAPCAP_CTL_ENABLE => Ok(TrapCapBehavior::Enable),
_ => Err(io::Errno::RANGE),
}
}
//
// PROC_NO_NEW_PRIVS_STATUS/PROC_NO_NEW_PRIVS_CTL
//
const PROC_NO_NEW_PRIVS_CTL: c_int = 19;
const PROC_NO_NEW_PRIVS_ENABLE: c_int = 1;
/// Enable the `no_new_privs` mode that ignores SUID and SGID bits on `execve`
/// in the specified process and its future descendants.
///
/// This is similar to `set_no_new_privs` on Linux, with the exception that on
/// FreeBSD there is no argument `no_new_privs` argument as it's only possible
/// to enable this mode and there's no going back.
///
/// # References
/// - [Linux: `prctl(PR_SET_NO_NEW_PRIVS,...)`]
/// - [FreeBSD: `procctl(PROC_NO_NEW_PRIVS_CTL,...)`]
///
/// [Linux: `prctl(PR_SET_NO_NEW_PRIVS,...)`]: https://man7.org/linux/man-pages/man2/prctl.2.html
/// [FreeBSD: `procctl(PROC_NO_NEW_PRIVS_CTL,...)`]: https://man.freebsd.org/cgi/man.cgi?query=procctl&sektion=2
#[inline]
pub fn set_no_new_privs(process: ProcSelector) -> io::Result<()> {
unsafe { procctl_set::(PROC_NO_NEW_PRIVS_CTL, process, &PROC_NO_NEW_PRIVS_ENABLE) }
}
const PROC_NO_NEW_PRIVS_STATUS: c_int = 20;
/// Check the `no_new_privs` mode of the specified process.
///
/// # References
/// - [Linux: `prctl(PR_GET_NO_NEW_PRIVS,...)`]
/// - [FreeBSD: `procctl(PROC_NO_NEW_PRIVS_STATUS,...)`]
///
/// [Linux: `prctl(PR_GET_NO_NEW_PRIVS,...)`]: https://man7.org/linux/man-pages/man2/prctl.2.html
/// [FreeBSD: `procctl(PROC_NO_NEW_PRIVS_STATUS,...)`]: https://man.freebsd.org/cgi/man.cgi?query=procctl&sektion=2
#[inline]
pub fn no_new_privs(process: ProcSelector) -> io::Result {
unsafe { procctl_get_optional::(PROC_NO_NEW_PRIVS_STATUS, process) }
.map(|x| x == PROC_NO_NEW_PRIVS_ENABLE)
}