bsd.rs - mozsearch

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use crate::errno::Errno;

use crate::sys::signal::Signal;

use crate::unistd::Pid;

use crate::Result;

use cfg_if::cfg_if;

use libc::{self, c_int};

use std::ptr;

pub type RequestType = c_int;

cfg_if! {

    if #[cfg(any(freebsdlike, apple_targets, target_os = "openbsd"))] {

        #[doc(hidden)]

        pub type AddressType = *mut ::libc::c_char;

    } else {

        #[doc(hidden)]

        pub type AddressType = *mut ::libc::c_void;

libc_enum! {

    #[repr(i32)]

    /// Ptrace Request enum defining the action to be taken.

    #[non_exhaustive]

    pub enum Request {

        PT_TRACE_ME,

        PT_READ_I,

        PT_READ_D,

        #[cfg(apple_targets)]

        PT_READ_U,

        PT_WRITE_I,

        PT_WRITE_D,

        #[cfg(apple_targets)]

        PT_WRITE_U,

        PT_CONTINUE,

        PT_KILL,

        #[cfg(any(any(freebsdlike, apple_targets),

                  all(target_os = "openbsd", target_arch = "x86_64"),

                  all(target_os = "netbsd", any(target_arch = "x86_64",

                                                target_arch = "powerpc"))))]

        PT_STEP,

        PT_ATTACH,

        PT_DETACH,

        #[cfg(apple_targets)]

        PT_SIGEXC,

        #[cfg(apple_targets)]

        PT_THUPDATE,

        #[cfg(apple_targets)]

        PT_ATTACHEXC

unsafe fn ptrace_other(

    request: Request,

    pid: Pid,

    addr: AddressType,

    data: c_int,

) -> Result<c_int> {

    unsafe {

        Errno::result(libc::ptrace(

            request as RequestType,

            libc::pid_t::from(pid),

            addr,

            data,

))

        .map(|_| 0)

/// Sets the process as traceable, as with `ptrace(PT_TRACEME, ...)`

///

/// Indicates that this process is to be traced by its parent.

/// This is the only ptrace request to be issued by the tracee.

pub fn traceme() -> Result<()> {

    unsafe {

        ptrace_other(Request::PT_TRACE_ME, Pid::from_raw(0), ptr::null_mut(), 0)

            .map(drop)

/// Attach to a running process, as with `ptrace(PT_ATTACH, ...)`

///

/// Attaches to the process specified by `pid`, making it a tracee of the calling process.

pub fn attach(pid: Pid) -> Result<()> {

    unsafe {

        ptrace_other(Request::PT_ATTACH, pid, ptr::null_mut(), 0).map(drop)

/// Detaches the current running process, as with `ptrace(PT_DETACH, ...)`

///

/// Detaches from the process specified by `pid` allowing it to run freely, optionally delivering a

/// signal specified by `sig`.

pub fn detach<T: Into<Option<Signal>>>(pid: Pid, sig: T) -> Result<()> {

    let data = match sig.into() {

        Some(s) => s as c_int,

        None => 0,

};

    unsafe {

        ptrace_other(Request::PT_DETACH, pid, ptr::null_mut(), data).map(drop)

/// Restart the stopped tracee process, as with `ptrace(PTRACE_CONT, ...)`

///

/// Continues the execution of the process with PID `pid`, optionally

/// delivering a signal specified by `sig`.

pub fn cont<T: Into<Option<Signal>>>(pid: Pid, sig: T) -> Result<()> {

    let data = match sig.into() {

        Some(s) => s as c_int,

        None => 0,

};

    unsafe {

        // Ignore the useless return value

        ptrace_other(Request::PT_CONTINUE, pid, 1 as AddressType, data)

            .map(drop)

/// Issues a kill request as with `ptrace(PT_KILL, ...)`

///

/// This request is equivalent to `ptrace(PT_CONTINUE, ..., SIGKILL);`

pub fn kill(pid: Pid) -> Result<()> {

    unsafe {

        ptrace_other(Request::PT_KILL, pid, 0 as AddressType, 0).map(drop)

/// Move the stopped tracee process forward by a single step as with

/// `ptrace(PT_STEP, ...)`

///

/// Advances the execution of the process with PID `pid` by a single step optionally delivering a

/// signal specified by `sig`.

///

/// # Example

/// ```rust

/// use nix::sys::ptrace::step;

/// use nix::unistd::Pid;

/// use nix::sys::signal::Signal;

/// use nix::sys::wait::*;

/// // If a process changes state to the stopped state because of a SIGUSR1

/// // signal, this will step the process forward and forward the user

/// // signal to the stopped process

/// match waitpid(Pid::from_raw(-1), None) {

///     Ok(WaitStatus::Stopped(pid, Signal::SIGUSR1)) => {

///         let _ = step(pid, Signal::SIGUSR1);

///     }

///     _ => {},

/// }

/// ```

#[cfg(any(

    any(freebsdlike, apple_targets),

    all(target_os = "openbsd", target_arch = "x86_64"),

    all(

        target_os = "netbsd",

        any(target_arch = "x86_64", target_arch = "powerpc")

))]

pub fn step<T: Into<Option<Signal>>>(pid: Pid, sig: T) -> Result<()> {

    let data = match sig.into() {

        Some(s) => s as c_int,

        None => 0,

};

    unsafe {

        ptrace_other(Request::PT_STEP, pid, ptr::null_mut(), data).map(drop)

/// Reads a word from a processes memory at the given address

// Technically, ptrace doesn't dereference the pointer.  It passes it directly

// to the kernel.

#[allow(clippy::not_unsafe_ptr_arg_deref)]

pub fn read(pid: Pid, addr: AddressType) -> Result<c_int> {

    unsafe {

        // Traditionally there was a difference between reading data or

        // instruction memory but not in modern systems.

        ptrace_other(Request::PT_READ_D, pid, addr, 0)

/// Writes a word into the processes memory at the given address

// Technically, ptrace doesn't dereference the pointer.  It passes it directly

// to the kernel.

#[allow(clippy::not_unsafe_ptr_arg_deref)]

pub fn write(pid: Pid, addr: AddressType, data: c_int) -> Result<()> {

    unsafe { ptrace_other(Request::PT_WRITE_D, pid, addr, data).map(drop) }