redox: convert to target_family unix

1 files changed, 0 insertions, 609 deletions

diff --git a/src/libstd/sys/redox/process.rs b/src/libstd/sys/redox/process.rs
deleted file mode 100644
index 2a553b2c93b..00000000000
--- a/src/libstd/sys/redox/process.rs
+++ /dev/null
@@ -1,609 +0,0 @@
-use crate::env::{self, split_paths};
-use crate::ffi::{CStr, OsStr};
-use crate::fmt;
-use crate::fs::File;
-use crate::io::{self, prelude::*, BufReader, Error, ErrorKind, SeekFrom};
-use crate::os::unix::ffi::OsStrExt;
-use crate::path::{Path, PathBuf};
-use crate::ptr;
-use crate::sys::ext::fs::MetadataExt;
-use crate::sys::ext::io::AsRawFd;
-use crate::sys::fd::FileDesc;
-use crate::sys::fs::{File as SysFile, OpenOptions};
-use crate::sys::os::{ENV_LOCK, environ};
-use crate::sys::pipe::{self, AnonPipe};
-use crate::sys::{cvt, syscall};
-use crate::sys_common::process::{CommandEnv, DefaultEnvKey};
-
-use libc::{EXIT_SUCCESS, EXIT_FAILURE};
-
-////////////////////////////////////////////////////////////////////////////////
-// Command
-////////////////////////////////////////////////////////////////////////////////
-
-pub struct Command {
-    // Currently we try hard to ensure that the call to `.exec()` doesn't
-    // actually allocate any memory. While many platforms try to ensure that
-    // memory allocation works after a fork in a multithreaded process, it's
-    // been observed to be buggy and somewhat unreliable, so we do our best to
-    // just not do it at all!
-    //
-    // Along those lines, the `argv` and `envp` raw pointers here are exactly
-    // what's gonna get passed to `execvp`. The `argv` array starts with the
-    // `program` and ends with a NULL, and the `envp` pointer, if present, is
-    // also null-terminated.
-    //
-    // Right now we don't support removing arguments, so there's no much fancy
-    // support there, but we support adding and removing environment variables,
-    // so a side table is used to track where in the `envp` array each key is
-    // located. Whenever we add a key we update it in place if it's already
-    // present, and whenever we remove a key we update the locations of all
-    // other keys.
-    program: String,
-    args: Vec<String>,
-    env: CommandEnv<DefaultEnvKey>,
-
-    cwd: Option<String>,
-    uid: Option<u32>,
-    gid: Option<u32>,
-    saw_nul: bool,
-    closures: Vec<Box<dyn FnMut() -> io::Result<()> + Send + Sync>>,
-    stdin: Option<Stdio>,
-    stdout: Option<Stdio>,
-    stderr: Option<Stdio>,
-}
-
-// passed back to std::process with the pipes connected to the child, if any
-// were requested
-pub struct StdioPipes {
-    pub stdin: Option<AnonPipe>,
-    pub stdout: Option<AnonPipe>,
-    pub stderr: Option<AnonPipe>,
-}
-
-// passed to do_exec() with configuration of what the child stdio should look
-// like
-struct ChildPipes {
-    stdin: ChildStdio,
-    stdout: ChildStdio,
-    stderr: ChildStdio,
-}
-
-enum ChildStdio {
-    Inherit,
-    Explicit(usize),
-    Owned(FileDesc),
-}
-
-pub enum Stdio {
-    Inherit,
-    Null,
-    MakePipe,
-    Fd(FileDesc),
-}
-
-impl Command {
-    pub fn new(program: &OsStr) -> Command {
-        Command {
-            program: program.to_str().unwrap().to_owned(),
-            args: Vec::new(),
-            env: Default::default(),
-            cwd: None,
-            uid: None,
-            gid: None,
-            saw_nul: false,
-            closures: Vec::new(),
-            stdin: None,
-            stdout: None,
-            stderr: None,
-        }
-    }
-
-    pub fn arg(&mut self, arg: &OsStr) {
-        self.args.push(arg.to_str().unwrap().to_owned());
-    }
-
-    pub fn env_mut(&mut self) -> &mut CommandEnv<DefaultEnvKey> {
-        &mut self.env
-    }
-
-    pub fn cwd(&mut self, dir: &OsStr) {
-        self.cwd = Some(dir.to_str().unwrap().to_owned());
-    }
-    pub fn uid(&mut self, id: u32) {
-        self.uid = Some(id);
-    }
-    pub fn gid(&mut self, id: u32) {
-        self.gid = Some(id);
-    }
-
-    pub unsafe fn pre_exec(
-        &mut self,
-        f: Box<dyn FnMut() -> io::Result<()> + Send + Sync>,
-    ) {
-        self.closures.push(f);
-    }
-
-    pub fn stdin(&mut self, stdin: Stdio) {
-        self.stdin = Some(stdin);
-    }
-    pub fn stdout(&mut self, stdout: Stdio) {
-        self.stdout = Some(stdout);
-    }
-    pub fn stderr(&mut self, stderr: Stdio) {
-        self.stderr = Some(stderr);
-    }
-
-    pub fn spawn(&mut self, default: Stdio, needs_stdin: bool)
-                 -> io::Result<(Process, StdioPipes)> {
-         const CLOEXEC_MSG_FOOTER: &[u8] = b"NOEX";
-
-         if self.saw_nul {
-             return Err(io::Error::new(ErrorKind::InvalidInput,
-                                       "nul byte found in provided data"));
-         }
-
-         let (ours, theirs) = self.setup_io(default, needs_stdin)?;
-         let (input, output) = pipe::anon_pipe()?;
-
-         let pid = unsafe {
-             match cvt(syscall::clone(0))? {
-                 0 => {
-                     drop(input);
-                     let Err(err) = self.do_exec(theirs);
-                     let errno = err.raw_os_error().unwrap_or(syscall::EINVAL) as u32;
-                     let bytes = [
-                         (errno >> 24) as u8,
-                         (errno >> 16) as u8,
-                         (errno >>  8) as u8,
-                         (errno >>  0) as u8,
-                         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
-                     assert!(output.write(&bytes).is_ok());
-                     let _ = syscall::exit(1);
-                     panic!("failed to exit");
-                 }
-                 n => n,
-             }
-         };
-
-         let mut p = Process { pid: pid, status: None };
-         drop(output);
-         let mut bytes = [0; 8];
-
-         // loop to handle EINTR
-         loop {
-             match input.read(&mut bytes) {
-                 Ok(0) => return Ok((p, ours)),
-                 Ok(8) => {
-                     assert!(combine(CLOEXEC_MSG_FOOTER) == combine(&bytes[4.. 8]),
-                             "Validation on the CLOEXEC pipe failed: {:?}", bytes);
-                     let errno = combine(&bytes[0.. 4]);
-                     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")
-                 }
-             }
-         }
-
-         fn combine(arr: &[u8]) -> i32 {
-             let a = arr[0] as u32;
-             let b = arr[1] as u32;
-             let c = arr[2] as u32;
-             let d = arr[3] as u32;
-
-             ((a << 24) | (b << 16) | (c << 8) | (d << 0)) as i32
-         }
-    }
-
-    pub fn exec(&mut self, default: Stdio) -> io::Error {
-        if self.saw_nul {
-            return io::Error::new(ErrorKind::InvalidInput,
-                                  "nul byte found in provided data")
-        }
-
-        match self.setup_io(default, true) {
-            Ok((_, theirs)) => unsafe {
-                let Err(e) = self.do_exec(theirs);
-                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 syscall::exit)
-    unsafe fn do_exec(&mut self, stdio: ChildPipes) -> Result<!, io::Error> {
-        if let Some(fd) = stdio.stderr.fd() {
-            cvt(syscall::dup2(fd, 2, &[]))?;
-            let mut flags = cvt(syscall::fcntl(2, syscall::F_GETFD, 0))?;
-            flags &= ! syscall::O_CLOEXEC;
-            cvt(syscall::fcntl(2, syscall::F_SETFD, flags))?;
-        }
-        if let Some(fd) = stdio.stdout.fd() {
-            cvt(syscall::dup2(fd, 1, &[]))?;
-            let mut flags = cvt(syscall::fcntl(1, syscall::F_GETFD, 0))?;
-            flags &= ! syscall::O_CLOEXEC;
-            cvt(syscall::fcntl(1, syscall::F_SETFD, flags))?;
-        }
-        if let Some(fd) = stdio.stdin.fd() {
-            cvt(syscall::dup2(fd, 0, &[]))?;
-            let mut flags = cvt(syscall::fcntl(0, syscall::F_GETFD, 0))?;
-            flags &= ! syscall::O_CLOEXEC;
-            cvt(syscall::fcntl(0, syscall::F_SETFD, flags))?;
-        }
-
-        if let Some(g) = self.gid {
-            cvt(syscall::setregid(g as usize, g as usize))?;
-        }
-        if let Some(u) = self.uid {
-            cvt(syscall::setreuid(u as usize, u as usize))?;
-        }
-        if let Some(ref cwd) = self.cwd {
-            cvt(syscall::chdir(cwd))?;
-        }
-
-        for callback in self.closures.iter_mut() {
-            callback()?;
-        }
-
-        self.env.apply();
-
-        let program = if self.program.contains(':') || self.program.contains('/') {
-            Some(PathBuf::from(&self.program))
-        } else if let Ok(path_env) = env::var("PATH") {
-            let mut program = None;
-            for mut path in split_paths(&path_env) {
-                path.push(&self.program);
-                if path.exists() {
-                    program = Some(path);
-                    break;
-                }
-            }
-            program
-        } else {
-            None
-        };
-
-        let mut file = if let Some(program) = program {
-            File::open(program.as_os_str())?
-        } else {
-            return Err(io::Error::from_raw_os_error(syscall::ENOENT));
-        };
-
-        // Push all the arguments
-        let mut args: Vec<[usize; 2]> = Vec::with_capacity(1 + self.args.len());
-
-        let interpreter = {
-            let mut reader = BufReader::new(&file);
-
-            let mut shebang = [0; 2];
-            let mut read = 0;
-            loop {
-                match reader.read(&mut shebang[read..])? {
-                    0 => break,
-                    n => read += n,
-                }
-            }
-
-            if &shebang == b"#!" {
-                // This is an interpreted script.
-                // First of all, since we'll be passing another file to
-                // fexec(), we need to manually check that we have permission
-                // to execute this file:
-                let uid = cvt(syscall::getuid())?;
-                let gid = cvt(syscall::getgid())?;
-                let meta = file.metadata()?;
-
-                let mode = if uid == meta.uid() as usize {
-                    meta.mode() >> 3*2 & 0o7
-                } else if gid == meta.gid() as usize {
-                    meta.mode() >> 3*1 & 0o7
-                } else {
-                    meta.mode() & 0o7
-                };
-                if mode & 1 == 0 {
-                    return Err(io::Error::from_raw_os_error(syscall::EPERM));
-                }
-
-                // Second of all, we need to actually read which interpreter it wants
-                let mut interpreter = Vec::new();
-                reader.read_until(b'\n', &mut interpreter)?;
-                // Pop one trailing newline, if any
-                if interpreter.ends_with(&[b'\n']) {
-                    interpreter.pop().unwrap();
-                }
-
-                // FIXME: Here we could just reassign `file` directly, if it
-                // wasn't for lexical lifetimes. Remove the whole `let
-                // interpreter = { ... };` hack once NLL lands.
-                // NOTE: Although DO REMEMBER to make sure the interpreter path
-                // still lives long enough to reach fexec.
-                Some(interpreter)
-            } else {
-                None
-            }
-        };
-        if let Some(ref interpreter) = interpreter {
-            let path: &OsStr = OsStr::from_bytes(&interpreter);
-            file = File::open(path)?;
-
-            args.push([interpreter.as_ptr() as usize, interpreter.len()]);
-        } else {
-            file.seek(SeekFrom::Start(0))?;
-        }
-
-        args.push([self.program.as_ptr() as usize, self.program.len()]);
-        args.extend(self.args.iter().map(|arg| [arg.as_ptr() as usize, arg.len()]));
-
-        // Push all the variables
-        let mut vars: Vec<[usize; 2]> = Vec::new();
-        {
-            let _guard = ENV_LOCK.lock();
-            let mut environ = *environ();
-            while *environ != ptr::null() {
-                let var = CStr::from_ptr(*environ).to_bytes();
-                vars.push([var.as_ptr() as usize, var.len()]);
-                environ = environ.offset(1);
-            }
-        }
-
-        if let Err(err) = syscall::fexec(file.as_raw_fd(), &args, &vars) {
-            Err(io::Error::from_raw_os_error(err.errno as i32))
-        } else {
-            panic!("return from exec without err");
-        }
-    }
-
-    fn setup_io(&self, default: Stdio, needs_stdin: bool)
-                -> io::Result<(StdioPipes, ChildPipes)> {
-        let null = Stdio::Null;
-        let default_stdin = if needs_stdin {&default} else {&null};
-        let stdin = self.stdin.as_ref().unwrap_or(default_stdin);
-        let stdout = self.stdout.as_ref().unwrap_or(&default);
-        let stderr = self.stderr.as_ref().unwrap_or(&default);
-        let (their_stdin, our_stdin) = stdin.to_child_stdio(true)?;
-        let (their_stdout, our_stdout) = stdout.to_child_stdio(false)?;
-        let (their_stderr, our_stderr) = stderr.to_child_stdio(false)?;
-        let ours = StdioPipes {
-            stdin: our_stdin,
-            stdout: our_stdout,
-            stderr: our_stderr,
-        };
-        let theirs = ChildPipes {
-            stdin: their_stdin,
-            stdout: their_stdout,
-            stderr: their_stderr,
-        };
-        Ok((ours, theirs))
-    }
-}
-
-impl Stdio {
-    fn to_child_stdio(&self, readable: bool)
-                      -> io::Result<(ChildStdio, Option<AnonPipe>)> {
-        match *self {
-            Stdio::Inherit => Ok((ChildStdio::Inherit, None)),
-
-            // Make sure that the source descriptors are not an stdio
-            // descriptor, otherwise the order which we set the child's
-            // descriptors may blow away a descriptor which we are hoping to
-            // save. For example, suppose we want the child's stderr to be the
-            // parent's stdout, and the child's stdout to be the parent's
-            // stderr. No matter which we dup first, the second will get
-            // overwritten prematurely.
-            Stdio::Fd(ref fd) => {
-                if fd.raw() <= 2 {
-                    Ok((ChildStdio::Owned(fd.duplicate()?), None))
-                } else {
-                    Ok((ChildStdio::Explicit(fd.raw()), None))
-                }
-            }
-
-            Stdio::MakePipe => {
-                let (reader, writer) = pipe::anon_pipe()?;
-                let (ours, theirs) = if readable {
-                    (writer, reader)
-                } else {
-                    (reader, writer)
-                };
-                Ok((ChildStdio::Owned(theirs.into_fd()), Some(ours)))
-            }
-
-            Stdio::Null => {
-                let mut opts = OpenOptions::new();
-                opts.read(readable);
-                opts.write(!readable);
-                let fd = SysFile::open(Path::new("null:"), &opts)?;
-                Ok((ChildStdio::Owned(fd.into_fd()), None))
-            }
-        }
-    }
-}
-
-impl From<AnonPipe> for Stdio {
-    fn from(pipe: AnonPipe) -> Stdio {
-        Stdio::Fd(pipe.into_fd())
-    }
-}
-
-impl From<SysFile> for Stdio {
-    fn from(file: SysFile) -> Stdio {
-        Stdio::Fd(file.into_fd())
-    }
-}
-
-impl ChildStdio {
-    fn fd(&self) -> Option<usize> {
-        match *self {
-            ChildStdio::Inherit => None,
-            ChildStdio::Explicit(fd) => Some(fd),
-            ChildStdio::Owned(ref fd) => Some(fd.raw()),
-        }
-    }
-}
-
-impl fmt::Debug for Command {
-    fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
-        write!(f, "{:?}", self.program)?;
-        for arg in &self.args {
-            write!(f, " {:?}", arg)?;
-        }
-        Ok(())
-    }
-}
-
-////////////////////////////////////////////////////////////////////////////////
-// Processes
-////////////////////////////////////////////////////////////////////////////////
-
-/// Unix exit statuses
-#[derive(PartialEq, Eq, Clone, Copy, Debug)]
-pub struct ExitStatus(i32);
-
-impl ExitStatus {
-    fn exited(&self) -> bool {
-        self.0 & 0x7F == 0
-    }
-
-    pub fn success(&self) -> bool {
-        self.code() == Some(0)
-    }
-
-    pub fn code(&self) -> Option<i32> {
-        if self.exited() {
-            Some((self.0 >> 8) & 0xFF)
-        } else {
-            None
-        }
-    }
-
-    pub fn signal(&self) -> Option<i32> {
-        if !self.exited() {
-            Some(self.0 & 0x7F)
-        } else {
-            None
-        }
-    }
-}
-
-impl From<i32> for ExitStatus {
-    fn from(a: i32) -> 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 code: {}", code)
-        } else {
-            let signal = self.signal().unwrap();
-            write!(f, "signal: {}", signal)
-        }
-    }
-}
-
-#[derive(PartialEq, Eq, Clone, Copy, Debug)]
-pub struct ExitCode(u8);
-
-impl ExitCode {
-    pub const SUCCESS: ExitCode = ExitCode(EXIT_SUCCESS as _);
-    pub const FAILURE: ExitCode = ExitCode(EXIT_FAILURE as _);
-
-    pub fn as_i32(&self) -> i32 {
-        self.0 as i32
-    }
-}
-
-/// The unique ID of the process (this should never be negative).
-pub struct Process {
-    pid: usize,
-    status: Option<ExitStatus>,
-}
-
-impl Process {
-    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(ErrorKind::InvalidInput,
-                           "invalid argument: can't kill an exited process"))
-        } else {
-            cvt(syscall::kill(self.pid, syscall::SIGKILL))?;
-            Ok(())
-        }
-    }
-
-    pub fn wait(&mut self) -> io::Result<ExitStatus> {
-        if let Some(status) = self.status {
-            return Ok(status)
-        }
-        let mut status = 0;
-        cvt(syscall::waitpid(self.pid, &mut status, 0))?;
-        self.status = Some(ExitStatus(status as i32));
-        Ok(ExitStatus(status as i32))
-    }
-
-    pub fn try_wait(&mut self) -> io::Result<Option<ExitStatus>> {
-        if let Some(status) = self.status {
-            return Ok(Some(status))
-        }
-        let mut status = 0;
-        let pid = cvt(syscall::waitpid(self.pid, &mut status, syscall::WNOHANG))?;
-        if pid == 0 {
-            Ok(None)
-        } else {
-            self.status = Some(ExitStatus(status as i32));
-            Ok(Some(ExitStatus(status as i32)))
-        }
-    }
-}