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|
use nix::fcntl::{fcntl, FcntlArg, FdFlag, OFlag};
use nix::unistd::*;
use nix::unistd::ForkResult::*;
use nix::sys::signal::{SaFlags, SigAction, SigHandler, SigSet, Signal, sigaction};
use nix::sys::wait::*;
use nix::sys::stat::{self, Mode, SFlag};
use std::{self, env, iter};
use std::ffi::CString;
use std::fs::File;
use std::io::Write;
use std::os::unix::prelude::*;
use tempfile::{self, tempfile};
use libc::{self, _exit, off_t};
#[test]
fn test_fork_and_waitpid() {
#[allow(unused_variables)]
let m = ::FORK_MTX.lock().expect("Mutex got poisoned by another test");
// Safe: Child only calls `_exit`, which is signal-safe
match fork().expect("Error: Fork Failed") {
Child => unsafe { _exit(0) },
Parent { child } => {
// assert that child was created and pid > 0
let child_raw: ::libc::pid_t = child.into();
assert!(child_raw > 0);
let wait_status = waitpid(child, None);
match wait_status {
// assert that waitpid returned correct status and the pid is the one of the child
Ok(WaitStatus::Exited(pid_t, _)) => assert!(pid_t == child),
// panic, must never happen
s @ Ok(_) => panic!("Child exited {:?}, should never happen", s),
// panic, waitpid should never fail
Err(s) => panic!("Error: waitpid returned Err({:?}", s)
}
},
}
}
#[test]
fn test_wait() {
// Grab FORK_MTX so wait doesn't reap a different test's child process
#[allow(unused_variables)]
let m = ::FORK_MTX.lock().expect("Mutex got poisoned by another test");
// Safe: Child only calls `_exit`, which is signal-safe
match fork().expect("Error: Fork Failed") {
Child => unsafe { _exit(0) },
Parent { child } => {
let wait_status = wait();
// just assert that (any) one child returns with WaitStatus::Exited
assert_eq!(wait_status, Ok(WaitStatus::Exited(child, 0)));
},
}
}
#[test]
fn test_mkstemp() {
let mut path = env::temp_dir();
path.push("nix_tempfile.XXXXXX");
let result = mkstemp(&path);
match result {
Ok((fd, path)) => {
close(fd).unwrap();
unlink(path.as_path()).unwrap();
},
Err(e) => panic!("mkstemp failed: {}", e)
}
}
#[test]
fn test_mkstemp_directory() {
// mkstemp should fail if a directory is given
assert!(mkstemp(&env::temp_dir()).is_err());
}
#[test]
fn test_mkfifo() {
let tempdir = tempfile::tempdir().unwrap();
let mkfifo_fifo = tempdir.path().join("mkfifo_fifo");
mkfifo(&mkfifo_fifo, Mode::S_IRUSR).unwrap();
let stats = stat::stat(&mkfifo_fifo).unwrap();
let typ = stat::SFlag::from_bits_truncate(stats.st_mode);
assert!(typ == SFlag::S_IFIFO);
}
#[test]
fn test_mkfifo_directory() {
// mkfifo should fail if a directory is given
assert!(mkfifo(&env::temp_dir(), Mode::S_IRUSR).is_err());
}
#[test]
fn test_getpid() {
let pid: ::libc::pid_t = getpid().into();
let ppid: ::libc::pid_t = getppid().into();
assert!(pid > 0);
assert!(ppid > 0);
}
#[test]
fn test_getsid() {
let none_sid: ::libc::pid_t = getsid(None).unwrap().into();
let pid_sid: ::libc::pid_t = getsid(Some(getpid())).unwrap().into();
assert!(none_sid > 0);
assert!(none_sid == pid_sid);
}
#[cfg(any(target_os = "linux", target_os = "android"))]
mod linux_android {
use nix::unistd::gettid;
#[test]
fn test_gettid() {
let tid: ::libc::pid_t = gettid().into();
assert!(tid > 0);
}
}
#[test]
// `getgroups()` and `setgroups()` do not behave as expected on Apple platforms
#[cfg(not(any(target_os = "ios", target_os = "macos")))]
fn test_setgroups() {
// Skip this test when not run as root as `setgroups()` requires root.
if !Uid::current().is_root() {
let stderr = std::io::stderr();
let mut handle = stderr.lock();
writeln!(handle, "test_setgroups requires root privileges. Skipping test.").unwrap();
return;
}
#[allow(unused_variables)]
let m = ::GROUPS_MTX.lock().expect("Mutex got poisoned by another test");
// Save the existing groups
let old_groups = getgroups().unwrap();
// Set some new made up groups
let groups = [Gid::from_raw(123), Gid::from_raw(456)];
setgroups(&groups).unwrap();
let new_groups = getgroups().unwrap();
assert_eq!(new_groups, groups);
// Revert back to the old groups
setgroups(&old_groups).unwrap();
}
#[test]
// `getgroups()` and `setgroups()` do not behave as expected on Apple platforms
#[cfg(not(any(target_os = "ios", target_os = "macos")))]
fn test_initgroups() {
// Skip this test when not run as root as `initgroups()` and `setgroups()`
// require root.
if !Uid::current().is_root() {
let stderr = std::io::stderr();
let mut handle = stderr.lock();
writeln!(handle, "test_initgroups requires root privileges. Skipping test.").unwrap();
return;
}
#[allow(unused_variables)]
let m = ::GROUPS_MTX.lock().expect("Mutex got poisoned by another test");
// Save the existing groups
let old_groups = getgroups().unwrap();
// It doesn't matter if the root user is not called "root" or if a user
// called "root" doesn't exist. We are just checking that the extra,
// made-up group, `123`, is set.
// FIXME: Test the other half of initgroups' functionality: whether the
// groups that the user belongs to are also set.
let user = CString::new("root").unwrap();
let group = Gid::from_raw(123);
let group_list = getgrouplist(&user, group).unwrap();
assert!(group_list.contains(&group));
initgroups(&user, group).unwrap();
let new_groups = getgroups().unwrap();
assert_eq!(new_groups, group_list);
// Revert back to the old groups
setgroups(&old_groups).unwrap();
}
macro_rules! execve_test_factory(
($test_name:ident, $syscall:ident, $exe: expr $(, $pathname:expr, $flags:expr)*) => (
#[test]
fn $test_name() {
#[allow(unused_variables)]
let m = ::FORK_MTX.lock().expect("Mutex got poisoned by another test");
// The `exec`d process will write to `writer`, and we'll read that
// data from `reader`.
let (reader, writer) = pipe().unwrap();
// Safe: Child calls `exit`, `dup`, `close` and the provided `exec*` family function.
// NOTE: Technically, this makes the macro unsafe to use because you could pass anything.
// The tests make sure not to do that, though.
match fork().unwrap() {
Child => {
// Close stdout.
close(1).unwrap();
// Make `writer` be the stdout of the new process.
dup(writer).unwrap();
// exec!
$syscall(
$exe,
$(&CString::new($pathname).unwrap(), )*
&[CString::new(b"".as_ref()).unwrap(),
CString::new(b"-c".as_ref()).unwrap(),
CString::new(b"echo nix!!! && echo foo=$foo && echo baz=$baz"
.as_ref()).unwrap()],
&[CString::new(b"foo=bar".as_ref()).unwrap(),
CString::new(b"baz=quux".as_ref()).unwrap()]
$(, $flags)*).unwrap();
},
Parent { child } => {
// Wait for the child to exit.
waitpid(child, None).unwrap();
// Read 1024 bytes.
let mut buf = [0u8; 1024];
read(reader, &mut buf).unwrap();
// It should contain the things we printed using `/bin/sh`.
let string = String::from_utf8_lossy(&buf);
assert!(string.contains("nix!!!"));
assert!(string.contains("foo=bar"));
assert!(string.contains("baz=quux"));
}
}
}
)
);
cfg_if!{
if #[cfg(target_os = "android")] {
execve_test_factory!(test_execve, execve, &CString::new("/system/bin/sh").unwrap());
execve_test_factory!(test_fexecve, fexecve, File::open("/system/bin/sh").unwrap().into_raw_fd());
} else if #[cfg(any(target_os = "freebsd",
target_os = "linux",
target_os = "netbsd",
target_os = "openbsd"))] {
execve_test_factory!(test_execve, execve, &CString::new("/bin/sh").unwrap());
execve_test_factory!(test_fexecve, fexecve, File::open("/bin/sh").unwrap().into_raw_fd());
} else if #[cfg(any(target_os = "dragonfly",
target_os = "ios",
target_os = "macos"))] {
execve_test_factory!(test_execve, execve, &CString::new("/bin/sh").unwrap());
// No fexecve() on macos/ios and DragonFly.
}
}
cfg_if!{
if #[cfg(target_os = "android")] {
use nix::fcntl::AtFlags;
execve_test_factory!(test_execveat_empty, execveat, File::open("/system/bin/sh").unwrap().into_raw_fd(),
"", AtFlags::AT_EMPTY_PATH);
execve_test_factory!(test_execveat_relative, execveat, File::open("/system/bin/").unwrap().into_raw_fd(),
"./sh", AtFlags::empty());
execve_test_factory!(test_execveat_absolute, execveat, File::open("/").unwrap().into_raw_fd(),
"/system/bin/sh", AtFlags::empty());
} else if #[cfg(all(target_os = "linux"), any(target_arch ="x86_64", target_arch ="x86"))] {
use nix::fcntl::AtFlags;
execve_test_factory!(test_execveat_empty, execveat, File::open("/bin/sh").unwrap().into_raw_fd(),
"", AtFlags::AT_EMPTY_PATH);
execve_test_factory!(test_execveat_relative, execveat, File::open("/bin/").unwrap().into_raw_fd(),
"./sh", AtFlags::empty());
execve_test_factory!(test_execveat_absolute, execveat, File::open("/").unwrap().into_raw_fd(),
"/bin/sh", AtFlags::empty());
}
}
#[test]
fn test_fchdir() {
// fchdir changes the process's cwd
#[allow(unused_variables)]
let m = ::CWD_MTX.lock().expect("Mutex got poisoned by another test");
let tmpdir = tempfile::tempdir().unwrap();
let tmpdir_path = tmpdir.path().canonicalize().unwrap();
let tmpdir_fd = File::open(&tmpdir_path).unwrap().into_raw_fd();
assert!(fchdir(tmpdir_fd).is_ok());
assert_eq!(getcwd().unwrap(), tmpdir_path);
assert!(close(tmpdir_fd).is_ok());
}
#[test]
fn test_getcwd() {
// chdir changes the process's cwd
#[allow(unused_variables)]
let m = ::CWD_MTX.lock().expect("Mutex got poisoned by another test");
let tmpdir = tempfile::tempdir().unwrap();
let tmpdir_path = tmpdir.path().canonicalize().unwrap();
assert!(chdir(&tmpdir_path).is_ok());
assert_eq!(getcwd().unwrap(), tmpdir_path);
// make path 500 chars longer so that buffer doubling in getcwd
// kicks in. Note: One path cannot be longer than 255 bytes
// (NAME_MAX) whole path cannot be longer than PATH_MAX (usually
// 4096 on linux, 1024 on macos)
let mut inner_tmp_dir = tmpdir_path.to_path_buf();
for _ in 0..5 {
let newdir = iter::repeat("a").take(100).collect::<String>();
inner_tmp_dir.push(newdir);
assert!(mkdir(inner_tmp_dir.as_path(), Mode::S_IRWXU).is_ok());
}
assert!(chdir(inner_tmp_dir.as_path()).is_ok());
assert_eq!(getcwd().unwrap(), inner_tmp_dir.as_path());
}
#[test]
fn test_lseek() {
const CONTENTS: &[u8] = b"abcdef123456";
let mut tmp = tempfile().unwrap();
tmp.write_all(CONTENTS).unwrap();
let tmpfd = tmp.into_raw_fd();
let offset: off_t = 5;
lseek(tmpfd, offset, Whence::SeekSet).unwrap();
let mut buf = [0u8; 7];
::read_exact(tmpfd, &mut buf);
assert_eq!(b"f123456", &buf);
close(tmpfd).unwrap();
}
#[cfg(any(target_os = "linux", target_os = "android"))]
#[test]
fn test_lseek64() {
const CONTENTS: &[u8] = b"abcdef123456";
let mut tmp = tempfile().unwrap();
tmp.write_all(CONTENTS).unwrap();
let tmpfd = tmp.into_raw_fd();
lseek64(tmpfd, 5, Whence::SeekSet).unwrap();
let mut buf = [0u8; 7];
::read_exact(tmpfd, &mut buf);
assert_eq!(b"f123456", &buf);
close(tmpfd).unwrap();
}
#[test]
fn test_fpathconf_limited() {
let f = tempfile().unwrap();
// AFAIK, PATH_MAX is limited on all platforms, so it makes a good test
let path_max = fpathconf(f.as_raw_fd(), PathconfVar::PATH_MAX);
assert!(path_max.expect("fpathconf failed").expect("PATH_MAX is unlimited") > 0);
}
#[test]
fn test_pathconf_limited() {
// AFAIK, PATH_MAX is limited on all platforms, so it makes a good test
let path_max = pathconf("/", PathconfVar::PATH_MAX);
assert!(path_max.expect("pathconf failed").expect("PATH_MAX is unlimited") > 0);
}
#[test]
fn test_sysconf_limited() {
// AFAIK, OPEN_MAX is limited on all platforms, so it makes a good test
let open_max = sysconf(SysconfVar::OPEN_MAX);
assert!(open_max.expect("sysconf failed").expect("OPEN_MAX is unlimited") > 0);
}
#[cfg(target_os = "freebsd")]
#[test]
fn test_sysconf_unsupported() {
// I know of no sysconf variables that are unsupported everywhere, but
// _XOPEN_CRYPT is unsupported on FreeBSD 11.0, which is one of the platforms
// we test.
let open_max = sysconf(SysconfVar::_XOPEN_CRYPT);
assert!(open_max.expect("sysconf failed").is_none())
}
// Test that we can create a pair of pipes. No need to verify that they pass
// data; that's the domain of the OS, not nix.
#[test]
fn test_pipe() {
let (fd0, fd1) = pipe().unwrap();
let m0 = stat::SFlag::from_bits_truncate(stat::fstat(fd0).unwrap().st_mode);
// S_IFIFO means it's a pipe
assert_eq!(m0, SFlag::S_IFIFO);
let m1 = stat::SFlag::from_bits_truncate(stat::fstat(fd1).unwrap().st_mode);
assert_eq!(m1, SFlag::S_IFIFO);
}
// pipe2(2) is the same as pipe(2), except it allows setting some flags. Check
// that we can set a flag.
#[test]
fn test_pipe2() {
let (fd0, fd1) = pipe2(OFlag::O_CLOEXEC).unwrap();
let f0 = FdFlag::from_bits_truncate(fcntl(fd0, FcntlArg::F_GETFD).unwrap());
assert!(f0.contains(FdFlag::FD_CLOEXEC));
let f1 = FdFlag::from_bits_truncate(fcntl(fd1, FcntlArg::F_GETFD).unwrap());
assert!(f1.contains(FdFlag::FD_CLOEXEC));
}
// Used in `test_alarm`.
static mut ALARM_CALLED: bool = false;
// Used in `test_alarm`.
pub extern fn alarm_signal_handler(raw_signal: libc::c_int) {
assert_eq!(raw_signal, libc::SIGALRM, "unexpected signal: {}", raw_signal);
unsafe { ALARM_CALLED = true };
}
#[test]
fn test_alarm() {
let _m = ::SIGNAL_MTX.lock().expect("Mutex got poisoned by another test");
let handler = SigHandler::Handler(alarm_signal_handler);
let signal_action = SigAction::new(handler, SaFlags::SA_RESTART, SigSet::empty());
let old_handler = unsafe {
sigaction(Signal::SIGALRM, &signal_action)
.expect("unable to set signal handler for alarm")
};
// Set an alarm.
assert_eq!(alarm::set(60), None);
// Overwriting an alarm should return the old alarm.
assert_eq!(alarm::set(1), Some(60));
// We should be woken up after 1 second by the alarm, so we'll sleep for 2
// seconds to be sure.
sleep(2);
assert_eq!(unsafe { ALARM_CALLED }, true, "expected our alarm signal handler to be called");
// Reset the signal.
unsafe {
sigaction(Signal::SIGALRM, &old_handler)
.expect("unable to set signal handler for alarm");
}
}
#[test]
fn test_canceling_alarm() {
let _m = ::SIGNAL_MTX.lock().expect("Mutex got poisoned by another test");
assert_eq!(alarm::cancel(), None);
assert_eq!(alarm::set(60), None);
assert_eq!(alarm::cancel(), Some(60));
}
|