extern crate tempdir; use nix::unistd::*; use nix::unistd::ForkResult::*; use nix::sys::wait::*; use nix::sys::stat; use std::iter; use std::ffi::CString; use std::fs::File; use std::io::Write; use std::os::unix::prelude::*; use tempfile::tempfile; use tempdir::TempDir; use libc::off_t; use std::process::exit; #[test] fn test_fork_and_waitpid() { #[allow(unused_variables)] let m = ::FORK_MTX.lock().expect("Mutex got poisoned by another test"); let pid = fork(); match pid { Ok(Child) => exit(0), Ok(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) } }, // panic, fork should never fail unless there is a serious problem with the OS Err(_) => panic!("Error: Fork Failed") } } #[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"); let pid = fork(); match pid { Ok(Child) => exit(0), Ok(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))); }, // panic, fork should never fail unless there is a serious problem with the OS Err(_) => panic!("Error: Fork Failed") } } #[test] fn test_mkstemp() { let result = mkstemp("/tmp/nix_tempfile.XXXXXX"); match result { Ok((fd, path)) => { close(fd).unwrap(); unlink(path.as_path()).unwrap(); }, Err(e) => panic!("mkstemp failed: {}", e) } let result = mkstemp("/tmp/"); match result { Ok(_) => { panic!("mkstemp succeeded even though it should fail (provided a directory)"); }, 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); } #[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); } } macro_rules! execve_test_factory( ($test_name:ident, $syscall:ident, $unix_sh:expr, $android_sh: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(); match fork().unwrap() { Child => { #[cfg(not(target_os = "android"))] const SH_PATH: &'static [u8] = $unix_sh; #[cfg(target_os = "android")] const SH_PATH: &'static [u8] = $android_sh; // Close stdout. close(1).unwrap(); // Make `writer` be the stdout of the new process. dup(writer).unwrap(); // exec! $syscall( &CString::new(SH_PATH).unwrap(), &[CString::new(b"".as_ref()).unwrap(), CString::new(b"-c".as_ref()).unwrap(), CString::new(b"echo nix!!! && echo foo=$foo && echo baz=$baz" .as_ref()).unwrap()], &[CString::new(b"foo=bar".as_ref()).unwrap(), CString::new(b"baz=quux".as_ref()).unwrap()]).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")); } } } ) ); #[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 = TempDir::new("test_fchdir").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 = TempDir::new("test_getcwd").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::(); inner_tmp_dir.push(newdir); assert!(mkdir(inner_tmp_dir.as_path(), stat::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: &'static [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: &'static [u8] = b"abcdef123456"; let mut tmp = tempfile().unwrap(); tmp.write(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(); } execve_test_factory!(test_execve, execve, b"/bin/sh", b"/system/bin/sh"); #[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()) }