#[cfg(not(target_os = "redox"))] use nix::errno::*; #[cfg(not(target_os = "redox"))] use nix::fcntl::{open, readlink, OFlag}; #[cfg(not(target_os = "redox"))] use nix::fcntl::{openat, readlinkat, renameat}; #[cfg(all( target_os = "linux", target_env = "gnu", any( target_arch = "x86_64", target_arch = "x32", target_arch = "powerpc", target_arch = "s390x" ) ))] use nix::fcntl::{renameat2, RenameFlags}; #[cfg(not(target_os = "redox"))] use nix::sys::stat::Mode; #[cfg(not(target_os = "redox"))] use nix::unistd::{close, read}; #[cfg(not(target_os = "redox"))] use std::fs::File; #[cfg(not(target_os = "redox"))] use std::io::prelude::*; #[cfg(not(target_os = "redox"))] use std::os::unix::fs; #[cfg(not(target_os = "redox"))] use tempfile::NamedTempFile; #[test] #[cfg(not(target_os = "redox"))] // QEMU does not handle openat well enough to satisfy this test // https://gitlab.com/qemu-project/qemu/-/issues/829 #[cfg_attr(qemu, ignore)] fn test_openat() { const CONTENTS: &[u8] = b"abcd"; let mut tmp = NamedTempFile::new().unwrap(); tmp.write_all(CONTENTS).unwrap(); let dirfd = open(tmp.path().parent().unwrap(), OFlag::empty(), Mode::empty()) .unwrap(); let fd = openat( Some(dirfd), tmp.path().file_name().unwrap(), OFlag::O_RDONLY, Mode::empty(), ) .unwrap(); let mut buf = [0u8; 1024]; assert_eq!(4, read(fd, &mut buf).unwrap()); assert_eq!(CONTENTS, &buf[0..4]); close(fd).unwrap(); close(dirfd).unwrap(); } #[test] #[cfg(not(target_os = "redox"))] fn test_renameat() { let old_dir = tempfile::tempdir().unwrap(); let old_dirfd = open(old_dir.path(), OFlag::empty(), Mode::empty()).unwrap(); let old_path = old_dir.path().join("old"); File::create(old_path).unwrap(); let new_dir = tempfile::tempdir().unwrap(); let new_dirfd = open(new_dir.path(), OFlag::empty(), Mode::empty()).unwrap(); renameat(Some(old_dirfd), "old", Some(new_dirfd), "new").unwrap(); assert_eq!( renameat(Some(old_dirfd), "old", Some(new_dirfd), "new").unwrap_err(), Errno::ENOENT ); close(old_dirfd).unwrap(); close(new_dirfd).unwrap(); assert!(new_dir.path().join("new").exists()); } #[test] #[cfg(all( target_os = "linux", target_env = "gnu", any( target_arch = "x86_64", target_arch = "x32", target_arch = "powerpc", target_arch = "s390x" ) ))] fn test_renameat2_behaves_like_renameat_with_no_flags() { let old_dir = tempfile::tempdir().unwrap(); let old_dirfd = open(old_dir.path(), OFlag::empty(), Mode::empty()).unwrap(); let old_path = old_dir.path().join("old"); File::create(old_path).unwrap(); let new_dir = tempfile::tempdir().unwrap(); let new_dirfd = open(new_dir.path(), OFlag::empty(), Mode::empty()).unwrap(); renameat2( Some(old_dirfd), "old", Some(new_dirfd), "new", RenameFlags::empty(), ) .unwrap(); assert_eq!( renameat2( Some(old_dirfd), "old", Some(new_dirfd), "new", RenameFlags::empty() ) .unwrap_err(), Errno::ENOENT ); close(old_dirfd).unwrap(); close(new_dirfd).unwrap(); assert!(new_dir.path().join("new").exists()); } #[test] #[cfg(all( target_os = "linux", target_env = "gnu", any( target_arch = "x86_64", target_arch = "x32", target_arch = "powerpc", target_arch = "s390x" ) ))] fn test_renameat2_exchange() { let old_dir = tempfile::tempdir().unwrap(); let old_dirfd = open(old_dir.path(), OFlag::empty(), Mode::empty()).unwrap(); let old_path = old_dir.path().join("old"); { let mut old_f = File::create(&old_path).unwrap(); old_f.write_all(b"old").unwrap(); } let new_dir = tempfile::tempdir().unwrap(); let new_dirfd = open(new_dir.path(), OFlag::empty(), Mode::empty()).unwrap(); let new_path = new_dir.path().join("new"); { let mut new_f = File::create(&new_path).unwrap(); new_f.write_all(b"new").unwrap(); } renameat2( Some(old_dirfd), "old", Some(new_dirfd), "new", RenameFlags::RENAME_EXCHANGE, ) .unwrap(); let mut buf = String::new(); let mut new_f = File::open(&new_path).unwrap(); new_f.read_to_string(&mut buf).unwrap(); assert_eq!(buf, "old"); buf = "".to_string(); let mut old_f = File::open(&old_path).unwrap(); old_f.read_to_string(&mut buf).unwrap(); assert_eq!(buf, "new"); close(old_dirfd).unwrap(); close(new_dirfd).unwrap(); } #[test] #[cfg(all( target_os = "linux", target_env = "gnu", any( target_arch = "x86_64", target_arch = "x32", target_arch = "powerpc", target_arch = "s390x" ) ))] fn test_renameat2_noreplace() { let old_dir = tempfile::tempdir().unwrap(); let old_dirfd = open(old_dir.path(), OFlag::empty(), Mode::empty()).unwrap(); let old_path = old_dir.path().join("old"); File::create(old_path).unwrap(); let new_dir = tempfile::tempdir().unwrap(); let new_dirfd = open(new_dir.path(), OFlag::empty(), Mode::empty()).unwrap(); let new_path = new_dir.path().join("new"); File::create(new_path).unwrap(); assert_eq!( renameat2( Some(old_dirfd), "old", Some(new_dirfd), "new", RenameFlags::RENAME_NOREPLACE ) .unwrap_err(), Errno::EEXIST ); close(old_dirfd).unwrap(); close(new_dirfd).unwrap(); assert!(new_dir.path().join("new").exists()); assert!(old_dir.path().join("old").exists()); } #[test] #[cfg(not(target_os = "redox"))] fn test_readlink() { let tempdir = tempfile::tempdir().unwrap(); let src = tempdir.path().join("a"); let dst = tempdir.path().join("b"); println!("a: {:?}, b: {:?}", &src, &dst); fs::symlink(src.as_path(), dst.as_path()).unwrap(); let dirfd = open(tempdir.path(), OFlag::empty(), Mode::empty()).unwrap(); let expected_dir = src.to_str().unwrap(); assert_eq!(readlink(&dst).unwrap().to_str().unwrap(), expected_dir); assert_eq!( readlinkat(Some(dirfd), "b").unwrap().to_str().unwrap(), expected_dir ); } /// This test creates a temporary file containing the contents /// 'foobarbaz' and uses the `copy_file_range` call to transfer /// 3 bytes at offset 3 (`bar`) to another empty file at offset 0. The /// resulting file is read and should contain the contents `bar`. /// The from_offset should be updated by the call to reflect /// the 3 bytes read (6). #[cfg(any( linux_android, // Not available until FreeBSD 13.0 all(target_os = "freebsd", fbsd14), ))] #[test] // QEMU does not support copy_file_range. Skip under qemu #[cfg_attr(qemu, ignore)] fn test_copy_file_range() { use nix::fcntl::copy_file_range; use std::os::unix::io::AsFd; const CONTENTS: &[u8] = b"foobarbaz"; let mut tmp1 = tempfile::tempfile().unwrap(); let mut tmp2 = tempfile::tempfile().unwrap(); tmp1.write_all(CONTENTS).unwrap(); tmp1.flush().unwrap(); let mut from_offset: i64 = 3; copy_file_range( tmp1.as_fd(), Some(&mut from_offset), tmp2.as_fd(), None, 3, ) .unwrap(); let mut res: String = String::new(); tmp2.rewind().unwrap(); tmp2.read_to_string(&mut res).unwrap(); assert_eq!(res, String::from("bar")); assert_eq!(from_offset, 6); } #[cfg(linux_android)] mod linux_android { use libc::loff_t; use std::io::prelude::*; use std::io::IoSlice; use std::os::unix::prelude::*; use nix::fcntl::*; use nix::unistd::{pipe, read, write}; use tempfile::tempfile; #[cfg(target_os = "linux")] use tempfile::NamedTempFile; use crate::*; #[test] fn test_splice() { const CONTENTS: &[u8] = b"abcdef123456"; let mut tmp = tempfile().unwrap(); tmp.write_all(CONTENTS).unwrap(); let (rd, wr) = pipe().unwrap(); let mut offset: loff_t = 5; let res = splice( tmp.as_raw_fd(), Some(&mut offset), wr.as_raw_fd(), None, 2, SpliceFFlags::empty(), ) .unwrap(); assert_eq!(2, res); let mut buf = [0u8; 1024]; assert_eq!(2, read(rd.as_raw_fd(), &mut buf).unwrap()); assert_eq!(b"f1", &buf[0..2]); assert_eq!(7, offset); } #[test] fn test_tee() { let (rd1, wr1) = pipe().unwrap(); let (rd2, wr2) = pipe().unwrap(); write(wr1, b"abc").unwrap(); let res = tee(rd1.as_raw_fd(), wr2.as_raw_fd(), 2, SpliceFFlags::empty()) .unwrap(); assert_eq!(2, res); let mut buf = [0u8; 1024]; // Check the tee'd bytes are at rd2. assert_eq!(2, read(rd2.as_raw_fd(), &mut buf).unwrap()); assert_eq!(b"ab", &buf[0..2]); // Check all the bytes are still at rd1. assert_eq!(3, read(rd1.as_raw_fd(), &mut buf).unwrap()); assert_eq!(b"abc", &buf[0..3]); } #[test] fn test_vmsplice() { let (rd, wr) = pipe().unwrap(); let buf1 = b"abcdef"; let buf2 = b"defghi"; let iovecs = [IoSlice::new(&buf1[0..3]), IoSlice::new(&buf2[0..3])]; let res = vmsplice(wr.as_raw_fd(), &iovecs[..], SpliceFFlags::empty()) .unwrap(); assert_eq!(6, res); // Check the bytes can be read at rd. let mut buf = [0u8; 32]; assert_eq!(6, read(rd.as_raw_fd(), &mut buf).unwrap()); assert_eq!(b"abcdef", &buf[0..6]); } #[cfg(target_os = "linux")] #[test] fn test_fallocate() { let tmp = NamedTempFile::new().unwrap(); let fd = tmp.as_raw_fd(); fallocate(fd, FallocateFlags::empty(), 0, 100).unwrap(); // Check if we read exactly 100 bytes let mut buf = [0u8; 200]; assert_eq!(100, read(fd, &mut buf).unwrap()); } // The tests below are disabled for the listed targets // due to OFD locks not being available in the kernel/libc // versions used in the CI environment, probably because // they run under QEMU. #[test] #[cfg(all(target_os = "linux", not(target_env = "musl")))] #[cfg_attr(target_env = "uclibc", ignore)] // uclibc doesn't support OFD locks, but the test should still compile fn test_ofd_write_lock() { use nix::sys::stat::fstat; use std::mem; let tmp = NamedTempFile::new().unwrap(); let fd = tmp.as_raw_fd(); let statfs = nix::sys::statfs::fstatfs(tmp.as_file()).unwrap(); if statfs.filesystem_type() == nix::sys::statfs::OVERLAYFS_SUPER_MAGIC { // OverlayFS is a union file system. It returns one inode value in // stat(2), but a different one shows up in /proc/locks. So we must // skip the test. skip!("/proc/locks does not work on overlayfs"); } let inode = fstat(fd).expect("fstat failed").st_ino as usize; let mut flock: libc::flock = unsafe { mem::zeroed() // required for Linux/mips }; flock.l_type = libc::F_WRLCK as libc::c_short; flock.l_whence = libc::SEEK_SET as libc::c_short; flock.l_start = 0; flock.l_len = 0; flock.l_pid = 0; fcntl(fd, FcntlArg::F_OFD_SETLKW(&flock)).expect("write lock failed"); assert_eq!( Some(("OFDLCK".to_string(), "WRITE".to_string())), lock_info(inode) ); flock.l_type = libc::F_UNLCK as libc::c_short; fcntl(fd, FcntlArg::F_OFD_SETLKW(&flock)).expect("write unlock failed"); assert_eq!(None, lock_info(inode)); } #[test] #[cfg(all(target_os = "linux", not(target_env = "musl")))] #[cfg_attr(target_env = "uclibc", ignore)] // uclibc doesn't support OFD locks, but the test should still compile fn test_ofd_read_lock() { use nix::sys::stat::fstat; use std::mem; let tmp = NamedTempFile::new().unwrap(); let fd = tmp.as_raw_fd(); let statfs = nix::sys::statfs::fstatfs(tmp.as_file()).unwrap(); if statfs.filesystem_type() == nix::sys::statfs::OVERLAYFS_SUPER_MAGIC { // OverlayFS is a union file system. It returns one inode value in // stat(2), but a different one shows up in /proc/locks. So we must // skip the test. skip!("/proc/locks does not work on overlayfs"); } let inode = fstat(fd).expect("fstat failed").st_ino as usize; let mut flock: libc::flock = unsafe { mem::zeroed() // required for Linux/mips }; flock.l_type = libc::F_RDLCK as libc::c_short; flock.l_whence = libc::SEEK_SET as libc::c_short; flock.l_start = 0; flock.l_len = 0; flock.l_pid = 0; fcntl(fd, FcntlArg::F_OFD_SETLKW(&flock)).expect("read lock failed"); assert_eq!( Some(("OFDLCK".to_string(), "READ".to_string())), lock_info(inode) ); flock.l_type = libc::F_UNLCK as libc::c_short; fcntl(fd, FcntlArg::F_OFD_SETLKW(&flock)).expect("read unlock failed"); assert_eq!(None, lock_info(inode)); } #[cfg(all(target_os = "linux", not(target_env = "musl")))] fn lock_info(inode: usize) -> Option<(String, String)> { use std::{fs::File, io::BufReader}; let file = File::open("/proc/locks").expect("open /proc/locks failed"); let buf = BufReader::new(file); for line in buf.lines() { let line = line.unwrap(); let parts: Vec<_> = line.split_whitespace().collect(); let lock_type = parts[1]; let lock_access = parts[3]; let ino_parts: Vec<_> = parts[5].split(':').collect(); let ino: usize = ino_parts[2].parse().unwrap(); if ino == inode { return Some((lock_type.to_string(), lock_access.to_string())); } } None } } #[cfg(any( linux_android, target_os = "emscripten", target_os = "fuchsia", target_os = "wasi", target_env = "uclibc", target_os = "freebsd" ))] mod test_posix_fadvise { use nix::errno::Errno; use nix::fcntl::*; use nix::unistd::pipe; use std::os::unix::io::AsRawFd; use tempfile::NamedTempFile; #[test] fn test_success() { let tmp = NamedTempFile::new().unwrap(); let fd = tmp.as_raw_fd(); posix_fadvise(fd, 0, 100, PosixFadviseAdvice::POSIX_FADV_WILLNEED) .expect("posix_fadvise failed"); } #[test] fn test_errno() { let (rd, _wr) = pipe().unwrap(); let res = posix_fadvise( rd.as_raw_fd(), 0, 100, PosixFadviseAdvice::POSIX_FADV_WILLNEED, ); assert_eq!(res, Err(Errno::ESPIPE)); } } #[cfg(any( linux_android, freebsdlike, target_os = "emscripten", target_os = "fuchsia", target_os = "wasi", ))] mod test_posix_fallocate { use nix::errno::Errno; use nix::fcntl::*; use nix::unistd::pipe; use std::{io::Read, os::unix::io::AsRawFd}; use tempfile::NamedTempFile; #[test] fn success() { const LEN: usize = 100; let mut tmp = NamedTempFile::new().unwrap(); let fd = tmp.as_raw_fd(); let res = posix_fallocate(fd, 0, LEN as libc::off_t); match res { Ok(_) => { let mut data = [1u8; LEN]; assert_eq!(tmp.read(&mut data).expect("read failure"), LEN); assert_eq!(&data[..], &[0u8; LEN][..]); } Err(Errno::EINVAL) => { // POSIX requires posix_fallocate to return EINVAL both for // invalid arguments (i.e. len < 0) and if the operation is not // supported by the file system. // There's no way to tell for sure whether the file system // supports posix_fallocate, so we must pass the test if it // returns EINVAL. } _ => res.unwrap(), } } #[test] fn errno() { let (rd, _wr) = pipe().unwrap(); let err = posix_fallocate(rd.as_raw_fd(), 0, 100).unwrap_err(); match err { Errno::EINVAL | Errno::ENODEV | Errno::ESPIPE | Errno::EBADF => (), errno => panic!("unexpected errno {errno}",), } } } #[cfg(any(target_os = "dragonfly", target_os = "netbsd", apple_targets))] #[test] fn test_f_get_path() { use nix::fcntl::*; use std::{os::unix::io::AsRawFd, path::PathBuf}; let tmp = NamedTempFile::new().unwrap(); let fd = tmp.as_raw_fd(); let mut path = PathBuf::new(); let res = fcntl(fd, FcntlArg::F_GETPATH(&mut path)).expect("get path failed"); assert_ne!(res, -1); assert_eq!( path.as_path().canonicalize().unwrap(), tmp.path().canonicalize().unwrap() ); } #[cfg(apple_targets)] #[test] fn test_f_get_path_nofirmlink() { use nix::fcntl::*; use std::{os::unix::io::AsRawFd, path::PathBuf}; let tmp = NamedTempFile::new().unwrap(); let fd = tmp.as_raw_fd(); let mut path = PathBuf::new(); let res = fcntl(fd, FcntlArg::F_GETPATH_NOFIRMLINK(&mut path)) .expect("get path failed"); let mut tmpstr = String::from("/System/Volumes/Data"); tmpstr.push_str( &tmp.path() .canonicalize() .unwrap() .into_os_string() .into_string() .unwrap(), ); assert_ne!(res, -1); assert_eq!( path.as_path() .canonicalize() .unwrap() .into_os_string() .into_string() .unwrap(), tmpstr ); } #[cfg(all(target_os = "freebsd", target_arch = "x86_64"))] #[test] fn test_f_kinfo() { use nix::fcntl::*; use std::{os::unix::io::AsRawFd, path::PathBuf}; let tmp = NamedTempFile::new().unwrap(); // With TMPDIR set with UFS, the vnode name is not entered // into the name cache thus path is always empty. // Therefore, we reopen the tempfile a second time for the test // to pass. let tmp2 = File::open(tmp.path()).unwrap(); let fd = tmp2.as_raw_fd(); let mut path = PathBuf::new(); let res = fcntl(fd, FcntlArg::F_KINFO(&mut path)).expect("get path failed"); assert_ne!(res, -1); assert_eq!(path, tmp.path()); } /// Test `Flock` and associated functions. /// #[cfg(not(any(target_os = "redox", target_os = "solaris")))] mod test_flock { use nix::fcntl::*; use tempfile::NamedTempFile; /// Verify that `Flock::lock()` correctly obtains a lock, and subsequently unlocks upon drop. #[test] fn verify_lock_and_drop() { // Get 2 `File` handles to same underlying file. let file1 = NamedTempFile::new().unwrap(); let file2 = file1.reopen().unwrap(); let file1 = file1.into_file(); // Lock first handle let lock1 = Flock::lock(file1, FlockArg::LockExclusive).unwrap(); // Attempt to lock second handle let file2 = match Flock::lock(file2, FlockArg::LockExclusiveNonblock) { Ok(_) => panic!("Expected second exclusive lock to fail."), Err((f, _)) => f, }; // Drop first lock std::mem::drop(lock1); // Attempt to lock second handle again (but successfully) if Flock::lock(file2, FlockArg::LockExclusiveNonblock).is_err() { panic!("Expected locking to be successful."); } } /// Verify that `Flock::unlock()` correctly obtains unlocks. #[test] fn verify_unlock() { // Get 2 `File` handles to same underlying file. let file1 = NamedTempFile::new().unwrap(); let file2 = file1.reopen().unwrap(); let file1 = file1.into_file(); // Lock first handle let lock1 = Flock::lock(file1, FlockArg::LockExclusive).unwrap(); // Unlock and retain file so any erroneous flocks also remain present. let _file1 = lock1.unlock().unwrap(); // Attempt to lock second handle. if Flock::lock(file2, FlockArg::LockExclusiveNonblock).is_err() { panic!("Expected locking to be successful."); } } }