extern crate async_tar; extern crate filetime; extern crate tempfile; #[cfg(all(unix, feature = "xattr"))] extern crate xattr; use async_std::{ fs::{self, File}, io::{self, Cursor, Read, Write}, path::{Path, PathBuf}, prelude::*, }; use std::iter::repeat; use async_tar::{Archive, ArchiveBuilder, Builder, EntryType, Header}; use filetime::FileTime; use tempfile::{Builder as TempBuilder, TempDir}; macro_rules! t { ($e:expr) => { match $e { Ok(v) => v, Err(e) => panic!("{} returned {}", stringify!($e), e), } }; } macro_rules! tar { ($e:expr) => { &include_bytes!(concat!("archives/", $e))[..] }; } mod header; /// test that we can concatenate the simple.tar archive and extract the same entries twice when we /// use the ignore_zeros option. #[async_std::test] async fn simple_concat() { let bytes = tar!("simple.tar"); let mut archive_bytes = Vec::new(); archive_bytes.extend(bytes); let original_names: Vec = decode_names(Archive::new(Cursor::new(&archive_bytes))).await; let expected: Vec<&str> = original_names.iter().map(|n| n.as_str()).collect(); // concat two archives (with null in-between); archive_bytes.extend(bytes); // test now that when we read the archive, it stops processing at the first zero header. let actual = decode_names(Archive::new(Cursor::new(&archive_bytes))).await; assert_eq!(expected, actual); // extend expected by itself. let expected: Vec<&str> = { let mut o = Vec::new(); o.extend(&expected); o.extend(&expected); o }; let builder = ArchiveBuilder::new(Cursor::new(&archive_bytes)).set_ignore_zeros(true); let ar = builder.build(); let actual = decode_names(ar).await; assert_eq!(expected, actual); async fn decode_names(ar: Archive) -> Vec where R: Read + Unpin + Sync + Send, { let mut names = Vec::new(); let mut entries = t!(ar.entries()); while let Some(entry) = entries.next().await { let e = t!(entry); names.push(t!(::std::str::from_utf8(&e.path_bytes())).to_string()); } names } } #[async_std::test] async fn header_impls() { let ar = Archive::new(Cursor::new(tar!("simple.tar"))); let hn = Header::new_old(); let hnb = hn.as_bytes(); let mut entries = t!(ar.entries()); while let Some(file) = entries.next().await { let file = t!(file); let h1 = file.header(); let h1b = h1.as_bytes(); let h2 = h1.clone(); let h2b = h2.as_bytes(); assert!(h1b[..] == h2b[..] && h2b[..] != hnb[..]) } } #[async_std::test] async fn header_impls_missing_last_header() { let ar = Archive::new(Cursor::new(tar!("simple_missing_last_header.tar"))); let hn = Header::new_old(); let hnb = hn.as_bytes(); let mut entries = t!(ar.entries()); while let Some(file) = entries.next().await { let file = t!(file); let h1 = file.header(); let h1b = h1.as_bytes(); let h2 = h1.clone(); let h2b = h2.as_bytes(); assert!(h1b[..] == h2b[..] && h2b[..] != hnb[..]) } } #[async_std::test] async fn reading_files() { let rdr = Cursor::new(tar!("reading_files.tar")); let ar = Archive::new(rdr); let mut entries = t!(ar.entries()); let mut a = t!(entries.next().await.unwrap()); assert_eq!(&*a.header().path_bytes(), b"a"); let mut s = String::new(); t!(a.read_to_string(&mut s).await); assert_eq!(s, "a\na\na\na\na\na\na\na\na\na\na\n"); let mut b = t!(entries.next().await.unwrap()); assert_eq!(&*b.header().path_bytes(), b"b"); s.truncate(0); t!(b.read_to_string(&mut s).await); assert_eq!(s, "b\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\n"); assert!(entries.next().await.is_none()); } #[async_std::test] async fn writing_files() { let mut ar = Builder::new(Vec::new()); let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let path = td.path().join("test"); t!(t!(File::create(&path).await).write_all(b"test").await); t!(ar .append_file("test2", &mut t!(File::open(&path).await)) .await); let data = t!(ar.into_inner().await); let ar = Archive::new(Cursor::new(data)); let mut entries = t!(ar.entries()); let mut f = t!(entries.next().await.unwrap()); assert_eq!(&*f.header().path_bytes(), b"test2"); assert_eq!(f.header().size().unwrap(), 4); let mut s = String::new(); t!(f.read_to_string(&mut s).await); assert_eq!(s, "test"); assert!(entries.next().await.is_none()); } #[async_std::test] async fn large_filename() { let mut ar = Builder::new(Vec::new()); let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let path = td.path().join("test"); t!(t!(File::create(&path).await).write_all(b"test").await); let filename = "abcd/".repeat(50); let mut header = Header::new_ustar(); header.set_path(&filename).unwrap(); header.set_metadata(&t!(fs::metadata(&path).await)); header.set_cksum(); t!(ar.append(&header, &b"test"[..]).await); let too_long = "abcd".repeat(200); t!(ar .append_file(&too_long, &mut t!(File::open(&path).await)) .await); t!(ar.append_data(&mut header, &too_long, &b"test"[..]).await); let rd = Cursor::new(t!(ar.into_inner().await)); let ar = Archive::new(rd); let mut entries = t!(ar.entries()); // The short entry added with `append` let mut f = entries.next().await.unwrap().unwrap(); assert_eq!(&*f.header().path_bytes(), filename.as_bytes()); assert_eq!(f.header().size().unwrap(), 4); let mut s = String::new(); t!(f.read_to_string(&mut s).await); assert_eq!(s, "test"); // The long entry added with `append_file` let mut f = entries.next().await.unwrap().unwrap(); assert_eq!(&*f.path_bytes(), too_long.as_bytes()); assert_eq!(f.header().size().unwrap(), 4); let mut s = String::new(); t!(f.read_to_string(&mut s).await); assert_eq!(s, "test"); // The long entry added with `append_data` let mut f = entries.next().await.unwrap().unwrap(); assert!(f.header().path_bytes().len() < too_long.len()); assert_eq!(&*f.path_bytes(), too_long.as_bytes()); assert_eq!(f.header().size().unwrap(), 4); let mut s = String::new(); t!(f.read_to_string(&mut s).await); assert_eq!(s, "test"); assert!(entries.next().await.is_none()); } #[async_std::test] async fn reading_entries() { let rdr = Cursor::new(tar!("reading_files.tar")); let ar = Archive::new(rdr); let mut entries = t!(ar.entries()); let mut a = t!(entries.next().await.unwrap()); assert_eq!(&*a.header().path_bytes(), b"a"); let mut s = String::new(); t!(a.read_to_string(&mut s).await); assert_eq!(s, "a\na\na\na\na\na\na\na\na\na\na\n"); s.truncate(0); t!(a.read_to_string(&mut s).await); assert_eq!(s, ""); let mut b = t!(entries.next().await.unwrap()); assert_eq!(&*b.header().path_bytes(), b"b"); s.truncate(0); t!(b.read_to_string(&mut s).await); assert_eq!(s, "b\nb\nb\nb\nb\nb\nb\nb\nb\nb\nb\n"); assert!(entries.next().await.is_none()); } async fn check_dirtree(td: &TempDir) { let dir_a = td.path().join("a"); let dir_b = td.path().join("a/b"); let file_c = td.path().join("a/c"); assert!(fs::metadata(&dir_a) .await .map(|m| m.is_dir()) .unwrap_or(false)); assert!(fs::metadata(&dir_b) .await .map(|m| m.is_dir()) .unwrap_or(false)); assert!(fs::metadata(&file_c) .await .map(|m| m.is_file()) .unwrap_or(false)); } #[async_std::test] async fn extracting_directories() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let rdr = Cursor::new(tar!("directory.tar")); let ar = Archive::new(rdr); t!(ar.unpack(td.path()).await); check_dirtree(&td).await; } #[async_std::test] #[cfg(all(unix, feature = "xattr"))] async fn xattrs() { // If /tmp is a tmpfs, xattr will fail // The xattr crate's unit tests also use /var/tmp for this reason let td = t!(TempBuilder::new() .prefix("async-tar") .tempdir_in("/var/tmp")); let rdr = Cursor::new(tar!("xattrs.tar")); let builder = ArchiveBuilder::new(rdr).set_unpack_xattrs(true); let ar = builder.build(); t!(ar.unpack(td.path()).await); let val = xattr::get(td.path().join("a/b"), "user.pax.flags").unwrap(); assert_eq!(val.unwrap(), b"epm"); } #[async_std::test] #[cfg(all(unix, feature = "xattr"))] async fn no_xattrs() { // If /tmp is a tmpfs, xattr will fail // The xattr crate's unit tests also use /var/tmp for this reason let td = t!(TempBuilder::new() .prefix("async-tar") .tempdir_in("/var/tmp")); let rdr = Cursor::new(tar!("xattrs.tar")); let builder = ArchiveBuilder::new(rdr).set_unpack_xattrs(false); let ar = builder.build(); t!(ar.unpack(td.path()).await); assert_eq!( xattr::get(td.path().join("a/b"), "user.pax.flags").unwrap(), None ); } #[async_std::test] async fn writing_and_extracting_directories() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let mut ar = Builder::new(Vec::new()); let tmppath = td.path().join("tmpfile"); t!(t!(File::create(&tmppath).await).write_all(b"c").await); t!(ar.append_dir("a", ".").await); t!(ar.append_dir("a/b", ".").await); t!(ar .append_file("a/c", &mut t!(File::open(&tmppath).await)) .await); t!(ar.finish().await); let rdr = Cursor::new(t!(ar.into_inner().await)); let ar = Archive::new(rdr); t!(ar.unpack(td.path()).await); check_dirtree(&td).await; } #[async_std::test] async fn writing_directories_recursively() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let base_dir = td.path().join("base"); t!(fs::create_dir(&base_dir).await); t!(t!(File::create(base_dir.join("file1")).await) .write_all(b"file1") .await); let sub_dir = base_dir.join("sub"); t!(fs::create_dir(&sub_dir).await); t!(t!(File::create(sub_dir.join("file2")).await) .write_all(b"file2") .await); let mut ar = Builder::new(Vec::new()); t!(ar.append_dir_all("foobar", base_dir).await); let data = t!(ar.into_inner().await); let ar = Archive::new(Cursor::new(data)); t!(ar.unpack(td.path()).await); let base_dir = td.path().join("foobar"); assert!(fs::metadata(&base_dir) .await .map(|m| m.is_dir()) .unwrap_or(false)); let file1_path = base_dir.join("file1"); assert!(fs::metadata(&file1_path) .await .map(|m| m.is_file()) .unwrap_or(false)); let sub_dir = base_dir.join("sub"); assert!(fs::metadata(&sub_dir) .await .map(|m| m.is_dir()) .unwrap_or(false)); let file2_path = sub_dir.join("file2"); assert!(fs::metadata(&file2_path) .await .map(|m| m.is_file()) .unwrap_or(false)); } #[async_std::test] async fn append_dir_all_blank_dest() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let base_dir = td.path().join("base"); t!(fs::create_dir(&base_dir).await); t!(t!(File::create(base_dir.join("file1")).await) .write_all(b"file1") .await); let sub_dir = base_dir.join("sub"); t!(fs::create_dir(&sub_dir).await); t!(t!(File::create(sub_dir.join("file2")).await) .write_all(b"file2") .await); let mut ar = Builder::new(Vec::new()); t!(ar.append_dir_all("", base_dir).await); let data = t!(ar.into_inner().await); let ar = Archive::new(Cursor::new(data)); t!(ar.unpack(td.path()).await); let base_dir = td.path(); assert!(fs::metadata(&base_dir) .await .map(|m| m.is_dir()) .unwrap_or(false)); let file1_path = base_dir.join("file1"); assert!(fs::metadata(&file1_path) .await .map(|m| m.is_file()) .unwrap_or(false)); let sub_dir = base_dir.join("sub"); assert!(fs::metadata(&sub_dir) .await .map(|m| m.is_dir()) .unwrap_or(false)); let file2_path = sub_dir.join("file2"); assert!(fs::metadata(&file2_path) .await .map(|m| m.is_file()) .unwrap_or(false)); } #[async_std::test] async fn append_dir_all_does_not_work_on_non_directory() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let path = td.path().join("test"); t!(t!(File::create(&path).await).write_all(b"test").await); let mut ar = Builder::new(Vec::new()); let result = ar.append_dir_all("test", path).await; assert!(result.is_err()); } #[async_std::test] async fn extracting_duplicate_dirs() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let rdr = Cursor::new(tar!("duplicate_dirs.tar")); let ar = Archive::new(rdr); t!(ar.unpack(td.path()).await); let some_dir = td.path().join("some_dir"); assert!(fs::metadata(&some_dir) .await .map(|m| m.is_dir()) .unwrap_or(false)); } #[async_std::test] async fn unpack_old_style_bsd_dir() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let mut ar = Builder::new(Vec::new()); let mut header = Header::new_old(); header.set_entry_type(EntryType::Regular); t!(header.set_path("testdir/")); header.set_size(0); header.set_cksum(); t!(ar.append(&header, &mut io::empty()).await); // Extracting let rdr = Cursor::new(t!(ar.into_inner().await)); let ar = Archive::new(rdr); t!(ar.clone().unpack(td.path()).await); // Iterating let rdr = Cursor::new(ar.into_inner().map_err(|_| ()).unwrap().into_inner()); let ar = Archive::new(rdr); assert!(t!(ar.entries()).all(|fr| fr.is_ok()).await); assert!(td.path().join("testdir").is_dir()); } #[async_std::test] async fn handling_incorrect_file_size() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let mut ar = Builder::new(Vec::new()); let path = td.path().join("tmpfile"); t!(File::create(&path).await); let mut file = t!(File::open(&path).await); let mut header = Header::new_old(); t!(header.set_path("somepath")); header.set_metadata(&t!(file.metadata().await)); header.set_size(2048); // past the end of file null blocks header.set_cksum(); t!(ar.append(&header, &mut file).await); // Extracting let rdr = Cursor::new(t!(ar.into_inner().await)); let ar = Archive::new(rdr); assert!(ar.clone().unpack(td.path()).await.is_err()); // Iterating let rdr = Cursor::new(ar.into_inner().map_err(|_| ()).unwrap().into_inner()); let ar = Archive::new(rdr); assert!(t!(ar.entries()).any(|fr| fr.is_err()).await); } #[async_std::test] async fn extracting_malicious_tarball() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let mut evil_tar = Vec::new(); { let mut a = Builder::new(&mut evil_tar); async fn append(a: &mut Builder, path: &'static str) { let mut header = Header::new_gnu(); assert!(header.set_path(path).is_err(), "was ok: {:?}", path); { let h = header.as_gnu_mut().unwrap(); for (a, b) in h.name.iter_mut().zip(path.as_bytes()) { *a = *b; } } header.set_size(1); header.set_cksum(); t!(a.append(&header, io::repeat(1).take(1)).await); } append(&mut a, "/tmp/abs_evil.txt").await; append(&mut a, "//tmp/abs_evil2.txt").await; append(&mut a, "///tmp/abs_evil3.txt").await; append(&mut a, "/./tmp/abs_evil4.txt").await; append(&mut a, "//./tmp/abs_evil5.txt").await; append(&mut a, "///./tmp/abs_evil6.txt").await; append(&mut a, "/../tmp/rel_evil.txt").await; append(&mut a, "../rel_evil2.txt").await; append(&mut a, "./../rel_evil3.txt").await; append(&mut a, "some/../../rel_evil4.txt").await; append(&mut a, "").await; append(&mut a, "././//./..").await; append(&mut a, "..").await; append(&mut a, "/////////..").await; append(&mut a, "/////////").await; } let ar = Archive::new(&evil_tar[..]); t!(ar.unpack(td.path()).await); assert!(fs::metadata("/tmp/abs_evil.txt").await.is_err()); assert!(fs::metadata("/tmp/abs_evil.txt2").await.is_err()); assert!(fs::metadata("/tmp/abs_evil.txt3").await.is_err()); assert!(fs::metadata("/tmp/abs_evil.txt4").await.is_err()); assert!(fs::metadata("/tmp/abs_evil.txt5").await.is_err()); assert!(fs::metadata("/tmp/abs_evil.txt6").await.is_err()); assert!(fs::metadata("/tmp/rel_evil.txt").await.is_err()); assert!(fs::metadata("/tmp/rel_evil.txt").await.is_err()); assert!(fs::metadata(td.path().join("../tmp/rel_evil.txt")) .await .is_err()); assert!(fs::metadata(td.path().join("../rel_evil2.txt")) .await .is_err()); assert!(fs::metadata(td.path().join("../rel_evil3.txt")) .await .is_err()); assert!(fs::metadata(td.path().join("../rel_evil4.txt")) .await .is_err()); // The `some` subdirectory should not be created because the only // filename that references this has '..'. assert!(fs::metadata(td.path().join("some")).await.is_err()); // The `tmp` subdirectory should be created and within this // subdirectory, there should be files named `abs_evil.txt` through // `abs_evil6.txt`. assert!(fs::metadata(td.path().join("tmp")) .await .map(|m| m.is_dir()) .unwrap_or(false)); assert!(fs::metadata(td.path().join("tmp/abs_evil.txt")) .await .map(|m| m.is_file()) .unwrap_or(false)); assert!(fs::metadata(td.path().join("tmp/abs_evil2.txt")) .await .map(|m| m.is_file()) .unwrap_or(false)); assert!(fs::metadata(td.path().join("tmp/abs_evil3.txt")) .await .map(|m| m.is_file()) .unwrap_or(false)); assert!(fs::metadata(td.path().join("tmp/abs_evil4.txt")) .await .map(|m| m.is_file()) .unwrap_or(false)); assert!(fs::metadata(td.path().join("tmp/abs_evil5.txt")) .await .map(|m| m.is_file()) .unwrap_or(false)); assert!(fs::metadata(td.path().join("tmp/abs_evil6.txt")) .await .map(|m| m.is_file()) .unwrap_or(false)); } #[async_std::test] async fn octal_spaces() { let rdr = Cursor::new(tar!("spaces.tar")); let ar = Archive::new(rdr); let entry = ar.entries().unwrap().next().await.unwrap().unwrap(); assert_eq!(entry.header().mode().unwrap() & 0o777, 0o777); assert_eq!(entry.header().uid().unwrap(), 0); assert_eq!(entry.header().gid().unwrap(), 0); assert_eq!(entry.header().size().unwrap(), 2); assert_eq!(entry.header().mtime().unwrap(), 0o12_440_016_664); assert_eq!(entry.header().cksum().unwrap(), 0o4253); } #[async_std::test] async fn extracting_malformed_tar_null_blocks() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let mut ar = Builder::new(Vec::new()); let path1 = td.path().join("tmpfile1"); let path2 = td.path().join("tmpfile2"); t!(File::create(&path1).await); t!(File::create(&path2).await); t!(ar .append_file("tmpfile1", &mut t!(File::open(&path1).await)) .await); let mut data = t!(ar.into_inner().await); let amt = data.len(); data.truncate(amt - 512); let mut ar = Builder::new(data); t!(ar .append_file("tmpfile2", &mut t!(File::open(&path2).await)) .await); t!(ar.finish().await); let data = t!(ar.into_inner().await); let ar = Archive::new(&data[..]); assert!(ar.unpack(td.path()).await.is_ok()); } #[async_std::test] async fn empty_filename() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let rdr = Cursor::new(tar!("empty_filename.tar")); let ar = Archive::new(rdr); assert!(ar.unpack(td.path()).await.is_ok()); } #[async_std::test] async fn file_times() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let rdr = Cursor::new(tar!("file_times.tar")); let ar = Archive::new(rdr); t!(ar.unpack(td.path()).await); let meta = fs::metadata(td.path().join("a")).await.unwrap(); let mtime = FileTime::from_last_modification_time(&meta); let atime = FileTime::from_last_access_time(&meta); assert_eq!(mtime.unix_seconds(), 1_000_000_000); assert_eq!(mtime.nanoseconds(), 0); assert_eq!(atime.unix_seconds(), 1_000_000_000); assert_eq!(atime.nanoseconds(), 0); } #[async_std::test] async fn backslash_treated_well() { // Insert a file into an archive with a backslash let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let mut ar = Builder::new(Vec::::new()); t!(ar.append_dir("foo\\bar", td.path()).await); let ar = Archive::new(Cursor::new(t!(ar.into_inner().await))); let f = t!(t!(ar.entries()).next().await.unwrap()); if cfg!(unix) { assert_eq!(t!(f.header().path()).to_str(), Some("foo\\bar")); } else { assert_eq!(t!(f.header().path()).to_str(), Some("foo/bar")); } // Unpack an archive with a backslash in the name let mut ar = Builder::new(Vec::::new()); let mut header = Header::new_gnu(); header.set_metadata(&t!(fs::metadata(td.path()).await)); header.set_size(0); for (a, b) in header.as_old_mut().name.iter_mut().zip(b"foo\\bar\x00") { *a = *b; } header.set_cksum(); t!(ar.append(&header, &mut io::empty()).await); let data = t!(ar.into_inner().await); let ar = Archive::new(&data[..]); let f = t!(t!(ar.entries()).next().await.unwrap()); assert_eq!(t!(f.header().path()).to_str(), Some("foo\\bar")); let ar = Archive::new(&data[..]); t!(ar.unpack(td.path()).await); assert!(fs::metadata(td.path().join("foo\\bar")).await.is_ok()); } #[cfg(unix)] #[async_std::test] async fn nul_bytes_in_path() { use std::{ffi::OsStr, os::unix::prelude::*}; let nul_path = OsStr::from_bytes(b"foo\0"); let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let mut ar = Builder::new(Vec::::new()); let err = ar.append_dir(nul_path, td.path()).await.unwrap_err(); assert!(err.to_string().contains("contains a nul byte")); } #[async_std::test] async fn links() { let ar = Archive::new(Cursor::new(tar!("link.tar"))); let mut entries = t!(ar.entries()); let link = t!(entries.next().await.unwrap()); assert_eq!( t!(link.header().link_name()).as_ref().map(|p| &**p), Some(Path::new("file")) ); let other = t!(entries.next().await.unwrap()); assert!(t!(other.header().link_name()).is_none()); } #[async_std::test] #[cfg(unix)] // making symlinks on windows is hard async fn unpack_links() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let ar = Archive::new(Cursor::new(tar!("link.tar"))); t!(ar.unpack(td.path()).await); let md = t!(fs::symlink_metadata(td.path().join("lnk")).await); assert!(md.file_type().is_symlink()); assert_eq!( &*t!(fs::read_link(td.path().join("lnk")).await), Path::new("file") ); t!(File::open(td.path().join("lnk")).await); } #[async_std::test] async fn pax_simple() { let ar = Archive::new(tar!("pax.tar")); let mut entries = t!(ar.entries()); let mut first = t!(entries.next().await.unwrap()); let mut attributes = t!(first.pax_extensions().await).unwrap(); let first = t!(attributes.next().unwrap()); let second = t!(attributes.next().unwrap()); let third = t!(attributes.next().unwrap()); assert!(attributes.next().is_none()); assert_eq!(first.key(), Ok("mtime")); assert_eq!(first.value(), Ok("1453146164.953123768")); assert_eq!(second.key(), Ok("atime")); assert_eq!(second.value(), Ok("1453251915.24892486")); assert_eq!(third.key(), Ok("ctime")); assert_eq!(third.value(), Ok("1453146164.953123768")); } #[async_std::test] async fn pax_path() { let ar = Archive::new(tar!("pax2.tar")); let mut entries = t!(ar.entries()); let first = t!(entries.next().await.unwrap()); assert!(first.path().unwrap().ends_with("aaaaaaaaaaaaaaa")); } #[async_std::test] async fn long_name_trailing_nul() { let mut b = Builder::new(Vec::::new()); let mut h = Header::new_gnu(); t!(h.set_path("././@LongLink")); h.set_size(4); h.set_entry_type(EntryType::new(b'L')); h.set_cksum(); t!(b.append(&h, "foo\0".as_bytes()).await); let mut h = Header::new_gnu(); t!(h.set_path("bar")); h.set_size(6); h.set_entry_type(EntryType::file()); h.set_cksum(); t!(b.append(&h, b"foobar" as &[u8]).await); let contents = t!(b.into_inner().await); let a = Archive::new(&contents[..]); let e = t!(t!(a.entries()).next().await.unwrap()); assert_eq!(&*e.path_bytes(), b"foo"); } #[async_std::test] async fn long_linkname_trailing_nul() { let mut b = Builder::new(Vec::::new()); let mut h = Header::new_gnu(); t!(h.set_path("././@LongLink")); h.set_size(4); h.set_entry_type(EntryType::new(b'K')); h.set_cksum(); t!(b.append(&h, "foo\0".as_bytes()).await); let mut h = Header::new_gnu(); t!(h.set_path("bar")); h.set_size(6); h.set_entry_type(EntryType::file()); h.set_cksum(); t!(b.append(&h, b"foobar" as &[u8]).await); let contents = t!(b.into_inner().await); let a = Archive::new(&contents[..]); let e = t!(t!(a.entries()).next().await.unwrap()); assert_eq!(&*e.link_name_bytes().unwrap(), b"foo"); } #[async_std::test] async fn encoded_long_name_has_trailing_nul() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let path = td.path().join("foo"); t!(t!(File::create(&path).await).write_all(b"test").await); let mut b = Builder::new(Vec::::new()); let long = "abcd".repeat(200); t!(b.append_file(&long, &mut t!(File::open(&path).await)).await); let contents = t!(b.into_inner().await); let a = Archive::new(&contents[..]); let mut e = t!(t!(a.entries_raw()).next().await.unwrap()); let mut name = Vec::new(); t!(e.read_to_end(&mut name).await); assert_eq!(name[name.len() - 1], 0); let header_name = &e.header().as_gnu().unwrap().name; assert!(header_name.starts_with(b"././@LongLink\x00")); } #[async_std::test] async fn reading_sparse() { let rdr = Cursor::new(tar!("sparse.tar")); let ar = Archive::new(rdr); let mut entries = t!(ar.entries()); let mut a = t!(entries.next().await.unwrap()); let mut s = String::new(); assert_eq!(&*a.header().path_bytes(), b"sparse_begin.txt"); t!(a.read_to_string(&mut s).await); assert_eq!(&s[..5], "test\n"); assert!(s[5..].chars().all(|x| x == '\u{0}')); let mut a = t!(entries.next().await.unwrap()); let mut s = String::new(); assert_eq!(&*a.header().path_bytes(), b"sparse_end.txt"); t!(a.read_to_string(&mut s).await); assert!(s[..s.len() - 9].chars().all(|x| x == '\u{0}')); assert_eq!(&s[s.len() - 9..], "test_end\n"); let mut a = t!(entries.next().await.unwrap()); let mut s = String::new(); assert_eq!(&*a.header().path_bytes(), b"sparse_ext.txt"); t!(a.read_to_string(&mut s).await); assert!(s[..0x1000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x1000..0x1000 + 5], "text\n"); assert!(s[0x1000 + 5..0x3000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x3000..0x3000 + 5], "text\n"); assert!(s[0x3000 + 5..0x5000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x5000..0x5000 + 5], "text\n"); assert!(s[0x5000 + 5..0x7000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x7000..0x7000 + 5], "text\n"); assert!(s[0x7000 + 5..0x9000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x9000..0x9000 + 5], "text\n"); assert!(s[0x9000 + 5..0xb000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0xb000..0xb000 + 5], "text\n"); let mut a = t!(entries.next().await.unwrap()); let mut s = String::new(); assert_eq!(&*a.header().path_bytes(), b"sparse.txt"); t!(a.read_to_string(&mut s).await); assert!(s[..0x1000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x1000..0x1000 + 6], "hello\n"); assert!(s[0x1000 + 6..0x2fa0].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x2fa0..0x2fa0 + 6], "world\n"); assert!(s[0x2fa0 + 6..0x4000].chars().all(|x| x == '\u{0}')); assert!(entries.next().await.is_none()); } #[async_std::test] async fn extract_sparse() { let rdr = Cursor::new(tar!("sparse.tar")); let ar = Archive::new(rdr); let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); t!(ar.unpack(td.path()).await); let mut s = String::new(); t!(t!(File::open(td.path().join("sparse_begin.txt")).await) .read_to_string(&mut s) .await); assert_eq!(&s[..5], "test\n"); assert!(s[5..].chars().all(|x| x == '\u{0}')); s.truncate(0); t!(t!(File::open(td.path().join("sparse_end.txt")).await) .read_to_string(&mut s) .await); assert!(s[..s.len() - 9].chars().all(|x| x == '\u{0}')); assert_eq!(&s[s.len() - 9..], "test_end\n"); s.truncate(0); t!(t!(File::open(td.path().join("sparse_ext.txt")).await) .read_to_string(&mut s) .await); assert!(s[..0x1000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x1000..0x1000 + 5], "text\n"); assert!(s[0x1000 + 5..0x3000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x3000..0x3000 + 5], "text\n"); assert!(s[0x3000 + 5..0x5000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x5000..0x5000 + 5], "text\n"); assert!(s[0x5000 + 5..0x7000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x7000..0x7000 + 5], "text\n"); assert!(s[0x7000 + 5..0x9000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x9000..0x9000 + 5], "text\n"); assert!(s[0x9000 + 5..0xb000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0xb000..0xb000 + 5], "text\n"); s.truncate(0); t!(t!(File::open(td.path().join("sparse.txt")).await) .read_to_string(&mut s) .await); assert!(s[..0x1000].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x1000..0x1000 + 6], "hello\n"); assert!(s[0x1000 + 6..0x2fa0].chars().all(|x| x == '\u{0}')); assert_eq!(&s[0x2fa0..0x2fa0 + 6], "world\n"); assert!(s[0x2fa0 + 6..0x4000].chars().all(|x| x == '\u{0}')); } #[async_std::test] async fn path_separators() { let mut ar = Builder::new(Vec::new()); let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let path = td.path().join("test"); t!(t!(File::create(&path).await).write_all(b"test").await); let short_path: PathBuf = repeat("abcd").take(2).collect(); let long_path: PathBuf = repeat("abcd").take(50).collect(); // Make sure UStar headers normalize to Unix path separators let mut header = Header::new_ustar(); t!(header.set_path(&short_path)); assert_eq!(t!(header.path()), short_path); assert!(!header.path_bytes().contains(&b'\\')); t!(header.set_path(&long_path)); assert_eq!(t!(header.path()), long_path); assert!(!header.path_bytes().contains(&b'\\')); // Make sure GNU headers normalize to Unix path separators, // including the `@LongLink` fallback used by `append_file`. t!(ar .append_file(&short_path, &mut t!(File::open(&path).await)) .await); t!(ar .append_file(&long_path, &mut t!(File::open(&path).await)) .await); let rd = Cursor::new(t!(ar.into_inner().await)); let ar = Archive::new(rd); let mut entries = t!(ar.entries()); let entry = t!(entries.next().await.unwrap()); assert_eq!(t!(entry.path()), short_path); assert!(!entry.path_bytes().contains(&b'\\')); let entry = t!(entries.next().await.unwrap()); assert_eq!(t!(entry.path()), long_path); assert!(!entry.path_bytes().contains(&b'\\')); assert!(entries.next().await.is_none()); } #[async_std::test] #[cfg(unix)] async fn append_path_symlink() { use std::{borrow::Cow, env, os::unix::fs::symlink}; let mut ar = Builder::new(Vec::new()); ar.follow_symlinks(false); let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let long_linkname = "abcd".repeat(30); let long_pathname = "dcba".repeat(30); t!(env::set_current_dir(td.path())); // "short" path name / short link name t!(symlink("testdest", "test")); t!(ar.append_path("test").await); // short path name / long link name t!(symlink(&long_linkname, "test2")); t!(ar.append_path("test2").await); // long path name / long link name t!(symlink(&long_linkname, &long_pathname)); t!(ar.append_path(&long_pathname).await); let rd = Cursor::new(t!(ar.into_inner().await)); let ar = Archive::new(rd); let mut entries = t!(ar.entries()); let entry = t!(entries.next().await.unwrap()); assert_eq!(t!(entry.path()), Path::new("test")); assert_eq!( t!(entry.link_name()), Some(Cow::from(Path::new("testdest"))) ); assert_eq!(t!(entry.header().size()), 0); let entry = t!(entries.next().await.unwrap()); assert_eq!(t!(entry.path()), Path::new("test2")); assert_eq!( t!(entry.link_name()), Some(Cow::from(Path::new(&long_linkname))) ); assert_eq!(t!(entry.header().size()), 0); let entry = t!(entries.next().await.unwrap()); assert_eq!(t!(entry.path()), Path::new(&long_pathname)); assert_eq!( t!(entry.link_name()), Some(Cow::from(Path::new(&long_linkname))) ); assert_eq!(t!(entry.header().size()), 0); assert!(entries.next().await.is_none()); } #[async_std::test] async fn name_with_slash_doesnt_fool_long_link_and_bsd_compat() { let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let mut ar = Builder::new(Vec::new()); let mut h = Header::new_gnu(); t!(h.set_path("././@LongLink")); h.set_size(4); h.set_entry_type(EntryType::new(b'L')); h.set_cksum(); t!(ar.append(&h, "foo\0".as_bytes()).await); let mut header = Header::new_gnu(); header.set_entry_type(EntryType::Regular); t!(header.set_path("testdir/")); header.set_size(0); header.set_cksum(); t!(ar.append(&header, &mut io::empty()).await); // Extracting let rdr = Cursor::new(t!(ar.into_inner().await)); let ar = Archive::new(rdr); t!(ar.clone().unpack(td.path()).await); // Iterating let rdr = Cursor::new(ar.into_inner().map_err(|_| ()).unwrap().into_inner()); let ar = Archive::new(rdr); assert!(t!(ar.entries()).all(|fr| fr.is_ok()).await); assert!(td.path().join("foo").is_file()); } #[async_std::test] async fn insert_local_file_different_name() { let mut ar = Builder::new(Vec::new()); let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let path = td.path().join("directory"); t!(fs::create_dir(&path).await); ar.append_path_with_name(&path, "archive/dir") .await .unwrap(); let path = td.path().join("file"); t!(t!(File::create(&path).await).write_all(b"test").await); ar.append_path_with_name(&path, "archive/dir/f") .await .unwrap(); let rd = Cursor::new(t!(ar.into_inner().await)); let ar = Archive::new(rd); let mut entries = t!(ar.entries()); let entry = t!(entries.next().await.unwrap()); assert_eq!(t!(entry.path()), Path::new("archive/dir")); let entry = t!(entries.next().await.unwrap()); assert_eq!(t!(entry.path()), Path::new("archive/dir/f")); assert!(entries.next().await.is_none()); } #[async_std::test] #[cfg(unix)] async fn tar_directory_containing_symlink_to_directory() { use std::os::unix::fs::symlink; let td = t!(TempBuilder::new().prefix("async-tar").tempdir()); let dummy_src = t!(TempBuilder::new().prefix("dummy_src").tempdir()); let dummy_dst = td.path().join("dummy_dst"); let mut ar = Builder::new(Vec::new()); t!(symlink(dummy_src.path().display().to_string(), &dummy_dst)); assert!(dummy_dst.read_link().is_ok()); assert!(dummy_dst.read_link().unwrap().is_dir()); ar.append_dir_all("symlinks", td.path()).await.unwrap(); ar.finish().await.unwrap(); } #[async_std::test] async fn long_path() { let td = t!(TempBuilder::new().prefix("tar-rs").tempdir()); let rdr = Cursor::new(tar!("7z_long_path.tar")); let ar = Archive::new(rdr); ar.unpack(td.path()).await.unwrap(); }