2 #[cfg(target_os = "windows")]
6 use std::path::{Path, PathBuf};
7 #[cfg(target_os = "windows")]
10 std::os::windows::ffi::OsStrExt
12 #[cfg(not(target_os = "windows"))]
13 use std::os::unix::io::AsRawFd;
15 pub(crate) trait DiskWriteable {
16 fn write_to_file(&self, writer: &mut fs::File) -> Result<(), std::io::Error>;
19 pub(crate) fn get_full_filepath(filepath: String, filename: String) -> String {
20 let mut path = PathBuf::from(filepath);
22 path.to_str().unwrap().to_string()
24 #[cfg(target_os = "windows")]
30 return Err(std::io::Error::last_os_error())
35 #[cfg(target_os = "windows")]
36 fn path_to_windows_str<T: AsRef<OsStr>>(x: T) -> Vec<winapi::shared::ntdef::WCHAR> {
37 x.as_ref().encode_wide().chain(Some(0)).collect()
40 #[allow(bare_trait_objects)]
41 pub(crate) fn write_to_file<D: DiskWriteable>(path: String, filename: String, data: &D) -> std::io::Result<()> {
42 println!("VMW: creating dir");
43 fs::create_dir_all(path.clone())?;
44 println!("VMW: created dir");
46 // Do a crazy dance with lots of fsync()s to be overly cautious here...
47 // We never want to end up in a state where we've lost the old data, or end up using the
48 // old data on power loss after we've returned.
49 // The way to atomically write a file on Unix platforms is:
50 // open(tmpname), write(tmpfile), fsync(tmpfile), close(tmpfile), rename(), fsync(dir)
51 let filename_with_path = get_full_filepath(path.clone(), filename);
52 let tmp_filename = format!("{}.tmp", filename_with_path);
55 // Note that going by rust-lang/rust@d602a6b, on MacOS it is only safe to use
56 // rust stdlib 1.36 or higher.
57 println!("VMW: about to create file");
58 let mut f = fs::File::create(&tmp_filename)?;
59 println!("VMW: created file");
60 data.write_to_file(&mut f)?;
61 println!("VMW: about to sync all");
63 println!("VMW: sync'd all");
65 // Fsync the parent directory on Unix.
66 #[cfg(not(target_os = "windows"))]
68 fs::rename(&tmp_filename, &filename_with_path)?;
69 let path = Path::new(&filename_with_path).parent().unwrap();
70 let dir_file = fs::OpenOptions::new().read(true).open(path)?;
71 unsafe { libc::fsync(dir_file.as_raw_fd()); }
73 // std::thread::sleep(std::time::Duration::new(60, 0));
74 #[cfg(target_os = "windows")]
76 println!("VMW: entries in dir:");
77 let dir_perms = fs::metadata(path.clone()).unwrap().permissions();
78 println!("VMW: dir perms: {:?}, readonly: {}", dir_perms, dir_perms.readonly());
79 let dir = PathBuf::from(path.clone());
80 for entry in fs::read_dir(dir).unwrap() {
81 let entry = entry.unwrap();
82 let metadata = entry.metadata().unwrap();
83 println!("VMW: entry in dir: {:?}, perms in entry: {:?}, readonly: {}", entry.path(), metadata.permissions(), metadata.permissions().readonly());
86 // let mut dir_perms = fs::metadata(path.clone()).unwrap().permissions();
87 // dir_perms.set_readonly(false);
88 // if let Ok(metadata) = fs::metadata(filename_with_path.clone()) {
89 // let mut perms = metadata.permissions();
90 // perms.set_readonly(false);
92 // // let mut perms = fs::metadata(filename_with_path.clone())?.permissions();
93 // let mut tmp_perms = fs::metadata(tmp_filename.clone())?.permissions();
94 // tmp_perms.set_readonly(false);
95 // println!("VMW: about to rename");
96 // let src = PathBuf::from(tmp_filename);
97 // let dst = PathBuf::from(filename_with_path);
98 // fs::rename(&tmp_filename.clone(), &filename_with_path.clone())?;
99 // call!(unsafe {winapi::um::winbase::MoveFileExW(
100 // path_to_windows_str(src).as_ptr(), path_to_windows_str(dst).as_ptr(),
101 // winapi::um::winbase::MOVEFILE_WRITE_THROUGH | winapi::um::winbase::MOVEFILE_REPLACE_EXISTING
103 let backup_filepath = format!("{}.backup", filename_with_path.clone());
104 call!(unsafe {winapi::um::winbase::ReplaceFileW(
105 path_to_windows_str(src).as_ptr(), path_to_windows_str(dst).as_ptr(), path_to_windows_str(backup_filepath).as_ptr(),
106 winapi::um::winbase::MOVEFILE_WRITE_THROUGH | winapi::um::winbase::MOVEFILE_REPLACE_EXISTING, std::ptr::null, std::ptr::null
108 println!("VMW: renamed");
115 use super::{DiskWriteable, get_full_filepath, write_to_file};
120 struct TestWriteable{}
121 impl DiskWriteable for TestWriteable {
122 fn write_to_file(&self, writer: &mut fs::File) -> Result<(), io::Error> {
123 writer.write_all(&[42; 1])
127 // Test that if the persister's path to channel data is read-only, writing
128 // data to it fails. Windows ignores the read-only flag for folders, so this
129 // test is Unix-only.
130 #[cfg(not(target_os = "windows"))]
132 fn test_readonly_dir() {
133 let test_writeable = TestWriteable{};
134 let filename = "test_readonly_dir_persister_filename".to_string();
135 let path = "test_readonly_dir_persister_dir";
136 fs::create_dir_all(path.to_string()).unwrap();
137 let mut perms = fs::metadata(path.to_string()).unwrap().permissions();
138 perms.set_readonly(true);
139 fs::set_permissions(path.to_string(), perms).unwrap();
140 match write_to_file(path.to_string(), filename, &test_writeable) {
141 Err(e) => assert_eq!(e.kind(), io::ErrorKind::PermissionDenied),
142 _ => panic!("Unexpected error message")
146 // Test failure to rename in the process of atomically creating a channel
147 // monitor's file. We induce this failure by making the `tmp` file a
149 // Explanation: given "from" = the file being renamed, "to" = the
150 // renamee that already exists: Windows should fail because it'll fail
151 // whenever "to" is a directory, and Unix should fail because if "from" is a
152 // file, then "to" is also required to be a file.
154 fn test_rename_failure() {
155 let test_writeable = TestWriteable{};
156 let filename = "test_rename_failure_filename";
157 let path = "test_rename_failure_dir";
158 // Create the channel data file and make it a directory.
159 fs::create_dir_all(get_full_filepath(path.to_string(), filename.to_string())).unwrap();
160 match write_to_file(path.to_string(), filename.to_string(), &test_writeable) {
162 #[cfg(not(target_os = "windows"))]
163 assert_eq!(e.kind(), io::ErrorKind::Other);
164 #[cfg(target_os = "windows")]
165 assert_eq!(e.kind(), io::ErrorKind::PermissionDenied);
167 _ => panic!("Unexpected error message")
169 fs::remove_dir_all(path).unwrap();
173 fn test_diskwriteable_failure() {
174 struct FailingWriteable {}
175 impl DiskWriteable for FailingWriteable {
176 fn write_to_file(&self, _writer: &mut fs::File) -> Result<(), std::io::Error> {
177 Err(std::io::Error::new(std::io::ErrorKind::Other, "expected failure"))
181 let filename = "test_diskwriteable_failure";
182 let path = "test_diskwriteable_failure_dir";
183 let test_writeable = FailingWriteable{};
184 match write_to_file(path.to_string(), filename.to_string(), &test_writeable) {
186 assert_eq!(e.kind(), std::io::ErrorKind::Other);
187 assert_eq!(e.get_ref().unwrap().to_string(), "expected failure");
189 _ => panic!("unexpected result")
191 fs::remove_dir_all(path).unwrap();
194 // Test failure to create the temporary file in the persistence process.
195 // We induce this failure by having the temp file already exist and be a
198 fn test_tmp_file_creation_failure() {
199 let test_writeable = TestWriteable{};
200 let filename = "test_tmp_file_creation_failure_filename".to_string();
201 let path = "test_tmp_file_creation_failure_dir".to_string();
203 // Create the tmp file and make it a directory.
204 let tmp_path = get_full_filepath(path.clone(), format!("{}.tmp", filename.clone()));
205 fs::create_dir_all(tmp_path).unwrap();
206 match write_to_file(path, filename, &test_writeable) {
208 #[cfg(not(target_os = "windows"))]
209 assert_eq!(e.kind(), io::ErrorKind::Other);
210 #[cfg(target_os = "windows")]
211 assert_eq!(e.kind(), io::ErrorKind::PermissionDenied);
213 _ => panic!("Unexpected error message")