use crate::os::windows::prelude::*; use crate::borrow::Cow; use crate::ffi::OsString; use crate::fmt; use crate::io::{self, BorrowedCursor, Error, IoSlice, IoSliceMut, SeekFrom}; use crate::mem::{self, MaybeUninit}; use crate::os::windows::io::{AsHandle, BorrowedHandle}; use crate::path::{Path, PathBuf}; use crate::ptr; use crate::slice; use crate::sync::Arc; use crate::sys::handle::Handle; use crate::sys::time::SystemTime; use crate::sys::{c, cvt, Align8}; use crate::sys_common::{AsInner, FromInner, IntoInner}; use crate::thread; use super::path::maybe_verbatim; use super::to_u16s; pub struct File { handle: Handle, } #[derive(Clone)] pub struct FileAttr { attributes: c::DWORD, creation_time: c::FILETIME, last_access_time: c::FILETIME, last_write_time: c::FILETIME, file_size: u64, reparse_tag: c::DWORD, volume_serial_number: Option, number_of_links: Option, file_index: Option, } #[derive(Copy, Clone, PartialEq, Eq, Hash, Debug)] pub struct FileType { attributes: c::DWORD, reparse_tag: c::DWORD, } pub struct ReadDir { handle: FindNextFileHandle, root: Arc, first: Option, } struct FindNextFileHandle(c::HANDLE); unsafe impl Send for FindNextFileHandle {} unsafe impl Sync for FindNextFileHandle {} pub struct DirEntry { root: Arc, data: c::WIN32_FIND_DATAW, } unsafe impl Send for OpenOptions {} unsafe impl Sync for OpenOptions {} #[derive(Clone, Debug)] pub struct OpenOptions { // generic read: bool, write: bool, append: bool, truncate: bool, create: bool, create_new: bool, // system-specific custom_flags: u32, access_mode: Option, attributes: c::DWORD, share_mode: c::DWORD, security_qos_flags: c::DWORD, security_attributes: c::LPSECURITY_ATTRIBUTES, } #[derive(Clone, PartialEq, Eq, Debug)] pub struct FilePermissions { attrs: c::DWORD, } #[derive(Copy, Clone, Debug, Default)] pub struct FileTimes { accessed: Option, modified: Option, } #[derive(Debug)] pub struct DirBuilder; impl fmt::Debug for ReadDir { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { // This will only be called from std::fs::ReadDir, which will add a "ReadDir()" frame. // Thus the result will be e g 'ReadDir("C:\")' fmt::Debug::fmt(&*self.root, f) } } impl Iterator for ReadDir { type Item = io::Result; fn next(&mut self) -> Option> { if let Some(first) = self.first.take() { if let Some(e) = DirEntry::new(&self.root, &first) { return Some(Ok(e)); } } unsafe { let mut wfd = mem::zeroed(); loop { if c::FindNextFileW(self.handle.0, &mut wfd) == 0 { if c::GetLastError() == c::ERROR_NO_MORE_FILES { return None; } else { return Some(Err(Error::last_os_error())); } } if let Some(e) = DirEntry::new(&self.root, &wfd) { return Some(Ok(e)); } } } } } impl Drop for FindNextFileHandle { fn drop(&mut self) { let r = unsafe { c::FindClose(self.0) }; debug_assert!(r != 0); } } impl DirEntry { fn new(root: &Arc, wfd: &c::WIN32_FIND_DATAW) -> Option { match &wfd.cFileName[0..3] { // check for '.' and '..' &[46, 0, ..] | &[46, 46, 0, ..] => return None, _ => {} } Some(DirEntry { root: root.clone(), data: *wfd }) } pub fn path(&self) -> PathBuf { self.root.join(&self.file_name()) } pub fn file_name(&self) -> OsString { let filename = super::truncate_utf16_at_nul(&self.data.cFileName); OsString::from_wide(filename) } pub fn file_type(&self) -> io::Result { Ok(FileType::new( self.data.dwFileAttributes, /* reparse_tag = */ self.data.dwReserved0, )) } pub fn metadata(&self) -> io::Result { Ok(self.data.into()) } } impl OpenOptions { pub fn new() -> OpenOptions { OpenOptions { // generic read: false, write: false, append: false, truncate: false, create: false, create_new: false, // system-specific custom_flags: 0, access_mode: None, share_mode: c::FILE_SHARE_READ | c::FILE_SHARE_WRITE | c::FILE_SHARE_DELETE, attributes: 0, security_qos_flags: 0, security_attributes: ptr::null_mut(), } } pub fn read(&mut self, read: bool) { self.read = read; } pub fn write(&mut self, write: bool) { self.write = write; } pub fn append(&mut self, append: bool) { self.append = append; } pub fn truncate(&mut self, truncate: bool) { self.truncate = truncate; } pub fn create(&mut self, create: bool) { self.create = create; } pub fn create_new(&mut self, create_new: bool) { self.create_new = create_new; } pub fn custom_flags(&mut self, flags: u32) { self.custom_flags = flags; } pub fn access_mode(&mut self, access_mode: u32) { self.access_mode = Some(access_mode); } pub fn share_mode(&mut self, share_mode: u32) { self.share_mode = share_mode; } pub fn attributes(&mut self, attrs: u32) { self.attributes = attrs; } pub fn security_qos_flags(&mut self, flags: u32) { // We have to set `SECURITY_SQOS_PRESENT` here, because one of the valid flags we can // receive is `SECURITY_ANONYMOUS = 0x0`, which we can't check for later on. self.security_qos_flags = flags | c::SECURITY_SQOS_PRESENT; } pub fn security_attributes(&mut self, attrs: c::LPSECURITY_ATTRIBUTES) { self.security_attributes = attrs; } fn get_access_mode(&self) -> io::Result { const ERROR_INVALID_PARAMETER: i32 = 87; match (self.read, self.write, self.append, self.access_mode) { (.., Some(mode)) => Ok(mode), (true, false, false, None) => Ok(c::GENERIC_READ), (false, true, false, None) => Ok(c::GENERIC_WRITE), (true, true, false, None) => Ok(c::GENERIC_READ | c::GENERIC_WRITE), (false, _, true, None) => Ok(c::FILE_GENERIC_WRITE & !c::FILE_WRITE_DATA), (true, _, true, None) => { Ok(c::GENERIC_READ | (c::FILE_GENERIC_WRITE & !c::FILE_WRITE_DATA)) } (false, false, false, None) => Err(Error::from_raw_os_error(ERROR_INVALID_PARAMETER)), } } fn get_creation_mode(&self) -> io::Result { const ERROR_INVALID_PARAMETER: i32 = 87; match (self.write, self.append) { (true, false) => {} (false, false) => { if self.truncate || self.create || self.create_new { return Err(Error::from_raw_os_error(ERROR_INVALID_PARAMETER)); } } (_, true) => { if self.truncate && !self.create_new { return Err(Error::from_raw_os_error(ERROR_INVALID_PARAMETER)); } } } Ok(match (self.create, self.truncate, self.create_new) { (false, false, false) => c::OPEN_EXISTING, (true, false, false) => c::OPEN_ALWAYS, (false, true, false) => c::TRUNCATE_EXISTING, (true, true, false) => c::CREATE_ALWAYS, (_, _, true) => c::CREATE_NEW, }) } fn get_flags_and_attributes(&self) -> c::DWORD { self.custom_flags | self.attributes | self.security_qos_flags | if self.create_new { c::FILE_FLAG_OPEN_REPARSE_POINT } else { 0 } } } impl File { pub fn open(path: &Path, opts: &OpenOptions) -> io::Result { let path = maybe_verbatim(path)?; let handle = unsafe { c::CreateFileW( path.as_ptr(), opts.get_access_mode()?, opts.share_mode, opts.security_attributes, opts.get_creation_mode()?, opts.get_flags_and_attributes(), ptr::null_mut(), ) }; if let Ok(handle) = handle.try_into() { Ok(File { handle: Handle::from_inner(handle) }) } else { Err(Error::last_os_error()) } } pub fn fsync(&self) -> io::Result<()> { cvt(unsafe { c::FlushFileBuffers(self.handle.as_raw_handle()) })?; Ok(()) } pub fn datasync(&self) -> io::Result<()> { self.fsync() } pub fn truncate(&self, size: u64) -> io::Result<()> { let mut info = c::FILE_END_OF_FILE_INFO { EndOfFile: size as c::LARGE_INTEGER }; let size = mem::size_of_val(&info); cvt(unsafe { c::SetFileInformationByHandle( self.handle.as_raw_handle(), c::FileEndOfFileInfo, &mut info as *mut _ as *mut _, size as c::DWORD, ) })?; Ok(()) } #[cfg(not(target_vendor = "uwp"))] pub fn file_attr(&self) -> io::Result { unsafe { let mut info: c::BY_HANDLE_FILE_INFORMATION = mem::zeroed(); cvt(c::GetFileInformationByHandle(self.handle.as_raw_handle(), &mut info))?; let mut reparse_tag = 0; if info.dwFileAttributes & c::FILE_ATTRIBUTE_REPARSE_POINT != 0 { let mut attr_tag: c::FILE_ATTRIBUTE_TAG_INFO = mem::zeroed(); cvt(c::GetFileInformationByHandleEx( self.handle.as_raw_handle(), c::FileAttributeTagInfo, ptr::addr_of_mut!(attr_tag).cast(), mem::size_of::().try_into().unwrap(), ))?; if attr_tag.FileAttributes & c::FILE_ATTRIBUTE_REPARSE_POINT != 0 { reparse_tag = attr_tag.ReparseTag; } } Ok(FileAttr { attributes: info.dwFileAttributes, creation_time: info.ftCreationTime, last_access_time: info.ftLastAccessTime, last_write_time: info.ftLastWriteTime, file_size: (info.nFileSizeLow as u64) | ((info.nFileSizeHigh as u64) << 32), reparse_tag, volume_serial_number: Some(info.dwVolumeSerialNumber), number_of_links: Some(info.nNumberOfLinks), file_index: Some( (info.nFileIndexLow as u64) | ((info.nFileIndexHigh as u64) << 32), ), }) } } #[cfg(target_vendor = "uwp")] pub fn file_attr(&self) -> io::Result { unsafe { let mut info: c::FILE_BASIC_INFO = mem::zeroed(); let size = mem::size_of_val(&info); cvt(c::GetFileInformationByHandleEx( self.handle.as_raw_handle(), c::FileBasicInfo, &mut info as *mut _ as *mut libc::c_void, size as c::DWORD, ))?; let mut attr = FileAttr { attributes: info.FileAttributes, creation_time: c::FILETIME { dwLowDateTime: info.CreationTime as c::DWORD, dwHighDateTime: (info.CreationTime >> 32) as c::DWORD, }, last_access_time: c::FILETIME { dwLowDateTime: info.LastAccessTime as c::DWORD, dwHighDateTime: (info.LastAccessTime >> 32) as c::DWORD, }, last_write_time: c::FILETIME { dwLowDateTime: info.LastWriteTime as c::DWORD, dwHighDateTime: (info.LastWriteTime >> 32) as c::DWORD, }, file_size: 0, reparse_tag: 0, volume_serial_number: None, number_of_links: None, file_index: None, }; let mut info: c::FILE_STANDARD_INFO = mem::zeroed(); let size = mem::size_of_val(&info); cvt(c::GetFileInformationByHandleEx( self.handle.as_raw_handle(), c::FileStandardInfo, &mut info as *mut _ as *mut libc::c_void, size as c::DWORD, ))?; attr.file_size = info.AllocationSize as u64; attr.number_of_links = Some(info.NumberOfLinks); if attr.file_type().is_reparse_point() { let mut attr_tag: c::FILE_ATTRIBUTE_TAG_INFO = mem::zeroed(); cvt(c::GetFileInformationByHandleEx( self.handle.as_raw_handle(), c::FileAttributeTagInfo, ptr::addr_of_mut!(attr_tag).cast(), mem::size_of::().try_into().unwrap(), ))?; if attr_tag.FileAttributes & c::FILE_ATTRIBUTE_REPARSE_POINT != 0 { attr.reparse_tag = attr_tag.ReparseTag; } } Ok(attr) } } pub fn read(&self, buf: &mut [u8]) -> io::Result { self.handle.read(buf) } pub fn read_vectored(&self, bufs: &mut [IoSliceMut<'_>]) -> io::Result { self.handle.read_vectored(bufs) } #[inline] pub fn is_read_vectored(&self) -> bool { self.handle.is_read_vectored() } pub fn read_at(&self, buf: &mut [u8], offset: u64) -> io::Result { self.handle.read_at(buf, offset) } pub fn read_buf(&self, cursor: BorrowedCursor<'_>) -> io::Result<()> { self.handle.read_buf(cursor) } pub fn write(&self, buf: &[u8]) -> io::Result { self.handle.write(buf) } pub fn write_vectored(&self, bufs: &[IoSlice<'_>]) -> io::Result { self.handle.write_vectored(bufs) } #[inline] pub fn is_write_vectored(&self) -> bool { self.handle.is_write_vectored() } pub fn write_at(&self, buf: &[u8], offset: u64) -> io::Result { self.handle.write_at(buf, offset) } pub fn flush(&self) -> io::Result<()> { Ok(()) } pub fn seek(&self, pos: SeekFrom) -> io::Result { let (whence, pos) = match pos { // Casting to `i64` is fine, `SetFilePointerEx` reinterprets this // integer as `u64`. SeekFrom::Start(n) => (c::FILE_BEGIN, n as i64), SeekFrom::End(n) => (c::FILE_END, n), SeekFrom::Current(n) => (c::FILE_CURRENT, n), }; let pos = pos as c::LARGE_INTEGER; let mut newpos = 0; cvt(unsafe { c::SetFilePointerEx(self.handle.as_raw_handle(), pos, &mut newpos, whence) })?; Ok(newpos as u64) } pub fn duplicate(&self) -> io::Result { Ok(Self { handle: self.handle.try_clone()? }) } // NB: returned pointer is derived from `space`, and has provenance to // match. A raw pointer is returned rather than a reference in order to // avoid narrowing provenance to the actual `REPARSE_DATA_BUFFER`. fn reparse_point( &self, space: &mut Align8<[MaybeUninit]>, ) -> io::Result<(c::DWORD, *const c::REPARSE_DATA_BUFFER)> { unsafe { let mut bytes = 0; cvt({ // Grab this in advance to avoid it invalidating the pointer // we get from `space.0.as_mut_ptr()`. let len = space.0.len(); c::DeviceIoControl( self.handle.as_raw_handle(), c::FSCTL_GET_REPARSE_POINT, ptr::null_mut(), 0, space.0.as_mut_ptr().cast(), len as c::DWORD, &mut bytes, ptr::null_mut(), ) })?; const _: () = assert!(core::mem::align_of::() <= 8); Ok((bytes, space.0.as_ptr().cast::())) } } fn readlink(&self) -> io::Result { let mut space = Align8([MaybeUninit::::uninit(); c::MAXIMUM_REPARSE_DATA_BUFFER_SIZE]); let (_bytes, buf) = self.reparse_point(&mut space)?; unsafe { let (path_buffer, subst_off, subst_len, relative) = match (*buf).ReparseTag { c::IO_REPARSE_TAG_SYMLINK => { let info: *const c::SYMBOLIC_LINK_REPARSE_BUFFER = ptr::addr_of!((*buf).rest).cast(); assert!(info.is_aligned()); ( ptr::addr_of!((*info).PathBuffer).cast::(), (*info).SubstituteNameOffset / 2, (*info).SubstituteNameLength / 2, (*info).Flags & c::SYMLINK_FLAG_RELATIVE != 0, ) } c::IO_REPARSE_TAG_MOUNT_POINT => { let info: *const c::MOUNT_POINT_REPARSE_BUFFER = ptr::addr_of!((*buf).rest).cast(); assert!(info.is_aligned()); ( ptr::addr_of!((*info).PathBuffer).cast::(), (*info).SubstituteNameOffset / 2, (*info).SubstituteNameLength / 2, false, ) } _ => { return Err(io::const_io_error!( io::ErrorKind::Uncategorized, "Unsupported reparse point type", )); } }; let subst_ptr = path_buffer.add(subst_off.into()); let mut subst = slice::from_raw_parts(subst_ptr, subst_len as usize); // Absolute paths start with an NT internal namespace prefix `\??\` // We should not let it leak through. if !relative && subst.starts_with(&[92u16, 63u16, 63u16, 92u16]) { subst = &subst[4..]; } Ok(PathBuf::from(OsString::from_wide(subst))) } } pub fn set_permissions(&self, perm: FilePermissions) -> io::Result<()> { let mut info = c::FILE_BASIC_INFO { CreationTime: 0, LastAccessTime: 0, LastWriteTime: 0, ChangeTime: 0, FileAttributes: perm.attrs, }; let size = mem::size_of_val(&info); cvt(unsafe { c::SetFileInformationByHandle( self.handle.as_raw_handle(), c::FileBasicInfo, &mut info as *mut _ as *mut _, size as c::DWORD, ) })?; Ok(()) } pub fn set_times(&self, times: FileTimes) -> io::Result<()> { let is_zero = |t: c::FILETIME| t.dwLowDateTime == 0 && t.dwHighDateTime == 0; if times.accessed.map_or(false, is_zero) || times.modified.map_or(false, is_zero) { return Err(io::const_io_error!( io::ErrorKind::InvalidInput, "Cannot set file timestamp to 0", )); } let is_max = |t: c::FILETIME| t.dwLowDateTime == c::DWORD::MAX && t.dwHighDateTime == c::DWORD::MAX; if times.accessed.map_or(false, is_max) || times.modified.map_or(false, is_max) { return Err(io::const_io_error!( io::ErrorKind::InvalidInput, "Cannot set file timestamp to 0xFFFF_FFFF_FFFF_FFFF", )); } cvt(unsafe { c::SetFileTime(self.as_handle(), None, times.accessed.as_ref(), times.modified.as_ref()) })?; Ok(()) } /// Get only basic file information such as attributes and file times. fn basic_info(&self) -> io::Result { unsafe { let mut info: c::FILE_BASIC_INFO = mem::zeroed(); let size = mem::size_of_val(&info); cvt(c::GetFileInformationByHandleEx( self.handle.as_raw_handle(), c::FileBasicInfo, &mut info as *mut _ as *mut libc::c_void, size as c::DWORD, ))?; Ok(info) } } /// Delete using POSIX semantics. /// /// Files will be deleted as soon as the handle is closed. This is supported /// for Windows 10 1607 (aka RS1) and later. However some filesystem /// drivers will not support it even then, e.g. FAT32. /// /// If the operation is not supported for this filesystem or OS version /// then errors will be `ERROR_NOT_SUPPORTED` or `ERROR_INVALID_PARAMETER`. fn posix_delete(&self) -> io::Result<()> { let mut info = c::FILE_DISPOSITION_INFO_EX { Flags: c::FILE_DISPOSITION_DELETE | c::FILE_DISPOSITION_POSIX_SEMANTICS | c::FILE_DISPOSITION_IGNORE_READONLY_ATTRIBUTE, }; let size = mem::size_of_val(&info); cvt(unsafe { c::SetFileInformationByHandle( self.handle.as_raw_handle(), c::FileDispositionInfoEx, &mut info as *mut _ as *mut _, size as c::DWORD, ) })?; Ok(()) } /// Delete a file using win32 semantics. The file won't actually be deleted /// until all file handles are closed. However, marking a file for deletion /// will prevent anyone from opening a new handle to the file. fn win32_delete(&self) -> io::Result<()> { let mut info = c::FILE_DISPOSITION_INFO { DeleteFile: c::TRUE as _ }; let size = mem::size_of_val(&info); cvt(unsafe { c::SetFileInformationByHandle( self.handle.as_raw_handle(), c::FileDispositionInfo, &mut info as *mut _ as *mut _, size as c::DWORD, ) })?; Ok(()) } /// Fill the given buffer with as many directory entries as will fit. /// This will remember its position and continue from the last call unless /// `restart` is set to `true`. /// /// The returned bool indicates if there are more entries or not. /// It is an error if `self` is not a directory. /// /// # Symlinks and other reparse points /// /// On Windows a file is either a directory or a non-directory. /// A symlink directory is simply an empty directory with some "reparse" metadata attached. /// So if you open a link (not its target) and iterate the directory, /// you will always iterate an empty directory regardless of the target. fn fill_dir_buff(&self, buffer: &mut DirBuff, restart: bool) -> io::Result { let class = if restart { c::FileIdBothDirectoryRestartInfo } else { c::FileIdBothDirectoryInfo }; unsafe { let result = cvt(c::GetFileInformationByHandleEx( self.handle.as_raw_handle(), class, buffer.as_mut_ptr().cast(), buffer.capacity() as _, )); match result { Ok(_) => Ok(true), Err(e) if e.raw_os_error() == Some(c::ERROR_NO_MORE_FILES as _) => Ok(false), Err(e) => Err(e), } } } } /// A buffer for holding directory entries. struct DirBuff { buffer: Box; Self::BUFFER_SIZE]>>, } impl DirBuff { const BUFFER_SIZE: usize = 1024; fn new() -> Self { Self { // Safety: `Align8<[MaybeUninit; N]>` does not need // initialization. buffer: unsafe { Box::new_uninit().assume_init() }, } } fn capacity(&self) -> usize { self.buffer.0.len() } fn as_mut_ptr(&mut self) -> *mut u8 { self.buffer.0.as_mut_ptr().cast() } /// Returns a `DirBuffIter`. fn iter(&self) -> DirBuffIter<'_> { DirBuffIter::new(self) } } impl AsRef<[MaybeUninit]> for DirBuff { fn as_ref(&self) -> &[MaybeUninit] { &self.buffer.0 } } /// An iterator over entries stored in a `DirBuff`. /// /// Currently only returns file names (UTF-16 encoded). struct DirBuffIter<'a> { buffer: Option<&'a [MaybeUninit]>, cursor: usize, } impl<'a> DirBuffIter<'a> { fn new(buffer: &'a DirBuff) -> Self { Self { buffer: Some(buffer.as_ref()), cursor: 0 } } } impl<'a> Iterator for DirBuffIter<'a> { type Item = (Cow<'a, [u16]>, bool); fn next(&mut self) -> Option { use crate::mem::size_of; let buffer = &self.buffer?[self.cursor..]; // Get the name and next entry from the buffer. // SAFETY: // - The buffer contains a `FILE_ID_BOTH_DIR_INFO` struct but the last // field (the file name) is unsized. So an offset has to be used to // get the file name slice. // - The OS has guaranteed initialization of the fields of // `FILE_ID_BOTH_DIR_INFO` and the trailing filename (for at least // `FileNameLength` bytes) let (name, is_directory, next_entry) = unsafe { let info = buffer.as_ptr().cast::(); // While this is guaranteed to be aligned in documentation for // https://docs.microsoft.com/en-us/windows/win32/api/winbase/ns-winbase-file_id_both_dir_info // it does not seem that reality is so kind, and assuming this // caused crashes in some cases (https://github.com/rust-lang/rust/issues/104530) // presumably, this can be blamed on buggy filesystem drivers, but who knows. let next_entry = ptr::addr_of!((*info).NextEntryOffset).read_unaligned() as usize; let length = ptr::addr_of!((*info).FileNameLength).read_unaligned() as usize; let attrs = ptr::addr_of!((*info).FileAttributes).read_unaligned(); let name = from_maybe_unaligned( ptr::addr_of!((*info).FileName).cast::(), length / size_of::(), ); let is_directory = (attrs & c::FILE_ATTRIBUTE_DIRECTORY) != 0; (name, is_directory, next_entry) }; if next_entry == 0 { self.buffer = None } else { self.cursor += next_entry } // Skip `.` and `..` pseudo entries. const DOT: u16 = b'.' as u16; match &name[..] { [DOT] | [DOT, DOT] => self.next(), _ => Some((name, is_directory)), } } } unsafe fn from_maybe_unaligned<'a>(p: *const u16, len: usize) -> Cow<'a, [u16]> { if p.is_aligned() { Cow::Borrowed(crate::slice::from_raw_parts(p, len)) } else { Cow::Owned((0..len).map(|i| p.add(i).read_unaligned()).collect()) } } /// Open a link relative to the parent directory, ensure no symlinks are followed. fn open_link_no_reparse(parent: &File, name: &[u16], access: u32) -> io::Result { // This is implemented using the lower level `NtCreateFile` function as // unfortunately opening a file relative to a parent is not supported by // win32 functions. It is however a fundamental feature of the NT kernel. // // See https://docs.microsoft.com/en-us/windows/win32/api/winternl/nf-winternl-ntcreatefile unsafe { let mut handle = ptr::null_mut(); let mut io_status = c::IO_STATUS_BLOCK::default(); let name_str = c::UNICODE_STRING::from_ref(name); use crate::sync::atomic::{AtomicU32, Ordering}; // The `OBJ_DONT_REPARSE` attribute ensures that we haven't been // tricked into following a symlink. However, it may not be available in // earlier versions of Windows. static ATTRIBUTES: AtomicU32 = AtomicU32::new(c::OBJ_DONT_REPARSE); let object = c::OBJECT_ATTRIBUTES { ObjectName: &name_str, RootDirectory: parent.as_raw_handle(), Attributes: ATTRIBUTES.load(Ordering::Relaxed), ..c::OBJECT_ATTRIBUTES::default() }; let status = c::NtCreateFile( &mut handle, access, &object, &mut io_status, crate::ptr::null_mut(), 0, c::FILE_SHARE_DELETE | c::FILE_SHARE_READ | c::FILE_SHARE_WRITE, c::FILE_OPEN, // If `name` is a symlink then open the link rather than the target. c::FILE_OPEN_REPARSE_POINT, crate::ptr::null_mut(), 0, ); // Convert an NTSTATUS to the more familiar Win32 error codes (aka "DosError") if c::nt_success(status) { Ok(File::from_raw_handle(handle)) } else if status == c::STATUS_DELETE_PENDING { // We make a special exception for `STATUS_DELETE_PENDING` because // otherwise this will be mapped to `ERROR_ACCESS_DENIED` which is // very unhelpful. Err(io::Error::from_raw_os_error(c::ERROR_DELETE_PENDING as _)) } else if status == c::STATUS_INVALID_PARAMETER && ATTRIBUTES.load(Ordering::Relaxed) == c::OBJ_DONT_REPARSE { // Try without `OBJ_DONT_REPARSE`. See above. ATTRIBUTES.store(0, Ordering::Relaxed); open_link_no_reparse(parent, name, access) } else { Err(io::Error::from_raw_os_error(c::RtlNtStatusToDosError(status) as _)) } } } impl AsInner for File { fn as_inner(&self) -> &Handle { &self.handle } } impl IntoInner for File { fn into_inner(self) -> Handle { self.handle } } impl FromInner for File { fn from_inner(handle: Handle) -> File { File { handle } } } impl AsHandle for File { fn as_handle(&self) -> BorrowedHandle<'_> { self.as_inner().as_handle() } } impl AsRawHandle for File { fn as_raw_handle(&self) -> RawHandle { self.as_inner().as_raw_handle() } } impl IntoRawHandle for File { fn into_raw_handle(self) -> RawHandle { self.into_inner().into_raw_handle() } } impl FromRawHandle for File { unsafe fn from_raw_handle(raw_handle: RawHandle) -> Self { Self { handle: FromInner::from_inner(FromRawHandle::from_raw_handle(raw_handle)) } } } impl fmt::Debug for File { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { // FIXME(#24570): add more info here (e.g., mode) let mut b = f.debug_struct("File"); b.field("handle", &self.handle.as_raw_handle()); if let Ok(path) = get_path(&self) { b.field("path", &path); } b.finish() } } impl FileAttr { pub fn size(&self) -> u64 { self.file_size } pub fn perm(&self) -> FilePermissions { FilePermissions { attrs: self.attributes } } pub fn attrs(&self) -> u32 { self.attributes } pub fn file_type(&self) -> FileType { FileType::new(self.attributes, self.reparse_tag) } pub fn modified(&self) -> io::Result { Ok(SystemTime::from(self.last_write_time)) } pub fn accessed(&self) -> io::Result { Ok(SystemTime::from(self.last_access_time)) } pub fn created(&self) -> io::Result { Ok(SystemTime::from(self.creation_time)) } pub fn modified_u64(&self) -> u64 { to_u64(&self.last_write_time) } pub fn accessed_u64(&self) -> u64 { to_u64(&self.last_access_time) } pub fn created_u64(&self) -> u64 { to_u64(&self.creation_time) } pub fn volume_serial_number(&self) -> Option { self.volume_serial_number } pub fn number_of_links(&self) -> Option { self.number_of_links } pub fn file_index(&self) -> Option { self.file_index } } impl From for FileAttr { fn from(wfd: c::WIN32_FIND_DATAW) -> Self { FileAttr { attributes: wfd.dwFileAttributes, creation_time: wfd.ftCreationTime, last_access_time: wfd.ftLastAccessTime, last_write_time: wfd.ftLastWriteTime, file_size: ((wfd.nFileSizeHigh as u64) << 32) | (wfd.nFileSizeLow as u64), reparse_tag: if wfd.dwFileAttributes & c::FILE_ATTRIBUTE_REPARSE_POINT != 0 { // reserved unless this is a reparse point wfd.dwReserved0 } else { 0 }, volume_serial_number: None, number_of_links: None, file_index: None, } } } fn to_u64(ft: &c::FILETIME) -> u64 { (ft.dwLowDateTime as u64) | ((ft.dwHighDateTime as u64) << 32) } impl FilePermissions { pub fn readonly(&self) -> bool { self.attrs & c::FILE_ATTRIBUTE_READONLY != 0 } pub fn set_readonly(&mut self, readonly: bool) { if readonly { self.attrs |= c::FILE_ATTRIBUTE_READONLY; } else { self.attrs &= !c::FILE_ATTRIBUTE_READONLY; } } } impl FileTimes { pub fn set_accessed(&mut self, t: SystemTime) { self.accessed = Some(t.into_inner()); } pub fn set_modified(&mut self, t: SystemTime) { self.modified = Some(t.into_inner()); } } impl FileType { fn new(attrs: c::DWORD, reparse_tag: c::DWORD) -> FileType { FileType { attributes: attrs, reparse_tag } } pub fn is_dir(&self) -> bool { !self.is_symlink() && self.is_directory() } pub fn is_file(&self) -> bool { !self.is_symlink() && !self.is_directory() } pub fn is_symlink(&self) -> bool { self.is_reparse_point() && self.is_reparse_tag_name_surrogate() } pub fn is_symlink_dir(&self) -> bool { self.is_symlink() && self.is_directory() } pub fn is_symlink_file(&self) -> bool { self.is_symlink() && !self.is_directory() } fn is_directory(&self) -> bool { self.attributes & c::FILE_ATTRIBUTE_DIRECTORY != 0 } fn is_reparse_point(&self) -> bool { self.attributes & c::FILE_ATTRIBUTE_REPARSE_POINT != 0 } fn is_reparse_tag_name_surrogate(&self) -> bool { self.reparse_tag & 0x20000000 != 0 } } impl DirBuilder { pub fn new() -> DirBuilder { DirBuilder } pub fn mkdir(&self, p: &Path) -> io::Result<()> { let p = maybe_verbatim(p)?; cvt(unsafe { c::CreateDirectoryW(p.as_ptr(), ptr::null_mut()) })?; Ok(()) } } pub fn readdir(p: &Path) -> io::Result { let root = p.to_path_buf(); let star = p.join("*"); let path = maybe_verbatim(&star)?; unsafe { let mut wfd = mem::zeroed(); let find_handle = c::FindFirstFileW(path.as_ptr(), &mut wfd); if find_handle != c::INVALID_HANDLE_VALUE { Ok(ReadDir { handle: FindNextFileHandle(find_handle), root: Arc::new(root), first: Some(wfd), }) } else { Err(Error::last_os_error()) } } } pub fn unlink(p: &Path) -> io::Result<()> { let p_u16s = maybe_verbatim(p)?; cvt(unsafe { c::DeleteFileW(p_u16s.as_ptr()) })?; Ok(()) } pub fn rename(old: &Path, new: &Path) -> io::Result<()> { let old = maybe_verbatim(old)?; let new = maybe_verbatim(new)?; cvt(unsafe { c::MoveFileExW(old.as_ptr(), new.as_ptr(), c::MOVEFILE_REPLACE_EXISTING) })?; Ok(()) } pub fn rmdir(p: &Path) -> io::Result<()> { let p = maybe_verbatim(p)?; cvt(unsafe { c::RemoveDirectoryW(p.as_ptr()) })?; Ok(()) } /// Open a file or directory without following symlinks. fn open_link(path: &Path, access_mode: u32) -> io::Result { let mut opts = OpenOptions::new(); opts.access_mode(access_mode); // `FILE_FLAG_BACKUP_SEMANTICS` allows opening directories. // `FILE_FLAG_OPEN_REPARSE_POINT` opens a link instead of its target. opts.custom_flags(c::FILE_FLAG_BACKUP_SEMANTICS | c::FILE_FLAG_OPEN_REPARSE_POINT); File::open(path, &opts) } pub fn remove_dir_all(path: &Path) -> io::Result<()> { let file = open_link(path, c::DELETE | c::FILE_LIST_DIRECTORY)?; // Test if the file is not a directory or a symlink to a directory. if (file.basic_info()?.FileAttributes & c::FILE_ATTRIBUTE_DIRECTORY) == 0 { return Err(io::Error::from_raw_os_error(c::ERROR_DIRECTORY as _)); } match remove_dir_all_iterative(&file, File::posix_delete) { Err(e) => { if let Some(code) = e.raw_os_error() { match code as u32 { // If POSIX delete is not supported for this filesystem then fallback to win32 delete. c::ERROR_NOT_SUPPORTED | c::ERROR_INVALID_FUNCTION | c::ERROR_INVALID_PARAMETER => { remove_dir_all_iterative(&file, File::win32_delete) } _ => Err(e), } } else { Err(e) } } ok => ok, } } fn remove_dir_all_iterative(f: &File, delete: fn(&File) -> io::Result<()>) -> io::Result<()> { // When deleting files we may loop this many times when certain error conditions occur. // This allows remove_dir_all to succeed when the error is temporary. const MAX_RETRIES: u32 = 10; let mut buffer = DirBuff::new(); let mut dirlist = vec![f.duplicate()?]; // FIXME: This is a hack so we can push to the dirlist vec after borrowing from it. fn copy_handle(f: &File) -> mem::ManuallyDrop { unsafe { mem::ManuallyDrop::new(File::from_raw_handle(f.as_raw_handle())) } } let mut restart = true; while let Some(dir) = dirlist.last() { let dir = copy_handle(dir); // Fill the buffer and iterate the entries. let more_data = dir.fill_dir_buff(&mut buffer, restart)?; restart = false; for (name, is_directory) in buffer.iter() { if is_directory { let child_dir = open_link_no_reparse( &dir, &name, c::SYNCHRONIZE | c::DELETE | c::FILE_LIST_DIRECTORY, )?; dirlist.push(child_dir); } else { for i in 1..=MAX_RETRIES { let result = open_link_no_reparse(&dir, &name, c::SYNCHRONIZE | c::DELETE); match result { Ok(f) => delete(&f)?, // Already deleted, so skip. Err(e) if e.kind() == io::ErrorKind::NotFound => break, // Retry a few times if the file is locked or a delete is already in progress. Err(e) if i < MAX_RETRIES && (e.raw_os_error() == Some(c::ERROR_DELETE_PENDING as _) || e.raw_os_error() == Some(c::ERROR_SHARING_VIOLATION as _)) => {} // Otherwise return the error. Err(e) => return Err(e), } thread::yield_now(); } } } // If there were no more files then delete the directory. if !more_data { if let Some(dir) = dirlist.pop() { // Retry deleting a few times in case we need to wait for a file to be deleted. for i in 1..=MAX_RETRIES { let result = delete(&dir); if let Err(e) = result { if i == MAX_RETRIES || e.kind() != io::ErrorKind::DirectoryNotEmpty { return Err(e); } thread::yield_now(); } else { break; } } } } } Ok(()) } pub fn readlink(path: &Path) -> io::Result { // Open the link with no access mode, instead of generic read. // By default FILE_LIST_DIRECTORY is denied for the junction "C:\Documents and Settings", so // this is needed for a common case. let mut opts = OpenOptions::new(); opts.access_mode(0); opts.custom_flags(c::FILE_FLAG_OPEN_REPARSE_POINT | c::FILE_FLAG_BACKUP_SEMANTICS); let file = File::open(&path, &opts)?; file.readlink() } pub fn symlink(original: &Path, link: &Path) -> io::Result<()> { symlink_inner(original, link, false) } pub fn symlink_inner(original: &Path, link: &Path, dir: bool) -> io::Result<()> { let original = to_u16s(original)?; let link = maybe_verbatim(link)?; let flags = if dir { c::SYMBOLIC_LINK_FLAG_DIRECTORY } else { 0 }; // Formerly, symlink creation required the SeCreateSymbolicLink privilege. For the Windows 10 // Creators Update, Microsoft loosened this to allow unprivileged symlink creation if the // computer is in Developer Mode, but SYMBOLIC_LINK_FLAG_ALLOW_UNPRIVILEGED_CREATE must be // added to dwFlags to opt into this behaviour. let result = cvt(unsafe { c::CreateSymbolicLinkW( link.as_ptr(), original.as_ptr(), flags | c::SYMBOLIC_LINK_FLAG_ALLOW_UNPRIVILEGED_CREATE, ) as c::BOOL }); if let Err(err) = result { if err.raw_os_error() == Some(c::ERROR_INVALID_PARAMETER as i32) { // Older Windows objects to SYMBOLIC_LINK_FLAG_ALLOW_UNPRIVILEGED_CREATE, // so if we encounter ERROR_INVALID_PARAMETER, retry without that flag. cvt(unsafe { c::CreateSymbolicLinkW(link.as_ptr(), original.as_ptr(), flags) as c::BOOL })?; } else { return Err(err); } } Ok(()) } #[cfg(not(target_vendor = "uwp"))] pub fn link(original: &Path, link: &Path) -> io::Result<()> { let original = maybe_verbatim(original)?; let link = maybe_verbatim(link)?; cvt(unsafe { c::CreateHardLinkW(link.as_ptr(), original.as_ptr(), ptr::null_mut()) })?; Ok(()) } #[cfg(target_vendor = "uwp")] pub fn link(_original: &Path, _link: &Path) -> io::Result<()> { return Err(io::const_io_error!( io::ErrorKind::Unsupported, "hard link are not supported on UWP", )); } pub fn stat(path: &Path) -> io::Result { metadata(path, ReparsePoint::Follow) } pub fn lstat(path: &Path) -> io::Result { metadata(path, ReparsePoint::Open) } #[repr(u32)] #[derive(Clone, Copy, PartialEq, Eq)] enum ReparsePoint { Follow = 0, Open = c::FILE_FLAG_OPEN_REPARSE_POINT, } impl ReparsePoint { fn as_flag(self) -> u32 { self as u32 } } fn metadata(path: &Path, reparse: ReparsePoint) -> io::Result { let mut opts = OpenOptions::new(); // No read or write permissions are necessary opts.access_mode(0); opts.custom_flags(c::FILE_FLAG_BACKUP_SEMANTICS | reparse.as_flag()); // Attempt to open the file normally. // If that fails with `ERROR_SHARING_VIOLATION` then retry using `FindFirstFileW`. // If the fallback fails for any reason we return the original error. match File::open(path, &opts) { Ok(file) => file.file_attr(), Err(e) if e.raw_os_error() == Some(c::ERROR_SHARING_VIOLATION as _) => { // `ERROR_SHARING_VIOLATION` will almost never be returned. // Usually if a file is locked you can still read some metadata. // However, there are special system files, such as // `C:\hiberfil.sys`, that are locked in a way that denies even that. unsafe { let path = maybe_verbatim(path)?; // `FindFirstFileW` accepts wildcard file names. // Fortunately wildcards are not valid file names and // `ERROR_SHARING_VIOLATION` means the file exists (but is locked) // therefore it's safe to assume the file name given does not // include wildcards. let mut wfd = mem::zeroed(); let handle = c::FindFirstFileW(path.as_ptr(), &mut wfd); if handle == c::INVALID_HANDLE_VALUE { // This can fail if the user does not have read access to the // directory. Err(e) } else { // We no longer need the find handle. c::FindClose(handle); // `FindFirstFileW` reads the cached file information from the // directory. The downside is that this metadata may be outdated. let attrs = FileAttr::from(wfd); if reparse == ReparsePoint::Follow && attrs.file_type().is_symlink() { Err(e) } else { Ok(attrs) } } } } Err(e) => Err(e), } } pub fn set_perm(p: &Path, perm: FilePermissions) -> io::Result<()> { let p = maybe_verbatim(p)?; unsafe { cvt(c::SetFileAttributesW(p.as_ptr(), perm.attrs))?; Ok(()) } } fn get_path(f: &File) -> io::Result { super::fill_utf16_buf( |buf, sz| unsafe { c::GetFinalPathNameByHandleW(f.handle.as_raw_handle(), buf, sz, c::VOLUME_NAME_DOS) }, |buf| PathBuf::from(OsString::from_wide(buf)), ) } pub fn canonicalize(p: &Path) -> io::Result { let mut opts = OpenOptions::new(); // No read or write permissions are necessary opts.access_mode(0); // This flag is so we can open directories too opts.custom_flags(c::FILE_FLAG_BACKUP_SEMANTICS); let f = File::open(p, &opts)?; get_path(&f) } pub fn copy(from: &Path, to: &Path) -> io::Result { unsafe extern "system" fn callback( _TotalFileSize: c::LARGE_INTEGER, _TotalBytesTransferred: c::LARGE_INTEGER, _StreamSize: c::LARGE_INTEGER, StreamBytesTransferred: c::LARGE_INTEGER, dwStreamNumber: c::DWORD, _dwCallbackReason: c::DWORD, _hSourceFile: c::HANDLE, _hDestinationFile: c::HANDLE, lpData: c::LPVOID, ) -> c::DWORD { if dwStreamNumber == 1 { *(lpData as *mut i64) = StreamBytesTransferred; } c::PROGRESS_CONTINUE } let pfrom = maybe_verbatim(from)?; let pto = maybe_verbatim(to)?; let mut size = 0i64; cvt(unsafe { c::CopyFileExW( pfrom.as_ptr(), pto.as_ptr(), Some(callback), &mut size as *mut _ as *mut _, ptr::null_mut(), 0, ) })?; Ok(size as u64) } #[allow(dead_code)] pub fn symlink_junction, Q: AsRef>( original: P, junction: Q, ) -> io::Result<()> { symlink_junction_inner(original.as_ref(), junction.as_ref()) } // Creating a directory junction on windows involves dealing with reparse // points and the DeviceIoControl function, and this code is a skeleton of // what can be found here: // // http://www.flexhex.com/docs/articles/hard-links.phtml #[allow(dead_code)] fn symlink_junction_inner(original: &Path, junction: &Path) -> io::Result<()> { let d = DirBuilder::new(); d.mkdir(&junction)?; let mut opts = OpenOptions::new(); opts.write(true); opts.custom_flags(c::FILE_FLAG_OPEN_REPARSE_POINT | c::FILE_FLAG_BACKUP_SEMANTICS); let f = File::open(junction, &opts)?; let h = f.as_inner().as_raw_handle(); unsafe { let mut data = Align8([MaybeUninit::::uninit(); c::MAXIMUM_REPARSE_DATA_BUFFER_SIZE]); let data_ptr = data.0.as_mut_ptr(); let db = data_ptr.cast::(); let buf = ptr::addr_of_mut!((*db).ReparseTarget).cast::(); let mut i = 0; // FIXME: this conversion is very hacky let v = br"\??\"; let v = v.iter().map(|x| *x as u16); for c in v.chain(original.as_os_str().encode_wide()) { *buf.add(i) = c; i += 1; } *buf.add(i) = 0; i += 1; (*db).ReparseTag = c::IO_REPARSE_TAG_MOUNT_POINT; (*db).ReparseTargetMaximumLength = (i * 2) as c::WORD; (*db).ReparseTargetLength = ((i - 1) * 2) as c::WORD; (*db).ReparseDataLength = (*db).ReparseTargetLength as c::DWORD + 12; let mut ret = 0; cvt(c::DeviceIoControl( h as *mut _, c::FSCTL_SET_REPARSE_POINT, data_ptr.cast(), (*db).ReparseDataLength + 8, ptr::null_mut(), 0, &mut ret, ptr::null_mut(), )) .map(drop) } } // Try to see if a file exists but, unlike `exists`, report I/O errors. pub fn try_exists(path: &Path) -> io::Result { // Open the file to ensure any symlinks are followed to their target. let mut opts = OpenOptions::new(); // No read, write, etc access rights are needed. opts.access_mode(0); // Backup semantics enables opening directories as well as files. opts.custom_flags(c::FILE_FLAG_BACKUP_SEMANTICS); match File::open(path, &opts) { Err(e) => match e.kind() { // The file definitely does not exist io::ErrorKind::NotFound => Ok(false), // `ERROR_SHARING_VIOLATION` means that the file has been locked by // another process. This is often temporary so we simply report it // as the file existing. _ if e.raw_os_error() == Some(c::ERROR_SHARING_VIOLATION as i32) => Ok(true), // Other errors such as `ERROR_ACCESS_DENIED` may indicate that the // file exists. However, these types of errors are usually more // permanent so we report them here. _ => Err(e), }, // The file was opened successfully therefore it must exist, Ok(_) => Ok(true), } }