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denoland-deno/ext/fs/std_fs.rs

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// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
#![allow(clippy::disallowed_methods)]
use std::borrow::Cow;
use std::env::current_dir;
use std::fs;
use std::io;
use std::io::Read;
use std::io::Write;
use std::path::Path;
use std::path::PathBuf;
use std::rc::Rc;
use deno_core::unsync::spawn_blocking;
use deno_io::fs::File;
use deno_io::fs::FsError;
use deno_io::fs::FsResult;
use deno_io::fs::FsStat;
use deno_io::StdFileResourceInner;
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use deno_path_util::normalize_path;
use crate::interface::AccessCheckCb;
use crate::interface::FsDirEntry;
use crate::interface::FsFileType;
use crate::FileSystem;
use crate::OpenOptions;
#[derive(Debug, Clone)]
pub struct RealFs;
#[async_trait::async_trait(?Send)]
impl FileSystem for RealFs {
fn cwd(&self) -> FsResult<PathBuf> {
std::env::current_dir().map_err(Into::into)
}
fn tmp_dir(&self) -> FsResult<PathBuf> {
Ok(std::env::temp_dir())
}
fn chdir(&self, path: &Path) -> FsResult<()> {
std::env::set_current_dir(path).map_err(Into::into)
}
#[cfg(not(unix))]
fn umask(&self, _mask: Option<u32>) -> FsResult<u32> {
// TODO implement umask for Windows
// see https://github.com/nodejs/node/blob/master/src/node_process_methods.cc
// and https://docs.microsoft.com/fr-fr/cpp/c-runtime-library/reference/umask?view=vs-2019
Err(FsError::NotSupported)
}
#[cfg(unix)]
fn umask(&self, mask: Option<u32>) -> FsResult<u32> {
use nix::sys::stat::mode_t;
use nix::sys::stat::umask;
use nix::sys::stat::Mode;
let r = if let Some(mask) = mask {
// If mask provided, return previous.
umask(Mode::from_bits_truncate(mask as mode_t))
} else {
// If no mask provided, we query the current. Requires two syscalls.
let prev = umask(Mode::from_bits_truncate(0o777));
let _ = umask(prev);
prev
};
#[cfg(any(target_os = "android", target_os = "linux"))]
{
Ok(r.bits())
}
#[cfg(any(
target_os = "macos",
target_os = "openbsd",
target_os = "freebsd"
))]
{
Ok(r.bits() as u32)
}
}
fn open_sync(
&self,
path: &Path,
options: OpenOptions,
access_check: Option<AccessCheckCb>,
) -> FsResult<Rc<dyn File>> {
let std_file = open_with_access_check(options, path, access_check)?;
Ok(Rc::new(StdFileResourceInner::file(std_file)))
}
async fn open_async<'a>(
&'a self,
path: PathBuf,
options: OpenOptions,
access_check: Option<AccessCheckCb<'a>>,
) -> FsResult<Rc<dyn File>> {
let std_file = open_with_access_check(options, &path, access_check)?;
Ok(Rc::new(StdFileResourceInner::file(std_file)))
}
fn mkdir_sync(
&self,
path: &Path,
recursive: bool,
mode: Option<u32>,
) -> FsResult<()> {
mkdir(path, recursive, mode)
}
async fn mkdir_async(
&self,
path: PathBuf,
recursive: bool,
mode: Option<u32>,
) -> FsResult<()> {
spawn_blocking(move || mkdir(&path, recursive, mode)).await?
}
fn chmod_sync(&self, path: &Path, mode: u32) -> FsResult<()> {
chmod(path, mode)
}
async fn chmod_async(&self, path: PathBuf, mode: u32) -> FsResult<()> {
spawn_blocking(move || chmod(&path, mode)).await?
}
fn chown_sync(
&self,
path: &Path,
uid: Option<u32>,
gid: Option<u32>,
) -> FsResult<()> {
chown(path, uid, gid)
}
async fn chown_async(
&self,
path: PathBuf,
uid: Option<u32>,
gid: Option<u32>,
) -> FsResult<()> {
spawn_blocking(move || chown(&path, uid, gid)).await?
}
fn remove_sync(&self, path: &Path, recursive: bool) -> FsResult<()> {
remove(path, recursive)
}
async fn remove_async(&self, path: PathBuf, recursive: bool) -> FsResult<()> {
spawn_blocking(move || remove(&path, recursive)).await?
}
fn copy_file_sync(&self, from: &Path, to: &Path) -> FsResult<()> {
copy_file(from, to)
}
async fn copy_file_async(&self, from: PathBuf, to: PathBuf) -> FsResult<()> {
spawn_blocking(move || copy_file(&from, &to)).await?
}
fn cp_sync(&self, fro: &Path, to: &Path) -> FsResult<()> {
cp(fro, to)
}
async fn cp_async(&self, fro: PathBuf, to: PathBuf) -> FsResult<()> {
spawn_blocking(move || cp(&fro, &to)).await?
}
fn stat_sync(&self, path: &Path) -> FsResult<FsStat> {
stat(path).map(Into::into)
}
async fn stat_async(&self, path: PathBuf) -> FsResult<FsStat> {
spawn_blocking(move || stat(&path)).await?.map(Into::into)
}
fn lstat_sync(&self, path: &Path) -> FsResult<FsStat> {
lstat(path).map(Into::into)
}
async fn lstat_async(&self, path: PathBuf) -> FsResult<FsStat> {
spawn_blocking(move || lstat(&path)).await?.map(Into::into)
}
fn exists_sync(&self, path: &Path) -> bool {
exists(path)
}
async fn exists_async(&self, path: PathBuf) -> FsResult<bool> {
spawn_blocking(move || exists(&path))
.await
.map_err(Into::into)
}
fn realpath_sync(&self, path: &Path) -> FsResult<PathBuf> {
realpath(path)
}
async fn realpath_async(&self, path: PathBuf) -> FsResult<PathBuf> {
spawn_blocking(move || realpath(&path)).await?
}
fn read_dir_sync(&self, path: &Path) -> FsResult<Vec<FsDirEntry>> {
read_dir(path)
}
async fn read_dir_async(&self, path: PathBuf) -> FsResult<Vec<FsDirEntry>> {
spawn_blocking(move || read_dir(&path)).await?
}
fn rename_sync(&self, oldpath: &Path, newpath: &Path) -> FsResult<()> {
fs::rename(oldpath, newpath).map_err(Into::into)
}
async fn rename_async(
&self,
oldpath: PathBuf,
newpath: PathBuf,
) -> FsResult<()> {
spawn_blocking(move || fs::rename(oldpath, newpath))
.await?
.map_err(Into::into)
}
fn link_sync(&self, oldpath: &Path, newpath: &Path) -> FsResult<()> {
fs::hard_link(oldpath, newpath).map_err(Into::into)
}
async fn link_async(
&self,
oldpath: PathBuf,
newpath: PathBuf,
) -> FsResult<()> {
spawn_blocking(move || fs::hard_link(oldpath, newpath))
.await?
.map_err(Into::into)
}
fn symlink_sync(
&self,
oldpath: &Path,
newpath: &Path,
file_type: Option<FsFileType>,
) -> FsResult<()> {
symlink(oldpath, newpath, file_type)
}
async fn symlink_async(
&self,
oldpath: PathBuf,
newpath: PathBuf,
file_type: Option<FsFileType>,
) -> FsResult<()> {
spawn_blocking(move || symlink(&oldpath, &newpath, file_type)).await?
}
fn read_link_sync(&self, path: &Path) -> FsResult<PathBuf> {
fs::read_link(path).map_err(Into::into)
}
async fn read_link_async(&self, path: PathBuf) -> FsResult<PathBuf> {
spawn_blocking(move || fs::read_link(path))
.await?
.map_err(Into::into)
}
fn truncate_sync(&self, path: &Path, len: u64) -> FsResult<()> {
truncate(path, len)
}
async fn truncate_async(&self, path: PathBuf, len: u64) -> FsResult<()> {
spawn_blocking(move || truncate(&path, len)).await?
}
fn utime_sync(
&self,
path: &Path,
atime_secs: i64,
atime_nanos: u32,
mtime_secs: i64,
mtime_nanos: u32,
) -> FsResult<()> {
let atime = filetime::FileTime::from_unix_time(atime_secs, atime_nanos);
let mtime = filetime::FileTime::from_unix_time(mtime_secs, mtime_nanos);
filetime::set_file_times(path, atime, mtime).map_err(Into::into)
}
async fn utime_async(
&self,
path: PathBuf,
atime_secs: i64,
atime_nanos: u32,
mtime_secs: i64,
mtime_nanos: u32,
) -> FsResult<()> {
let atime = filetime::FileTime::from_unix_time(atime_secs, atime_nanos);
let mtime = filetime::FileTime::from_unix_time(mtime_secs, mtime_nanos);
spawn_blocking(move || {
filetime::set_file_times(path, atime, mtime).map_err(Into::into)
})
.await?
}
fn lutime_sync(
&self,
path: &Path,
atime_secs: i64,
atime_nanos: u32,
mtime_secs: i64,
mtime_nanos: u32,
) -> FsResult<()> {
let atime = filetime::FileTime::from_unix_time(atime_secs, atime_nanos);
let mtime = filetime::FileTime::from_unix_time(mtime_secs, mtime_nanos);
filetime::set_symlink_file_times(path, atime, mtime).map_err(Into::into)
}
async fn lutime_async(
&self,
path: PathBuf,
atime_secs: i64,
atime_nanos: u32,
mtime_secs: i64,
mtime_nanos: u32,
) -> FsResult<()> {
let atime = filetime::FileTime::from_unix_time(atime_secs, atime_nanos);
let mtime = filetime::FileTime::from_unix_time(mtime_secs, mtime_nanos);
spawn_blocking(move || {
filetime::set_symlink_file_times(path, atime, mtime).map_err(Into::into)
})
.await?
}
fn lchown_sync(
&self,
path: &Path,
uid: Option<u32>,
gid: Option<u32>,
) -> FsResult<()> {
lchown(path, uid, gid)
}
async fn lchown_async(
&self,
path: PathBuf,
uid: Option<u32>,
gid: Option<u32>,
) -> FsResult<()> {
spawn_blocking(move || lchown(&path, uid, gid)).await?
}
fn write_file_sync(
&self,
path: &Path,
options: OpenOptions,
access_check: Option<AccessCheckCb>,
data: &[u8],
) -> FsResult<()> {
let mut file = open_with_access_check(options, path, access_check)?;
#[cfg(unix)]
if let Some(mode) = options.mode {
use std::os::unix::fs::PermissionsExt;
file.set_permissions(fs::Permissions::from_mode(mode))?;
}
file.write_all(data)?;
Ok(())
}
async fn write_file_async<'a>(
&'a self,
path: PathBuf,
options: OpenOptions,
access_check: Option<AccessCheckCb<'a>>,
data: Vec<u8>,
) -> FsResult<()> {
let mut file = open_with_access_check(options, &path, access_check)?;
spawn_blocking(move || {
#[cfg(unix)]
if let Some(mode) = options.mode {
use std::os::unix::fs::PermissionsExt;
file.set_permissions(fs::Permissions::from_mode(mode))?;
}
file.write_all(&data)?;
Ok(())
})
.await?
}
fn read_file_sync(
&self,
path: &Path,
access_check: Option<AccessCheckCb>,
) -> FsResult<Cow<'static, [u8]>> {
let mut file = open_with_access_check(
OpenOptions {
read: true,
..Default::default()
},
path,
access_check,
)?;
let mut buf = Vec::new();
file.read_to_end(&mut buf)?;
Ok(Cow::Owned(buf))
}
async fn read_file_async<'a>(
&'a self,
path: PathBuf,
access_check: Option<AccessCheckCb<'a>>,
) -> FsResult<Cow<'static, [u8]>> {
let mut file = open_with_access_check(
OpenOptions {
read: true,
..Default::default()
},
&path,
access_check,
)?;
spawn_blocking(move || {
let mut buf = Vec::new();
file.read_to_end(&mut buf)?;
Ok::<_, FsError>(Cow::Owned(buf))
})
.await?
.map_err(Into::into)
}
}
fn mkdir(path: &Path, recursive: bool, mode: Option<u32>) -> FsResult<()> {
let mut builder = fs::DirBuilder::new();
builder.recursive(recursive);
#[cfg(unix)]
if let Some(mode) = mode {
use std::os::unix::fs::DirBuilderExt;
builder.mode(mode);
}
#[cfg(not(unix))]
{
_ = mode;
}
builder.create(path).map_err(Into::into)
}
#[cfg(unix)]
fn chmod(path: &Path, mode: u32) -> FsResult<()> {
use std::os::unix::fs::PermissionsExt;
let permissions = fs::Permissions::from_mode(mode);
fs::set_permissions(path, permissions)?;
Ok(())
}
// TODO: implement chmod for Windows (#4357)
#[cfg(not(unix))]
fn chmod(path: &Path, _mode: u32) -> FsResult<()> {
// Still check file/dir exists on Windows
std::fs::metadata(path)?;
Err(FsError::NotSupported)
}
#[cfg(unix)]
fn chown(path: &Path, uid: Option<u32>, gid: Option<u32>) -> FsResult<()> {
use nix::unistd::chown;
use nix::unistd::Gid;
use nix::unistd::Uid;
let owner = uid.map(Uid::from_raw);
let group = gid.map(Gid::from_raw);
let res = chown(path, owner, group);
if let Err(err) = res {
return Err(io::Error::from_raw_os_error(err as i32).into());
}
Ok(())
}
// TODO: implement chown for Windows
#[cfg(not(unix))]
fn chown(_path: &Path, _uid: Option<u32>, _gid: Option<u32>) -> FsResult<()> {
Err(FsError::NotSupported)
}
#[cfg(unix)]
fn lchown(path: &Path, uid: Option<u32>, gid: Option<u32>) -> FsResult<()> {
use std::os::unix::ffi::OsStrExt;
let c_path = std::ffi::CString::new(path.as_os_str().as_bytes()).unwrap();
// -1 = leave unchanged
let uid = uid
.map(|uid| uid as libc::uid_t)
.unwrap_or(-1i32 as libc::uid_t);
let gid = gid
.map(|gid| gid as libc::gid_t)
.unwrap_or(-1i32 as libc::gid_t);
// SAFETY: `c_path` is a valid C string and lives throughout this function call.
let result = unsafe { libc::lchown(c_path.as_ptr(), uid, gid) };
if result != 0 {
return Err(io::Error::last_os_error().into());
}
Ok(())
}
// TODO: implement lchown for Windows
#[cfg(not(unix))]
fn lchown(_path: &Path, _uid: Option<u32>, _gid: Option<u32>) -> FsResult<()> {
Err(FsError::NotSupported)
}
fn remove(path: &Path, recursive: bool) -> FsResult<()> {
// TODO: this is racy. This should open fds, and then `unlink` those.
let metadata = fs::symlink_metadata(path)?;
let file_type = metadata.file_type();
let res = if file_type.is_dir() {
if recursive {
fs::remove_dir_all(path)
} else {
fs::remove_dir(path)
}
} else if file_type.is_symlink() {
#[cfg(unix)]
{
fs::remove_file(path)
}
#[cfg(not(unix))]
{
use std::os::windows::prelude::MetadataExt;
use winapi::um::winnt::FILE_ATTRIBUTE_DIRECTORY;
if metadata.file_attributes() & FILE_ATTRIBUTE_DIRECTORY != 0 {
fs::remove_dir(path)
} else {
fs::remove_file(path)
}
}
} else {
fs::remove_file(path)
};
res.map_err(Into::into)
}
fn copy_file(from: &Path, to: &Path) -> FsResult<()> {
#[cfg(target_os = "macos")]
{
use libc::clonefile;
use libc::stat;
use libc::unlink;
use std::ffi::CString;
use std::os::unix::fs::OpenOptionsExt;
use std::os::unix::fs::PermissionsExt;
let from_str = CString::new(from.as_os_str().as_encoded_bytes())
.map_err(|err| io::Error::new(io::ErrorKind::InvalidInput, err))?;
let to_str = CString::new(to.as_os_str().as_encoded_bytes())
.map_err(|err| io::Error::new(io::ErrorKind::InvalidInput, err))?;
// SAFETY: `from` and `to` are valid C strings.
// std::fs::copy does open() + fcopyfile() on macOS. We try to use
// clonefile() instead, which is more efficient.
unsafe {
let mut st = std::mem::zeroed();
let ret = stat(from_str.as_ptr(), &mut st);
if ret != 0 {
return Err(io::Error::last_os_error().into());
}
if st.st_size > 128 * 1024 {
// Try unlink. If it fails, we are going to try clonefile() anyway.
let _ = unlink(to_str.as_ptr());
// Matches rust stdlib behavior for io::copy.
// https://github.com/rust-lang/rust/blob/3fdd578d72a24d4efc2fe2ad18eec3b6ba72271e/library/std/src/sys/unix/fs.rs#L1613-L1616
if clonefile(from_str.as_ptr(), to_str.as_ptr(), 0) == 0 {
return Ok(());
}
} else {
// Do a regular copy. fcopyfile() is an overkill for < 128KB
// files.
let mut buf = [0u8; 128 * 1024];
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let mut from_file = fs::File::open(from)?;
let perm = from_file.metadata()?.permissions();
let mut to_file = fs::OpenOptions::new()
// create the file with the correct mode right away
.mode(perm.mode())
.write(true)
.create(true)
.truncate(true)
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.open(to)?;
let writer_metadata = to_file.metadata()?;
if writer_metadata.is_file() {
// Set the correct file permissions, in case the file already existed.
// Don't set the permissions on already existing non-files like
// pipes/FIFOs or device nodes.
to_file.set_permissions(perm)?;
}
loop {
let nread = from_file.read(&mut buf)?;
if nread == 0 {
break;
}
to_file.write_all(&buf[..nread])?;
}
return Ok(());
}
}
// clonefile() failed, fall back to std::fs::copy().
}
fs::copy(from, to)?;
Ok(())
}
fn cp(from: &Path, to: &Path) -> FsResult<()> {
fn cp_(source_meta: fs::Metadata, from: &Path, to: &Path) -> FsResult<()> {
use rayon::prelude::IntoParallelIterator;
use rayon::prelude::ParallelIterator;
let ty = source_meta.file_type();
if ty.is_dir() {
#[allow(unused_mut)]
let mut builder = fs::DirBuilder::new();
#[cfg(unix)]
{
use std::os::unix::fs::DirBuilderExt;
use std::os::unix::fs::PermissionsExt;
builder.mode(fs::symlink_metadata(from)?.permissions().mode());
}
builder.create(to)?;
let mut entries: Vec<_> = fs::read_dir(from)?
.map(|res| res.map(|e| e.file_name()))
.collect::<Result<_, _>>()?;
entries.shrink_to_fit();
entries
.into_par_iter()
.map(|file_name| {
cp_(
fs::symlink_metadata(from.join(&file_name)).unwrap(),
&from.join(&file_name),
&to.join(&file_name),
)
.map_err(|err| {
io::Error::new(
err.kind(),
format!(
"failed to copy '{}' to '{}': {:?}",
from.join(&file_name).display(),
to.join(&file_name).display(),
err
),
)
})
})
.collect::<Result<Vec<_>, _>>()?;
return Ok(());
} else if ty.is_symlink() {
let from = std::fs::read_link(from)?;
#[cfg(unix)]
std::os::unix::fs::symlink(from, to)?;
#[cfg(windows)]
std::os::windows::fs::symlink_file(from, to)?;
return Ok(());
}
#[cfg(unix)]
{
use std::os::unix::fs::FileTypeExt;
if ty.is_socket() {
return Err(
io::Error::new(
io::ErrorKind::InvalidInput,
"sockets cannot be copied",
)
.into(),
);
}
}
// Ensure parent destination directory exists
if let Some(parent) = to.parent() {
fs::create_dir_all(parent)?;
}
copy_file(from, to)
}
#[cfg(target_os = "macos")]
{
// Just clonefile()
use libc::clonefile;
use libc::unlink;
use std::ffi::CString;
use std::os::unix::ffi::OsStrExt;
let from_str = CString::new(from.as_os_str().as_bytes())
.map_err(|err| io::Error::new(io::ErrorKind::InvalidInput, err))?;
let to_str = CString::new(to.as_os_str().as_bytes())
.map_err(|err| io::Error::new(io::ErrorKind::InvalidInput, err))?;
// SAFETY: `from` and `to` are valid C strings.
unsafe {
// Try unlink. If it fails, we are going to try clonefile() anyway.
let _ = unlink(to_str.as_ptr());
if clonefile(from_str.as_ptr(), to_str.as_ptr(), 0) == 0 {
return Ok(());
}
}
}
let source_meta = fs::symlink_metadata(from)?;
#[inline]
fn is_identical(
source_meta: &fs::Metadata,
dest_meta: &fs::Metadata,
) -> bool {
#[cfg(unix)]
{
use std::os::unix::fs::MetadataExt;
source_meta.ino() == dest_meta.ino()
}
#[cfg(windows)]
{
use std::os::windows::fs::MetadataExt;
// https://learn.microsoft.com/en-us/windows/win32/api/fileapi/ns-fileapi-by_handle_file_information
//
// The identifier (low and high parts) and the volume serial number uniquely identify a file on a single computer.
// To determine whether two open handles represent the same file, combine the identifier and the volume serial
// number for each file and compare them.
//
// Use this code once file_index() and volume_serial_number() is stabalized
// See: https://github.com/rust-lang/rust/issues/63010
//
// source_meta.file_index() == dest_meta.file_index()
// && source_meta.volume_serial_number()
// == dest_meta.volume_serial_number()
source_meta.last_write_time() == dest_meta.last_write_time()
&& source_meta.creation_time() == dest_meta.creation_time()
}
}
match (fs::metadata(to), fs::symlink_metadata(to)) {
(Ok(m), _) if m.is_dir() => cp_(
source_meta,
from,
&to.join(from.file_name().ok_or_else(|| {
io::Error::new(
io::ErrorKind::InvalidInput,
"the source path is not a valid file",
)
})?),
)?,
(_, Ok(m)) if is_identical(&source_meta, &m) => {
return Err(
io::Error::new(
io::ErrorKind::InvalidInput,
"the source and destination are the same file",
)
.into(),
)
}
_ => cp_(source_meta, from, to)?,
}
Ok(())
}
#[cfg(not(windows))]
fn stat(path: &Path) -> FsResult<FsStat> {
let metadata = fs::metadata(path)?;
Ok(FsStat::from_std(metadata))
}
#[cfg(windows)]
fn stat(path: &Path) -> FsResult<FsStat> {
let metadata = fs::metadata(path)?;
let mut fsstat = FsStat::from_std(metadata);
use winapi::um::winbase::FILE_FLAG_BACKUP_SEMANTICS;
let path = path.canonicalize()?;
stat_extra(&mut fsstat, &path, FILE_FLAG_BACKUP_SEMANTICS)?;
Ok(fsstat)
}
#[cfg(not(windows))]
fn lstat(path: &Path) -> FsResult<FsStat> {
let metadata = fs::symlink_metadata(path)?;
Ok(FsStat::from_std(metadata))
}
#[cfg(windows)]
fn lstat(path: &Path) -> FsResult<FsStat> {
use winapi::um::winbase::FILE_FLAG_BACKUP_SEMANTICS;
use winapi::um::winbase::FILE_FLAG_OPEN_REPARSE_POINT;
let metadata = fs::symlink_metadata(path)?;
let mut fsstat = FsStat::from_std(metadata);
stat_extra(
&mut fsstat,
path,
FILE_FLAG_BACKUP_SEMANTICS | FILE_FLAG_OPEN_REPARSE_POINT,
)?;
Ok(fsstat)
}
#[cfg(windows)]
fn stat_extra(
fsstat: &mut FsStat,
path: &Path,
file_flags: winapi::shared::minwindef::DWORD,
) -> FsResult<()> {
use std::os::windows::prelude::OsStrExt;
use winapi::um::fileapi::CreateFileW;
use winapi::um::fileapi::OPEN_EXISTING;
use winapi::um::handleapi::CloseHandle;
use winapi::um::handleapi::INVALID_HANDLE_VALUE;
use winapi::um::winnt::FILE_SHARE_DELETE;
use winapi::um::winnt::FILE_SHARE_READ;
use winapi::um::winnt::FILE_SHARE_WRITE;
unsafe fn get_dev(
handle: winapi::shared::ntdef::HANDLE,
) -> std::io::Result<u64> {
use winapi::shared::minwindef::FALSE;
use winapi::um::fileapi::GetFileInformationByHandle;
use winapi::um::fileapi::BY_HANDLE_FILE_INFORMATION;
let info = {
let mut info =
std::mem::MaybeUninit::<BY_HANDLE_FILE_INFORMATION>::zeroed();
if GetFileInformationByHandle(handle, info.as_mut_ptr()) == FALSE {
return Err(std::io::Error::last_os_error());
}
info.assume_init()
};
Ok(info.dwVolumeSerialNumber as u64)
}
const WINDOWS_TICK: i64 = 10_000; // 100-nanosecond intervals in a millisecond
const SEC_TO_UNIX_EPOCH: i64 = 11_644_473_600; // Seconds between Windows epoch and Unix epoch
fn windows_time_to_unix_time_msec(windows_time: &i64) -> i64 {
let milliseconds_since_windows_epoch = windows_time / WINDOWS_TICK;
milliseconds_since_windows_epoch - SEC_TO_UNIX_EPOCH * 1000
}
use windows_sys::Wdk::Storage::FileSystem::FILE_ALL_INFORMATION;
use windows_sys::Win32::Foundation::NTSTATUS;
unsafe fn query_file_information(
handle: winapi::shared::ntdef::HANDLE,
) -> Result<FILE_ALL_INFORMATION, NTSTATUS> {
use windows_sys::Wdk::Storage::FileSystem::NtQueryInformationFile;
use windows_sys::Win32::Foundation::RtlNtStatusToDosError;
use windows_sys::Win32::Foundation::ERROR_MORE_DATA;
use windows_sys::Win32::System::IO::IO_STATUS_BLOCK;
let mut info = std::mem::MaybeUninit::<FILE_ALL_INFORMATION>::zeroed();
let mut io_status_block =
std::mem::MaybeUninit::<IO_STATUS_BLOCK>::zeroed();
let status = NtQueryInformationFile(
handle as _,
io_status_block.as_mut_ptr(),
info.as_mut_ptr() as *mut _,
std::mem::size_of::<FILE_ALL_INFORMATION>() as _,
18, /* FileAllInformation */
);
if status < 0 {
let converted_status = RtlNtStatusToDosError(status);
// If error more data is returned, then it means that the buffer is too small to get full filename information
// to have that we should retry. However, since we only use BasicInformation and StandardInformation, it is fine to ignore it
// since struct is populated with other data anyway.
// https://learn.microsoft.com/en-us/windows-hardware/drivers/ddi/ntifs/nf-ntifs-ntqueryinformationfile#remarksdd
if converted_status != ERROR_MORE_DATA {
return Err(converted_status as NTSTATUS);
}
}
Ok(info.assume_init())
}
// SAFETY: winapi calls
unsafe {
let mut path: Vec<_> = path.as_os_str().encode_wide().collect();
path.push(0);
let file_handle = CreateFileW(
path.as_ptr(),
0,
FILE_SHARE_READ | FILE_SHARE_DELETE | FILE_SHARE_WRITE,
std::ptr::null_mut(),
OPEN_EXISTING,
file_flags,
std::ptr::null_mut(),
);
if file_handle == INVALID_HANDLE_VALUE {
return Err(std::io::Error::last_os_error().into());
}
let result = get_dev(file_handle);
fsstat.dev = result?;
if let Ok(file_info) = query_file_information(file_handle) {
fsstat.ctime = Some(windows_time_to_unix_time_msec(
&file_info.BasicInformation.ChangeTime,
) as u64);
if file_info.BasicInformation.FileAttributes
& winapi::um::winnt::FILE_ATTRIBUTE_REPARSE_POINT
!= 0
{
fsstat.is_symlink = true;
}
if file_info.BasicInformation.FileAttributes
& winapi::um::winnt::FILE_ATTRIBUTE_DIRECTORY
!= 0
{
fsstat.mode |= libc::S_IFDIR as u32;
fsstat.size = 0;
} else {
fsstat.mode |= libc::S_IFREG as u32;
fsstat.size = file_info.StandardInformation.EndOfFile as u64;
}
if file_info.BasicInformation.FileAttributes
& winapi::um::winnt::FILE_ATTRIBUTE_READONLY
!= 0
{
fsstat.mode |=
(libc::S_IREAD | (libc::S_IREAD >> 3) | (libc::S_IREAD >> 6)) as u32;
} else {
fsstat.mode |= ((libc::S_IREAD | libc::S_IWRITE)
| ((libc::S_IREAD | libc::S_IWRITE) >> 3)
| ((libc::S_IREAD | libc::S_IWRITE) >> 6))
as u32;
}
}
CloseHandle(file_handle);
Ok(())
}
}
fn exists(path: &Path) -> bool {
#[cfg(unix)]
{
use nix::unistd::access;
use nix::unistd::AccessFlags;
access(path, AccessFlags::F_OK).is_ok()
}
#[cfg(windows)]
{
use std::os::windows::ffi::OsStrExt;
use winapi::um::fileapi::GetFileAttributesW;
use winapi::um::fileapi::INVALID_FILE_ATTRIBUTES;
let path = path
.as_os_str()
.encode_wide()
.chain(std::iter::once(0))
.collect::<Vec<_>>();
// Safety: `path` is a null-terminated string
let attrs = unsafe { GetFileAttributesW(path.as_ptr()) };
attrs != INVALID_FILE_ATTRIBUTES
}
}
fn realpath(path: &Path) -> FsResult<PathBuf> {
Ok(deno_path_util::strip_unc_prefix(path.canonicalize()?))
}
fn read_dir(path: &Path) -> FsResult<Vec<FsDirEntry>> {
let entries = fs::read_dir(path)?
.filter_map(|entry| {
let entry = entry.ok()?;
let name = entry.file_name().into_string().ok()?;
let metadata = entry.file_type();
macro_rules! method_or_false {
($method:ident) => {
if let Ok(metadata) = &metadata {
metadata.$method()
} else {
false
}
};
}
Some(FsDirEntry {
name,
is_file: method_or_false!(is_file),
is_directory: method_or_false!(is_dir),
is_symlink: method_or_false!(is_symlink),
})
})
.collect();
Ok(entries)
}
#[cfg(not(windows))]
fn symlink(
oldpath: &Path,
newpath: &Path,
_file_type: Option<FsFileType>,
) -> FsResult<()> {
std::os::unix::fs::symlink(oldpath, newpath)?;
Ok(())
}
#[cfg(windows)]
fn symlink(
oldpath: &Path,
newpath: &Path,
file_type: Option<FsFileType>,
) -> FsResult<()> {
let file_type = match file_type {
Some(file_type) => file_type,
None => {
let old_meta = fs::metadata(oldpath);
match old_meta {
Ok(metadata) => {
if metadata.is_file() {
FsFileType::File
} else if metadata.is_dir() {
FsFileType::Directory
} else {
return Err(FsError::Io(io::Error::new(
io::ErrorKind::InvalidInput,
"On Windows the target must be a file or directory",
)));
}
}
Err(err) if err.kind() == io::ErrorKind::NotFound => {
return Err(FsError::Io(io::Error::new(
io::ErrorKind::InvalidInput,
"On Windows an `options` argument is required if the target does not exist",
)))
}
Err(err) => return Err(err.into()),
}
}
};
match file_type {
FsFileType::File => {
std::os::windows::fs::symlink_file(oldpath, newpath)?;
}
FsFileType::Directory => {
std::os::windows::fs::symlink_dir(oldpath, newpath)?;
}
FsFileType::Junction => {
junction::create(oldpath, newpath)?;
}
};
Ok(())
}
fn truncate(path: &Path, len: u64) -> FsResult<()> {
let file = fs::OpenOptions::new().write(true).open(path)?;
file.set_len(len)?;
Ok(())
}
fn open_options(options: OpenOptions) -> fs::OpenOptions {
let mut open_options = fs::OpenOptions::new();
if let Some(mode) = options.mode {
// mode only used if creating the file on Unix
// if not specified, defaults to 0o666
#[cfg(unix)]
{
use std::os::unix::fs::OpenOptionsExt;
open_options.mode(mode & 0o777);
}
#[cfg(not(unix))]
let _ = mode; // avoid unused warning
}
open_options.read(options.read);
open_options.create(options.create);
open_options.write(options.write);
open_options.truncate(options.truncate);
open_options.append(options.append);
open_options.create_new(options.create_new);
open_options
}
#[inline(always)]
fn open_with_access_check(
options: OpenOptions,
path: &Path,
access_check: Option<AccessCheckCb>,
) -> FsResult<std::fs::File> {
if let Some(access_check) = access_check {
let path_bytes = path.as_os_str().as_encoded_bytes();
let is_windows_device_path = cfg!(windows)
&& path_bytes.starts_with(br"\\.\")
&& !path_bytes.contains(&b':');
let path = if is_windows_device_path {
// On Windows, normalize_path doesn't work with device-prefix-style
// paths. We pass these through.
path.to_owned()
} else if path.is_absolute() {
normalize_path(path)
} else {
let cwd = current_dir()?;
normalize_path(cwd.join(path))
};
(*access_check)(false, &path, &options)?;
// On Linux, /proc may contain magic links that we don't want to resolve
let is_linux_special_path = cfg!(target_os = "linux")
&& (path.starts_with("/proc") || path.starts_with("/dev"));
let needs_canonicalization =
!is_windows_device_path && !is_linux_special_path;
let path = if needs_canonicalization {
match path.canonicalize() {
Ok(path) => path,
Err(_) => {
if let (Some(parent), Some(filename)) =
(path.parent(), path.file_name())
{
parent.canonicalize()?.join(filename)
} else {
return Err(std::io::ErrorKind::NotFound.into());
}
}
}
} else {
path
};
(*access_check)(true, &path, &options)?;
let mut opts: fs::OpenOptions = open_options(options);
#[cfg(windows)]
{
// allow opening directories
use std::os::windows::fs::OpenOptionsExt;
opts.custom_flags(winapi::um::winbase::FILE_FLAG_BACKUP_SEMANTICS);
}
#[cfg(unix)]
{
// Don't follow symlinks on open -- we must always pass fully-resolved files
// with the exception of /proc/ which is too special, and /dev/std* which might point to
// proc.
use std::os::unix::fs::OpenOptionsExt;
if needs_canonicalization {
opts.custom_flags(libc::O_NOFOLLOW);
}
}
Ok(opts.open(&path)?)
} else {
// for unix
#[allow(unused_mut)]
let mut opts = open_options(options);
#[cfg(windows)]
{
// allow opening directories
use std::os::windows::fs::OpenOptionsExt;
opts.custom_flags(winapi::um::winbase::FILE_FLAG_BACKUP_SEMANTICS);
}
Ok(opts.open(path)?)
}
}