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denoland-deno/cli/util/fs.rs

1004 lines
31 KiB
Rust

// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
use std::fs::OpenOptions;
use std::io::Error;
use std::io::ErrorKind;
use std::io::Write;
use std::path::Path;
use std::path::PathBuf;
use std::sync::Arc;
use std::time::Duration;
use deno_config::glob::FileCollector;
use deno_config::glob::FilePatterns;
use deno_config::glob::PathOrPattern;
use deno_config::glob::PathOrPatternSet;
use deno_config::glob::WalkEntry;
use deno_core::anyhow::anyhow;
use deno_core::anyhow::Context;
use deno_core::error::AnyError;
use deno_core::unsync::spawn_blocking;
use deno_core::ModuleSpecifier;
use deno_runtime::deno_fs::FileSystem;
use crate::util::path::get_atomic_file_path;
use crate::util::progress_bar::ProgressBar;
use crate::util::progress_bar::ProgressBarStyle;
use crate::util::progress_bar::ProgressMessagePrompt;
/// Writes the file to the file system at a temporary path, then
/// renames it to the destination in a single sys call in order
/// to never leave the file system in a corrupted state.
///
/// This also handles creating the directory if a NotFound error
/// occurs.
pub fn atomic_write_file_with_retries<T: AsRef<[u8]>>(
file_path: &Path,
data: T,
mode: u32,
) -> std::io::Result<()> {
struct RealAtomicWriteFileFs {
mode: u32,
}
impl AtomicWriteFileFs for RealAtomicWriteFileFs {
fn write_file(&self, path: &Path, bytes: &[u8]) -> std::io::Result<()> {
write_file(path, bytes, self.mode)
}
fn rename_file(&self, from: &Path, to: &Path) -> std::io::Result<()> {
std::fs::rename(from, to)
}
fn remove_file(&self, path: &Path) -> std::io::Result<()> {
std::fs::remove_file(path)
}
fn create_dir_all(&self, dir_path: &Path) -> std::io::Result<()> {
std::fs::create_dir_all(dir_path)
}
fn path_exists(&self, path: &Path) -> bool {
path.exists()
}
}
atomic_write_file_with_retries_and_fs(
&RealAtomicWriteFileFs { mode },
file_path,
data.as_ref(),
)
}
pub trait AtomicWriteFileFs {
fn write_file(&self, path: &Path, bytes: &[u8]) -> std::io::Result<()>;
fn rename_file(&self, from: &Path, to: &Path) -> std::io::Result<()>;
fn remove_file(&self, path: &Path) -> std::io::Result<()>;
fn create_dir_all(&self, dir_path: &Path) -> std::io::Result<()>;
fn path_exists(&self, path: &Path) -> bool;
}
pub struct AtomicWriteFileFsAdapter<'a> {
pub fs: &'a dyn FileSystem,
pub write_mode: u32,
}
impl<'a> AtomicWriteFileFs for AtomicWriteFileFsAdapter<'a> {
fn write_file(&self, path: &Path, bytes: &[u8]) -> std::io::Result<()> {
self
.fs
.write_file_sync(
path,
deno_runtime::deno_fs::OpenOptions::write(
true,
false,
false,
Some(self.write_mode),
),
None,
bytes,
)
.map_err(|e| e.into_io_error())
}
fn rename_file(&self, from: &Path, to: &Path) -> std::io::Result<()> {
self.fs.rename_sync(from, to).map_err(|e| e.into_io_error())
}
fn remove_file(&self, path: &Path) -> std::io::Result<()> {
self
.fs
.remove_sync(path, false)
.map_err(|e| e.into_io_error())
}
fn create_dir_all(&self, dir_path: &Path) -> std::io::Result<()> {
self
.fs
.mkdir_sync(dir_path, /* recursive */ true, None)
.map_err(|e| e.into_io_error())
}
fn path_exists(&self, path: &Path) -> bool {
self.fs.exists_sync(path)
}
}
pub fn atomic_write_file_with_retries_and_fs<T: AsRef<[u8]>>(
fs: &impl AtomicWriteFileFs,
file_path: &Path,
data: T,
) -> std::io::Result<()> {
let mut count = 0;
loop {
match atomic_write_file(fs, file_path, data.as_ref()) {
Ok(()) => return Ok(()),
Err(err) => {
if count >= 5 {
// too many retries, return the error
return Err(err);
}
count += 1;
let sleep_ms = std::cmp::min(50, 10 * count);
std::thread::sleep(std::time::Duration::from_millis(sleep_ms));
}
}
}
}
/// Writes the file to the file system at a temporary path, then
/// renames it to the destination in a single sys call in order
/// to never leave the file system in a corrupted state.
///
/// This also handles creating the directory if a NotFound error
/// occurs.
fn atomic_write_file(
fs: &impl AtomicWriteFileFs,
file_path: &Path,
data: &[u8],
) -> std::io::Result<()> {
fn atomic_write_file_raw(
fs: &impl AtomicWriteFileFs,
temp_file_path: &Path,
file_path: &Path,
data: &[u8],
) -> std::io::Result<()> {
fs.write_file(temp_file_path, data)?;
fs.rename_file(temp_file_path, file_path)
.inspect_err(|_err| {
// clean up the created temp file on error
let _ = fs.remove_file(temp_file_path);
})
}
let temp_file_path = get_atomic_file_path(file_path);
if let Err(write_err) =
atomic_write_file_raw(fs, &temp_file_path, file_path, data)
{
if write_err.kind() == ErrorKind::NotFound {
let parent_dir_path = file_path.parent().unwrap();
match fs.create_dir_all(parent_dir_path) {
Ok(()) => {
return atomic_write_file_raw(fs, &temp_file_path, file_path, data)
.map_err(|err| add_file_context_to_err(file_path, err));
}
Err(create_err) => {
if !fs.path_exists(parent_dir_path) {
return Err(Error::new(
create_err.kind(),
format!(
"{:#} (for '{}')\nCheck the permission of the directory.",
create_err,
parent_dir_path.display()
),
));
}
}
}
}
return Err(add_file_context_to_err(file_path, write_err));
}
Ok(())
}
/// Creates a std::fs::File handling if the parent does not exist.
pub fn create_file(file_path: &Path) -> std::io::Result<std::fs::File> {
match std::fs::File::create(file_path) {
Ok(file) => Ok(file),
Err(err) => {
if err.kind() == ErrorKind::NotFound {
let parent_dir_path = file_path.parent().unwrap();
match std::fs::create_dir_all(parent_dir_path) {
Ok(()) => {
return std::fs::File::create(file_path)
.map_err(|err| add_file_context_to_err(file_path, err));
}
Err(create_err) => {
if !parent_dir_path.exists() {
return Err(Error::new(
create_err.kind(),
format!(
"{:#} (for '{}')\nCheck the permission of the directory.",
create_err,
parent_dir_path.display()
),
));
}
}
}
}
Err(add_file_context_to_err(file_path, err))
}
}
}
fn add_file_context_to_err(file_path: &Path, err: Error) -> Error {
Error::new(
err.kind(),
format!("{:#} (for '{}')", err, file_path.display()),
)
}
pub fn write_file<T: AsRef<[u8]>>(
filename: &Path,
data: T,
mode: u32,
) -> std::io::Result<()> {
write_file_2(filename, data, true, mode, true, false)
}
pub fn write_file_2<T: AsRef<[u8]>>(
filename: &Path,
data: T,
update_mode: bool,
mode: u32,
is_create: bool,
is_append: bool,
) -> std::io::Result<()> {
let mut file = OpenOptions::new()
.read(false)
.write(true)
.append(is_append)
.truncate(!is_append)
.create(is_create)
.open(filename)?;
if update_mode {
#[cfg(unix)]
{
use std::os::unix::fs::PermissionsExt;
let mode = mode & 0o777;
let permissions = PermissionsExt::from_mode(mode);
file.set_permissions(permissions)?;
}
#[cfg(not(unix))]
let _ = mode;
}
file.write_all(data.as_ref())
}
/// Similar to `std::fs::canonicalize()` but strips UNC prefixes on Windows.
pub fn canonicalize_path(path: &Path) -> Result<PathBuf, Error> {
Ok(deno_path_util::strip_unc_prefix(path.canonicalize()?))
}
/// Canonicalizes a path which might be non-existent by going up the
/// ancestors until it finds a directory that exists, canonicalizes
/// that path, then adds back the remaining path components.
///
/// Note: When using this, you should be aware that a symlink may
/// subsequently be created along this path by some other code.
pub fn canonicalize_path_maybe_not_exists(
path: &Path,
) -> Result<PathBuf, Error> {
deno_path_util::canonicalize_path_maybe_not_exists(path, &canonicalize_path)
}
pub fn canonicalize_path_maybe_not_exists_with_fs(
path: &Path,
fs: &dyn FileSystem,
) -> Result<PathBuf, Error> {
deno_path_util::canonicalize_path_maybe_not_exists(path, &|path| {
fs.realpath_sync(path).map_err(|err| err.into_io_error())
})
}
/// Collects module specifiers that satisfy the given predicate as a file path, by recursively walking `include`.
/// Specifiers that start with http and https are left intact.
/// Note: This ignores all .git and node_modules folders.
pub fn collect_specifiers(
mut files: FilePatterns,
vendor_folder: Option<PathBuf>,
predicate: impl Fn(WalkEntry) -> bool,
) -> Result<Vec<ModuleSpecifier>, AnyError> {
let mut prepared = vec![];
// break out the remote specifiers
if let Some(include_mut) = &mut files.include {
let includes = std::mem::take(include_mut);
let path_or_patterns = includes.into_path_or_patterns();
let mut result = Vec::with_capacity(path_or_patterns.len());
for path_or_pattern in path_or_patterns {
match path_or_pattern {
PathOrPattern::Path(path) => {
if path.is_dir() {
result.push(PathOrPattern::Path(path));
} else if !files.exclude.matches_path(&path) {
let url = specifier_from_file_path(&path)?;
prepared.push(url);
}
}
PathOrPattern::NegatedPath(path) => {
// add it back
result.push(PathOrPattern::NegatedPath(path));
}
PathOrPattern::RemoteUrl(remote_url) => {
prepared.push(remote_url);
}
PathOrPattern::Pattern(pattern) => {
// add it back
result.push(PathOrPattern::Pattern(pattern));
}
}
}
*include_mut = PathOrPatternSet::new(result);
}
let collected_files = FileCollector::new(predicate)
.ignore_git_folder()
.ignore_node_modules()
.set_vendor_folder(vendor_folder)
.collect_file_patterns(&deno_config::fs::RealDenoConfigFs, files)?;
let mut collected_files_as_urls = collected_files
.iter()
.map(|f| specifier_from_file_path(f).unwrap())
.collect::<Vec<ModuleSpecifier>>();
collected_files_as_urls.sort();
prepared.extend(collected_files_as_urls);
Ok(prepared)
}
/// Asynchronously removes a directory and all its descendants, but does not error
/// when the directory does not exist.
pub async fn remove_dir_all_if_exists(path: &Path) -> std::io::Result<()> {
let result = tokio::fs::remove_dir_all(path).await;
match result {
Err(err) if err.kind() == std::io::ErrorKind::NotFound => Ok(()),
_ => result,
}
}
mod clone_dir_imp {
#[cfg(target_vendor = "apple")]
mod apple {
use super::super::copy_dir_recursive;
use deno_core::error::AnyError;
use std::os::unix::ffi::OsStrExt;
use std::path::Path;
fn clonefile(from: &Path, to: &Path) -> std::io::Result<()> {
let from = std::ffi::CString::new(from.as_os_str().as_bytes())?;
let to = std::ffi::CString::new(to.as_os_str().as_bytes())?;
// SAFETY: `from` and `to` are valid C strings.
let ret = unsafe { libc::clonefile(from.as_ptr(), to.as_ptr(), 0) };
if ret != 0 {
return Err(std::io::Error::last_os_error());
}
Ok(())
}
pub fn clone_dir_recursive(from: &Path, to: &Path) -> Result<(), AnyError> {
if let Some(parent) = to.parent() {
std::fs::create_dir_all(parent)?;
}
// Try to clone the whole directory
if let Err(err) = clonefile(from, to) {
if err.kind() != std::io::ErrorKind::AlreadyExists {
log::warn!(
"Failed to clone dir {:?} to {:?} via clonefile: {}",
from,
to,
err
);
}
// clonefile won't overwrite existing files, so if the dir exists
// we need to handle it recursively.
copy_dir_recursive(from, to)?;
}
Ok(())
}
}
#[cfg(target_vendor = "apple")]
pub(super) use apple::clone_dir_recursive;
#[cfg(not(target_vendor = "apple"))]
pub(super) fn clone_dir_recursive(
from: &std::path::Path,
to: &std::path::Path,
) -> Result<(), deno_core::error::AnyError> {
if let Err(e) = super::hard_link_dir_recursive(from, to) {
log::debug!("Failed to hard link dir {:?} to {:?}: {}", from, to, e);
super::copy_dir_recursive(from, to)?;
}
Ok(())
}
}
/// Clones a directory to another directory. The exact method
/// is not guaranteed - it may be a hardlink, copy, or other platform-specific
/// operation.
///
/// Note: Does not handle symlinks.
pub fn clone_dir_recursive(from: &Path, to: &Path) -> Result<(), AnyError> {
clone_dir_imp::clone_dir_recursive(from, to)
}
/// Copies a directory to another directory.
///
/// Note: Does not handle symlinks.
pub fn copy_dir_recursive(from: &Path, to: &Path) -> Result<(), AnyError> {
std::fs::create_dir_all(to)
.with_context(|| format!("Creating {}", to.display()))?;
let read_dir = std::fs::read_dir(from)
.with_context(|| format!("Reading {}", from.display()))?;
for entry in read_dir {
let entry = entry?;
let file_type = entry.file_type()?;
let new_from = from.join(entry.file_name());
let new_to = to.join(entry.file_name());
if file_type.is_dir() {
copy_dir_recursive(&new_from, &new_to).with_context(|| {
format!("Dir {} to {}", new_from.display(), new_to.display())
})?;
} else if file_type.is_file() {
std::fs::copy(&new_from, &new_to).with_context(|| {
format!("Copying {} to {}", new_from.display(), new_to.display())
})?;
}
}
Ok(())
}
/// Hardlinks the files in one directory to another directory.
///
/// Note: Does not handle symlinks.
pub fn hard_link_dir_recursive(from: &Path, to: &Path) -> Result<(), AnyError> {
std::fs::create_dir_all(to)
.with_context(|| format!("Creating {}", to.display()))?;
let read_dir = std::fs::read_dir(from)
.with_context(|| format!("Reading {}", from.display()))?;
for entry in read_dir {
let entry = entry?;
let file_type = entry.file_type()?;
let new_from = from.join(entry.file_name());
let new_to = to.join(entry.file_name());
if file_type.is_dir() {
hard_link_dir_recursive(&new_from, &new_to).with_context(|| {
format!("Dir {} to {}", new_from.display(), new_to.display())
})?;
} else if file_type.is_file() {
// note: chance for race conditions here between attempting to create,
// then removing, then attempting to create. There doesn't seem to be
// a way to hard link with overwriting in Rust, but maybe there is some
// way with platform specific code. The workaround here is to handle
// scenarios where something else might create or remove files.
if let Err(err) = std::fs::hard_link(&new_from, &new_to) {
if err.kind() == ErrorKind::AlreadyExists {
if let Err(err) = std::fs::remove_file(&new_to) {
if err.kind() == ErrorKind::NotFound {
// Assume another process/thread created this hard link to the file we are wanting
// to remove then sleep a little bit to let the other process/thread move ahead
// faster to reduce contention.
std::thread::sleep(Duration::from_millis(10));
} else {
return Err(err).with_context(|| {
format!(
"Removing file to hard link {} to {}",
new_from.display(),
new_to.display()
)
});
}
}
// Always attempt to recreate the hardlink. In contention scenarios, the other process
// might have been killed or exited after removing the file, but before creating the hardlink
if let Err(err) = std::fs::hard_link(&new_from, &new_to) {
// Assume another process/thread created this hard link to the file we are wanting
// to now create then sleep a little bit to let the other process/thread move ahead
// faster to reduce contention.
if err.kind() == ErrorKind::AlreadyExists {
std::thread::sleep(Duration::from_millis(10));
} else {
return Err(err).with_context(|| {
format!(
"Hard linking {} to {}",
new_from.display(),
new_to.display()
)
});
}
}
} else {
return Err(err).with_context(|| {
format!(
"Hard linking {} to {}",
new_from.display(),
new_to.display()
)
});
}
}
}
}
Ok(())
}
pub fn symlink_dir(oldpath: &Path, newpath: &Path) -> Result<(), Error> {
let err_mapper = |err: Error, kind: Option<ErrorKind>| {
Error::new(
kind.unwrap_or_else(|| err.kind()),
format!(
"{}, symlink '{}' -> '{}'",
err,
oldpath.display(),
newpath.display()
),
)
};
#[cfg(unix)]
{
use std::os::unix::fs::symlink;
symlink(oldpath, newpath).map_err(|e| err_mapper(e, None))?;
}
#[cfg(not(unix))]
{
use std::os::windows::fs::symlink_dir;
symlink_dir(oldpath, newpath).map_err(|err| {
if let Some(code) = err.raw_os_error() {
if code as u32 == winapi::shared::winerror::ERROR_PRIVILEGE_NOT_HELD
|| code as u32 == winapi::shared::winerror::ERROR_INVALID_FUNCTION
{
return err_mapper(err, Some(ErrorKind::PermissionDenied));
}
}
err_mapper(err, None)
})?;
}
Ok(())
}
/// Gets the total size (in bytes) of a directory.
pub fn dir_size(path: &Path) -> std::io::Result<u64> {
let entries = std::fs::read_dir(path)?;
let mut total = 0;
for entry in entries {
let entry = entry?;
total += match entry.metadata()? {
data if data.is_dir() => dir_size(&entry.path())?,
data => data.len(),
};
}
Ok(total)
}
struct LaxSingleProcessFsFlagInner {
file_path: PathBuf,
fs_file: std::fs::File,
finished_token: Arc<tokio_util::sync::CancellationToken>,
}
impl Drop for LaxSingleProcessFsFlagInner {
fn drop(&mut self) {
use fs3::FileExt;
// kill the poll thread
self.finished_token.cancel();
// release the file lock
if let Err(err) = self.fs_file.unlock() {
log::debug!(
"Failed releasing lock for {}. {:#}",
self.file_path.display(),
err
);
}
}
}
/// A file system based flag that will attempt to synchronize multiple
/// processes so they go one after the other. In scenarios where
/// synchronization cannot be achieved, it will allow the current process
/// to proceed.
///
/// This should only be used in places where it's ideal for multiple
/// processes to not update something on the file system at the same time,
/// but it's not that big of a deal.
pub struct LaxSingleProcessFsFlag(
#[allow(dead_code)] Option<LaxSingleProcessFsFlagInner>,
);
impl LaxSingleProcessFsFlag {
pub async fn lock(file_path: PathBuf, long_wait_message: &str) -> Self {
log::debug!("Acquiring file lock at {}", file_path.display());
use fs3::FileExt;
let last_updated_path = file_path.with_extension("lock.poll");
let start_instant = std::time::Instant::now();
let open_result = std::fs::OpenOptions::new()
.read(true)
.write(true)
.create(true)
.truncate(false)
.open(&file_path);
match open_result {
Ok(fs_file) => {
let mut pb_update_guard = None;
let mut error_count = 0;
while error_count < 10 {
let lock_result = fs_file.try_lock_exclusive();
let poll_file_update_ms = 100;
match lock_result {
Ok(_) => {
log::debug!("Acquired file lock at {}", file_path.display());
let _ignore = std::fs::write(&last_updated_path, "");
let token = Arc::new(tokio_util::sync::CancellationToken::new());
// Spawn a blocking task that will continually update a file
// signalling the lock is alive. This is a fail safe for when
// a file lock is never released. For example, on some operating
// systems, if a process does not release the lock (say it's
// killed), then the OS may release it at an indeterminate time
//
// This uses a blocking task because we use a single threaded
// runtime and this is time sensitive so we don't want it to update
// at the whims of whatever is occurring on the runtime thread.
spawn_blocking({
let token = token.clone();
let last_updated_path = last_updated_path.clone();
move || {
let mut i = 0;
while !token.is_cancelled() {
i += 1;
let _ignore =
std::fs::write(&last_updated_path, i.to_string());
std::thread::sleep(Duration::from_millis(
poll_file_update_ms,
));
}
}
});
return Self(Some(LaxSingleProcessFsFlagInner {
file_path,
fs_file,
finished_token: token,
}));
}
Err(_) => {
// show a message if it's been a while
if pb_update_guard.is_none()
&& start_instant.elapsed().as_millis() > 1_000
{
let pb = ProgressBar::new(ProgressBarStyle::TextOnly);
let guard = pb.update_with_prompt(
ProgressMessagePrompt::Blocking,
long_wait_message,
);
pb_update_guard = Some((guard, pb));
}
// sleep for a little bit
tokio::time::sleep(Duration::from_millis(20)).await;
// Poll the last updated path to check if it's stopped updating,
// which is an indication that the file lock is claimed, but
// was never properly released.
match std::fs::metadata(&last_updated_path)
.and_then(|p| p.modified())
{
Ok(last_updated_time) => {
let current_time = std::time::SystemTime::now();
match current_time.duration_since(last_updated_time) {
Ok(duration) => {
if duration.as_millis()
> (poll_file_update_ms * 2) as u128
{
// the other process hasn't updated this file in a long time
// so maybe it was killed and the operating system hasn't
// released the file lock yet
return Self(None);
} else {
error_count = 0; // reset
}
}
Err(_) => {
error_count += 1;
}
}
}
Err(_) => {
error_count += 1;
}
}
}
}
}
drop(pb_update_guard); // explicit for clarity
Self(None)
}
Err(err) => {
log::debug!(
"Failed to open file lock at {}. {:#}",
file_path.display(),
err
);
Self(None) // let the process through
}
}
}
}
pub fn specifier_from_file_path(
path: &Path,
) -> Result<ModuleSpecifier, AnyError> {
ModuleSpecifier::from_file_path(path)
.map_err(|_| anyhow!("Invalid file path '{}'", path.display()))
}
#[cfg(test)]
mod tests {
use super::*;
use deno_core::futures;
use deno_core::parking_lot::Mutex;
use deno_path_util::normalize_path;
use pretty_assertions::assert_eq;
use test_util::PathRef;
use test_util::TempDir;
use tokio::sync::Notify;
#[test]
fn test_normalize_path() {
assert_eq!(normalize_path(Path::new("a/../b")), PathBuf::from("b"));
assert_eq!(normalize_path(Path::new("a/./b/")), PathBuf::from("a/b/"));
assert_eq!(
normalize_path(Path::new("a/./b/../c")),
PathBuf::from("a/c")
);
if cfg!(windows) {
assert_eq!(
normalize_path(Path::new("C:\\a\\.\\b\\..\\c")),
PathBuf::from("C:\\a\\c")
);
}
}
#[test]
fn test_collect_specifiers() {
fn create_files(dir_path: &PathRef, files: &[&str]) {
dir_path.create_dir_all();
for f in files {
dir_path.join(f).write("");
}
}
// dir.ts
// ├── a.ts
// ├── b.js
// ├── child
// │ ├── e.mjs
// │ ├── f.mjsx
// │ ├── .foo.TS
// │ └── README.md
// ├── c.tsx
// ├── d.jsx
// └── ignore
// ├── g.d.ts
// └── .gitignore
let t = TempDir::new();
let root_dir_path = t.path().join("dir.ts");
let root_dir_files = ["a.ts", "b.js", "c.tsx", "d.jsx"];
create_files(&root_dir_path, &root_dir_files);
let child_dir_path = root_dir_path.join("child");
let child_dir_files = ["e.mjs", "f.mjsx", ".foo.TS", "README.md"];
create_files(&child_dir_path, &child_dir_files);
let ignore_dir_path = root_dir_path.join("ignore");
let ignore_dir_files = ["g.d.ts", ".gitignore"];
create_files(&ignore_dir_path, &ignore_dir_files);
let predicate = |e: WalkEntry| {
// exclude dotfiles
e.path
.file_name()
.and_then(|f| f.to_str())
.map(|f| !f.starts_with('.'))
.unwrap_or(false)
};
let result = collect_specifiers(
FilePatterns {
base: root_dir_path.to_path_buf(),
include: Some(
PathOrPatternSet::from_include_relative_path_or_patterns(
root_dir_path.as_path(),
&[
"http://localhost:8080".to_string(),
"./".to_string(),
"https://localhost:8080".to_string(),
],
)
.unwrap(),
),
exclude: PathOrPatternSet::new(vec![PathOrPattern::Path(
ignore_dir_path.to_path_buf(),
)]),
},
None,
predicate,
)
.unwrap();
let root_dir_url = ModuleSpecifier::from_file_path(&root_dir_path)
.unwrap()
.to_string();
let expected = vec![
"http://localhost:8080/".to_string(),
"https://localhost:8080/".to_string(),
format!("{root_dir_url}/a.ts"),
format!("{root_dir_url}/b.js"),
format!("{root_dir_url}/c.tsx"),
format!("{root_dir_url}/child/README.md"),
format!("{root_dir_url}/child/e.mjs"),
format!("{root_dir_url}/child/f.mjsx"),
format!("{root_dir_url}/d.jsx"),
];
assert_eq!(
result
.into_iter()
.map(|s| s.to_string())
.collect::<Vec<_>>(),
expected
);
let scheme = if cfg!(target_os = "windows") {
"file:///"
} else {
"file://"
};
let result = collect_specifiers(
FilePatterns {
base: root_dir_path.to_path_buf(),
include: Some(PathOrPatternSet::new(vec![PathOrPattern::new(
&format!(
"{}{}",
scheme,
root_dir_path.join("child").to_string().replace('\\', "/")
),
)
.unwrap()])),
exclude: Default::default(),
},
None,
predicate,
)
.unwrap();
let expected = vec![
format!("{root_dir_url}/child/README.md"),
format!("{root_dir_url}/child/e.mjs"),
format!("{root_dir_url}/child/f.mjsx"),
];
assert_eq!(
result
.into_iter()
.map(|s| s.to_string())
.collect::<Vec<_>>(),
expected
);
}
#[tokio::test]
async fn lax_fs_lock() {
let temp_dir = TempDir::new();
let lock_path = temp_dir.path().join("file.lock");
let signal1 = Arc::new(Notify::new());
let signal2 = Arc::new(Notify::new());
let signal3 = Arc::new(Notify::new());
let signal4 = Arc::new(Notify::new());
tokio::spawn({
let lock_path = lock_path.clone();
let signal1 = signal1.clone();
let signal2 = signal2.clone();
let signal3 = signal3.clone();
let signal4 = signal4.clone();
let temp_dir = temp_dir.clone();
async move {
let flag =
LaxSingleProcessFsFlag::lock(lock_path.to_path_buf(), "waiting")
.await;
signal1.notify_one();
signal2.notified().await;
tokio::time::sleep(Duration::from_millis(10)).await; // give the other thread time to acquire the lock
temp_dir.write("file.txt", "update1");
signal3.notify_one();
signal4.notified().await;
drop(flag);
}
});
let signal5 = Arc::new(Notify::new());
tokio::spawn({
let temp_dir = temp_dir.clone();
let signal5 = signal5.clone();
async move {
signal1.notified().await;
signal2.notify_one();
let flag =
LaxSingleProcessFsFlag::lock(lock_path.to_path_buf(), "waiting")
.await;
temp_dir.write("file.txt", "update2");
signal5.notify_one();
drop(flag);
}
});
signal3.notified().await;
assert_eq!(temp_dir.read_to_string("file.txt"), "update1");
signal4.notify_one();
signal5.notified().await;
assert_eq!(temp_dir.read_to_string("file.txt"), "update2");
}
#[tokio::test]
async fn lax_fs_lock_ordered() {
let temp_dir = TempDir::new();
let lock_path = temp_dir.path().join("file.lock");
let output_path = temp_dir.path().join("output");
let expected_order = Arc::new(Mutex::new(Vec::new()));
let count = 10;
let mut tasks = Vec::with_capacity(count);
std::fs::write(&output_path, "").unwrap();
for i in 0..count {
let lock_path = lock_path.clone();
let output_path = output_path.clone();
let expected_order = expected_order.clone();
tasks.push(tokio::spawn(async move {
let flag =
LaxSingleProcessFsFlag::lock(lock_path.to_path_buf(), "waiting")
.await;
expected_order.lock().push(i.to_string());
// be extremely racy
let mut output = std::fs::read_to_string(&output_path).unwrap();
if !output.is_empty() {
output.push('\n');
}
output.push_str(&i.to_string());
std::fs::write(&output_path, output).unwrap();
drop(flag);
}));
}
futures::future::join_all(tasks).await;
let expected_output = expected_order.lock().join("\n");
assert_eq!(
std::fs::read_to_string(output_path).unwrap(),
expected_output
);
}
}