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use std::cell::UnsafeCell; use std::cmp; use std::fmt; use std::io::{Read as _, Seek as _, Write as _}; use std::ops::{Deref, DerefMut}; use std::pin::Pin; use std::sync::atomic::{AtomicBool, Ordering}; use std::sync::{Arc, Mutex}; use crate::fs::{Metadata, Permissions}; use crate::future; use crate::io::{self, Read, Seek, SeekFrom, Write}; use crate::path::Path; use crate::prelude::*; use crate::task::{spawn_blocking, Context, Poll, Waker}; use crate::utils::Context as _; /// An open file on the filesystem. /// /// Depending on what options the file was opened with, this type can be used for reading and/or /// writing. /// /// Files are automatically closed when they get dropped and any errors detected on closing are /// ignored. Use the [`sync_all`] method before dropping a file if such errors need to be handled. /// /// This type is an async version of [`std::fs::File`]. /// /// [`sync_all`]: #method.sync_all /// [`std::fs::File`]: https://doc.rust-lang.org/std/fs/struct.File.html /// /// # Examples /// /// Create a new file and write some bytes to it: /// /// ```no_run /// # fn main() -> std::io::Result<()> { async_std::task::block_on(async { /// # /// use async_std::fs::File; /// use async_std::prelude::*; /// /// let mut file = File::create("a.txt").await?; /// file.write_all(b"Hello, world!").await?; /// # /// # Ok(()) }) } /// ``` /// /// Read the contents of a file into a vector of bytes: /// /// ```no_run /// # fn main() -> std::io::Result<()> { async_std::task::block_on(async { /// # /// use async_std::fs::File; /// use async_std::prelude::*; /// /// let mut file = File::open("a.txt").await?; /// let mut contents = Vec::new(); /// file.read_to_end(&mut contents).await?; /// # /// # Ok(()) }) } /// ``` pub struct File { /// A reference to the inner file. file: Arc<std::fs::File>, /// The state of the file protected by an async lock. lock: Lock<State>, } impl File { /// Creates an async file handle. pub(crate) fn new(file: std::fs::File, is_flushed: bool) -> File { let file = Arc::new(file); File { file: file.clone(), lock: Lock::new(State { file, mode: Mode::Idle, cache: Vec::new(), is_flushed, last_read_err: None, last_write_err: None, }), } } /// Opens a file in read-only mode. /// /// See the [`OpenOptions::open`] function for more options. /// /// # Errors /// /// An error will be returned in the following situations: /// /// * `path` does not point to an existing file. /// * The current process lacks permissions to read the file. /// * Some other I/O error occurred. /// /// For more details, see the list of errors documented by [`OpenOptions::open`]. /// /// [`OpenOptions::open`]: struct.OpenOptions.html#method.open /// /// # Examples /// /// ```no_run /// # fn main() -> std::io::Result<()> { async_std::task::block_on(async { /// # /// use async_std::fs::File; /// /// let file = File::open("a.txt").await?; /// # /// # Ok(()) }) } /// ``` pub async fn open<P: AsRef<Path>>(path: P) -> io::Result<File> { let path = path.as_ref().to_owned(); let file = spawn_blocking(move || { std::fs::File::open(&path).context(|| format!("could not open `{}`", path.display())) }) .await?; Ok(File::new(file, true)) } /// Opens a file in write-only mode. /// /// This function will create a file if it does not exist, and will truncate it if it does. /// /// See the [`OpenOptions::open`] function for more options. /// /// # Errors /// /// An error will be returned in the following situations: /// /// * The file's parent directory does not exist. /// * The current process lacks permissions to write to the file. /// * Some other I/O error occurred. /// /// For more details, see the list of errors documented by [`OpenOptions::open`]. /// /// [`OpenOptions::open`]: struct.OpenOptions.html#method.open /// /// # Examples /// /// ```no_run /// # fn main() -> std::io::Result<()> { async_std::task::block_on(async { /// # /// use async_std::fs::File; /// /// let file = File::create("a.txt").await?; /// # /// # Ok(()) }) } /// ``` pub async fn create<P: AsRef<Path>>(path: P) -> io::Result<File> { let path = path.as_ref().to_owned(); let file = spawn_blocking(move || { std::fs::File::create(&path) .context(|| format!("could not create `{}`", path.display())) }) .await?; Ok(File::new(file, true)) } /// Synchronizes OS-internal buffered contents and metadata to disk. /// /// This function will ensure that all in-memory data reaches the filesystem. /// /// This can be used to handle errors that would otherwise only be caught when the file is /// closed. When a file is dropped, errors in synchronizing this in-memory data are ignored. /// /// # Examples /// /// ```no_run /// # fn main() -> std::io::Result<()> { async_std::task::block_on(async { /// # /// use async_std::fs::File; /// use async_std::prelude::*; /// /// let mut file = File::create("a.txt").await?; /// file.write_all(b"Hello, world!").await?; /// file.sync_all().await?; /// # /// # Ok(()) }) } /// ``` pub async fn sync_all(&self) -> io::Result<()> { // Flush the write cache before calling `sync_all()`. let state = future::poll_fn(|cx| { let state = futures_core::ready!(self.lock.poll_lock(cx)); state.poll_flush(cx) }) .await?; spawn_blocking(move || state.file.sync_all()).await } /// Synchronizes OS-internal buffered contents to disk. /// /// This is similar to [`sync_all`], except that file metadata may not be synchronized. /// /// This is intended for use cases that must synchronize the contents of the file, but don't /// need the file metadata synchronized to disk. /// /// Note that some platforms may simply implement this in terms of [`sync_all`]. /// /// [`sync_all`]: #method.sync_all /// /// # Examples /// /// ```no_run /// # fn main() -> std::io::Result<()> { async_std::task::block_on(async { /// # /// use async_std::fs::File; /// use async_std::prelude::*; /// /// let mut file = File::create("a.txt").await?; /// file.write_all(b"Hello, world!").await?; /// file.sync_data().await?; /// # /// # Ok(()) }) } /// ``` pub async fn sync_data(&self) -> io::Result<()> { // Flush the write cache before calling `sync_data()`. let state = future::poll_fn(|cx| { let state = futures_core::ready!(self.lock.poll_lock(cx)); state.poll_flush(cx) }) .await?; spawn_blocking(move || state.file.sync_data()).await } /// Truncates or extends the file. /// /// If `size` is less than the current file size, then the file will be truncated. If it is /// greater than the current file size, then the file will be extended to `size` and have all /// intermediate data filled with zeros. /// /// The file's cursor stays at the same position, even if the cursor ends up being past the end /// of the file after this operation. /// /// # Examples /// /// ```no_run /// # fn main() -> std::io::Result<()> { async_std::task::block_on(async { /// # /// use async_std::fs::File; /// /// let file = File::create("a.txt").await?; /// file.set_len(10).await?; /// # /// # Ok(()) }) } /// ``` pub async fn set_len(&self, size: u64) -> io::Result<()> { // Invalidate the read cache and flush the write cache before calling `set_len()`. let state = future::poll_fn(|cx| { let state = futures_core::ready!(self.lock.poll_lock(cx)); let state = futures_core::ready!(state.poll_unread(cx))?; state.poll_flush(cx) }) .await?; spawn_blocking(move || state.file.set_len(size)).await } /// Reads the file's metadata. /// /// # Examples /// /// ```no_run /// # fn main() -> std::io::Result<()> { async_std::task::block_on(async { /// # /// use async_std::fs::File; /// /// let file = File::open("a.txt").await?; /// let metadata = file.metadata().await?; /// # /// # Ok(()) }) } /// ``` pub async fn metadata(&self) -> io::Result<Metadata> { let file = self.file.clone(); spawn_blocking(move || file.metadata()).await } /// Changes the permissions on the file. /// /// # Errors /// /// An error will be returned in the following situations: /// /// * The current process lacks permissions to change attributes on the file. /// * Some other I/O error occurred. /// /// # Examples /// /// ```no_run /// # fn main() -> std::io::Result<()> { async_std::task::block_on(async { /// # /// use async_std::fs::File; /// /// let file = File::create("a.txt").await?; /// /// let mut perms = file.metadata().await?.permissions(); /// perms.set_readonly(true); /// file.set_permissions(perms).await?; /// # /// # Ok(()) }) } /// ``` pub async fn set_permissions(&self, perm: Permissions) -> io::Result<()> { let file = self.file.clone(); spawn_blocking(move || file.set_permissions(perm)).await } } impl Drop for File { fn drop(&mut self) { // We need to flush the file on drop. Unfortunately, that is not possible to do in a // non-blocking fashion, but our only other option here is losing data remaining in the // write cache. Good task schedulers should be resilient to occasional blocking hiccups in // file destructors so we don't expect this to be a common problem in practice. let _ = futures_lite::future::block_on(self.flush()); } } impl fmt::Debug for File { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { self.file.fmt(f) } } impl Read for File { fn poll_read( self: Pin<&mut Self>, cx: &mut Context<'_>, buf: &mut [u8], ) -> Poll<io::Result<usize>> { Pin::new(&mut &*self).poll_read(cx, buf) } } impl Read for &File { fn poll_read( self: Pin<&mut Self>, cx: &mut Context<'_>, buf: &mut [u8], ) -> Poll<io::Result<usize>> { let state = futures_core::ready!(self.lock.poll_lock(cx)); state.poll_read(cx, buf) } } impl Write for File { fn poll_write( self: Pin<&mut Self>, cx: &mut Context<'_>, buf: &[u8], ) -> Poll<io::Result<usize>> { Pin::new(&mut &*self).poll_write(cx, buf) } fn poll_flush(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<io::Result<()>> { Pin::new(&mut &*self).poll_flush(cx) } fn poll_close(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<io::Result<()>> { Pin::new(&mut &*self).poll_close(cx) } } impl Write for &File { fn poll_write( self: Pin<&mut Self>, cx: &mut Context<'_>, buf: &[u8], ) -> Poll<io::Result<usize>> { let state = futures_core::ready!(self.lock.poll_lock(cx)); state.poll_write(cx, buf) } fn poll_flush(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<io::Result<()>> { let state = futures_core::ready!(self.lock.poll_lock(cx)); state.poll_flush(cx).map(|res| res.map(drop)) } fn poll_close(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<io::Result<()>> { let state = futures_core::ready!(self.lock.poll_lock(cx)); state.poll_close(cx) } } impl Seek for File { fn poll_seek( self: Pin<&mut Self>, cx: &mut Context<'_>, pos: SeekFrom, ) -> Poll<io::Result<u64>> { Pin::new(&mut &*self).poll_seek(cx, pos) } } impl Seek for &File { fn poll_seek( self: Pin<&mut Self>, cx: &mut Context<'_>, pos: SeekFrom, ) -> Poll<io::Result<u64>> { let state = futures_core::ready!(self.lock.poll_lock(cx)); state.poll_seek(cx, pos) } } impl From<std::fs::File> for File { fn from(file: std::fs::File) -> File { File::new(file, false) } } cfg_unix! { use crate::os::unix::io::{AsRawFd, FromRawFd, IntoRawFd, RawFd}; impl AsRawFd for File { fn as_raw_fd(&self) -> RawFd { self.file.as_raw_fd() } } impl FromRawFd for File { unsafe fn from_raw_fd(fd: RawFd) -> File { std::fs::File::from_raw_fd(fd).into() } } impl IntoRawFd for File { fn into_raw_fd(self) -> RawFd { let file = self.file.clone(); drop(self); Arc::try_unwrap(file) .expect("cannot acquire ownership of the file handle after drop") .into_raw_fd() } } } cfg_windows! { use crate::os::windows::io::{AsRawHandle, FromRawHandle, IntoRawHandle, RawHandle}; impl AsRawHandle for File { fn as_raw_handle(&self) -> RawHandle { self.file.as_raw_handle() } } impl FromRawHandle for File { unsafe fn from_raw_handle(handle: RawHandle) -> File { std::fs::File::from_raw_handle(handle).into() } } impl IntoRawHandle for File { fn into_raw_handle(self) -> RawHandle { let file = self.file.clone(); drop(self); Arc::try_unwrap(file) .expect("cannot acquire ownership of the file handle after drop") .into_raw_handle() } } } /// An async mutex with non-borrowing lock guards. struct Lock<T>(Arc<LockState<T>>); unsafe impl<T: Send> Send for Lock<T> {} unsafe impl<T: Send> Sync for Lock<T> {} /// The state of a lock. struct LockState<T> { /// Set to `true` when locked. locked: AtomicBool, /// The inner value. value: UnsafeCell<T>, /// A list of tasks interested in acquiring the lock. wakers: Mutex<Vec<Waker>>, } impl<T> Lock<T> { /// Creates a new lock initialized with `value`. fn new(value: T) -> Lock<T> { Lock(Arc::new(LockState { locked: AtomicBool::new(false), value: UnsafeCell::new(value), wakers: Mutex::new(Vec::new()), })) } /// Attempts to acquire the lock. fn poll_lock(&self, cx: &mut Context<'_>) -> Poll<LockGuard<T>> { // Try acquiring the lock. if self.0.locked.swap(true, Ordering::Acquire) { // Lock the list of wakers. let mut list = self.0.wakers.lock().unwrap(); // Try acquiring the lock again. if self.0.locked.swap(true, Ordering::Acquire) { // If failed again, add the current task to the list and return. if list.iter().all(|w| !w.will_wake(cx.waker())) { list.push(cx.waker().clone()); } return Poll::Pending; } } // The lock was successfully acquired. Poll::Ready(LockGuard(self.0.clone())) } } /// A lock guard. /// /// When dropped, ownership of the inner value is returned back to the lock. struct LockGuard<T>(Arc<LockState<T>>); unsafe impl<T: Send> Send for LockGuard<T> {} unsafe impl<T: Sync> Sync for LockGuard<T> {} impl<T> LockGuard<T> { /// Registers a task interested in acquiring the lock. /// /// When this lock guard gets dropped, all registered tasks will be woken up. fn register(&self, cx: &Context<'_>) { let mut list = self.0.wakers.lock().unwrap(); if list.iter().all(|w| !w.will_wake(cx.waker())) { list.push(cx.waker().clone()); } } } impl<T> Drop for LockGuard<T> { fn drop(&mut self) { // Release the lock. self.0.locked.store(false, Ordering::Release); // Wake up all registered tasks interested in acquiring the lock. for w in self.0.wakers.lock().unwrap().drain(..) { w.wake(); } } } impl<T> Deref for LockGuard<T> { type Target = T; fn deref(&self) -> &T { unsafe { &*self.0.value.get() } } } impl<T> DerefMut for LockGuard<T> { fn deref_mut(&mut self) -> &mut T { unsafe { &mut *self.0.value.get() } } } /// Modes a file can be in. /// /// The file can either be in idle mode, reading mode, or writing mode. enum Mode { /// The cache is empty. Idle, /// The cache contains data read from the inner file. /// /// The `usize` represents how many bytes from the beginning of cache have been consumed. Reading(usize), /// The cache contains data that needs to be written to the inner file. Writing, } /// The current state of a file. /// /// The `File` struct protects this state behind a lock. /// /// Filesystem operations that get spawned as blocking tasks will acquire the lock, take ownership /// of the state and return it back once the operation completes. struct State { /// The inner file. file: Arc<std::fs::File>, /// The current mode (idle, reading, or writing). mode: Mode, /// The read/write cache. /// /// If in reading mode, the cache contains a chunk of data that has been read from the file. /// If in writing mode, the cache contains data that will eventually be written to the file. cache: Vec<u8>, /// Set to `true` if the file is flushed. /// /// When a file is flushed, the write cache and the inner file's buffer are empty. is_flushed: bool, /// The last read error that came from an async operation. last_read_err: Option<io::Error>, /// The last write error that came from an async operation. last_write_err: Option<io::Error>, } impl LockGuard<State> { /// Seeks to a new position in the file. fn poll_seek(mut self, cx: &mut Context<'_>, pos: SeekFrom) -> Poll<io::Result<u64>> { // If this operation doesn't move the cursor, then poll the current position inside the // file. This call should not block because it doesn't touch the actual file on disk. if pos == SeekFrom::Current(0) { // Poll the internal file cursor. let internal = (&*self.file).seek(SeekFrom::Current(0))?; // Factor in the difference caused by caching. let actual = match self.mode { Mode::Idle => internal, Mode::Reading(start) => internal - self.cache.len() as u64 + start as u64, Mode::Writing => internal + self.cache.len() as u64, }; return Poll::Ready(Ok(actual)); } // If the file is in reading mode and the cache will stay valid after seeking, then adjust // the current position in the read cache without invaliding it. if let Mode::Reading(start) = self.mode { if let SeekFrom::Current(diff) = pos { if let Some(new) = (start as i64).checked_add(diff) { if 0 <= new && new <= self.cache.len() as i64 { // Poll the internal file cursor. let internal = (&*self.file).seek(SeekFrom::Current(0))?; // Adjust the current position in the read cache. self.mode = Mode::Reading(new as usize); // Factor in the difference caused by caching. return Poll::Ready(Ok(internal - self.cache.len() as u64 + new as u64)); } } } } // Invalidate the read cache and flush the write cache before calling `seek()`. self = futures_core::ready!(self.poll_unread(cx))?; self = futures_core::ready!(self.poll_flush(cx))?; // Seek to the new position. This call should not block because it only changes the // internal offset into the file and doesn't touch the actual file on disk. Poll::Ready((&*self.file).seek(pos)) } /// Reads some bytes from the file into a buffer. fn poll_read(mut self, cx: &mut Context<'_>, buf: &mut [u8]) -> Poll<io::Result<usize>> { // If an async operation has left a read error, return it now. if let Some(err) = self.last_read_err.take() { return Poll::Ready(Err(err)); } match self.mode { Mode::Idle => {} Mode::Reading(start) => { // How many bytes in the cache are available for reading. let available = self.cache.len() - start; // If there is cached unconsumed data or if the cache is empty, we can read from // it. Empty cache in reading mode indicates that the last operation didn't read // any bytes, i.e. it reached the end of the file. if available > 0 || self.cache.is_empty() { // Copy data from the cache into the buffer. let n = cmp::min(available, buf.len()); buf[..n].copy_from_slice(&self.cache[start..(start + n)]); // Move the read cursor forward. self.mode = Mode::Reading(start + n); return Poll::Ready(Ok(n)); } } Mode::Writing => { // If we're in writing mode, flush the write cache. self = futures_core::ready!(self.poll_flush(cx))?; } } // Make the cache as long as `buf`. if self.cache.len() < buf.len() { let diff = buf.len() - self.cache.len(); self.cache.reserve(diff); } unsafe { self.cache.set_len(buf.len()); } // Register current task's interest in the file lock. self.register(cx); // Start a read operation asynchronously. spawn_blocking(move || { // Read some data from the file into the cache. let res = { let State { file, cache, .. } = &mut *self; (&**file).read(cache) }; match res { Ok(n) => { // Update cache length and switch to reading mode, starting from index 0. unsafe { self.cache.set_len(n); } self.mode = Mode::Reading(0); } Err(err) => { // Save the error and switch to idle mode. self.cache.clear(); self.mode = Mode::Idle; self.last_read_err = Some(err); } } }); Poll::Pending } /// Invalidates the read cache. /// /// This method will also move the internal file's cursor backwards by the number of unconsumed /// bytes in the read cache. fn poll_unread(mut self, _: &mut Context<'_>) -> Poll<io::Result<Self>> { match self.mode { Mode::Idle | Mode::Writing => Poll::Ready(Ok(self)), Mode::Reading(start) => { // The number of unconsumed bytes in the read cache. let n = self.cache.len() - start; if n > 0 { // Seek `n` bytes backwards. This call should not block because it only changes // the internal offset into the file and doesn't touch the actual file on disk. // // We ignore errors here because special files like `/dev/random` are not // seekable. let _ = (&*self.file).seek(SeekFrom::Current(-(n as i64))); } // Switch to idle mode. self.cache.clear(); self.mode = Mode::Idle; Poll::Ready(Ok(self)) } } } /// Writes some data from a buffer into the file. fn poll_write(mut self, cx: &mut Context<'_>, buf: &[u8]) -> Poll<io::Result<usize>> { // If an async operation has left a write error, return it now. if let Some(err) = self.last_write_err.take() { return Poll::Ready(Err(err)); } // If we're in reading mode, invalidate the read buffer. self = futures_core::ready!(self.poll_unread(cx))?; // If necessary, grow the cache to have as much capacity as `buf`. if self.cache.capacity() < buf.len() { let diff = buf.len() - self.cache.capacity(); self.cache.reserve(diff); } // How many bytes can be written into the cache before filling up. let available = self.cache.capacity() - self.cache.len(); // If there is space available in the cache or if the buffer is empty, we can write data // into the cache. if available > 0 || buf.is_empty() { let n = cmp::min(available, buf.len()); let start = self.cache.len(); // Copy data from the buffer into the cache. unsafe { self.cache.set_len(start + n); } self.cache[start..start + n].copy_from_slice(&buf[..n]); // Mark the file as not flushed and switch to writing mode. self.is_flushed = false; self.mode = Mode::Writing; Poll::Ready(Ok(n)) } else { // Drain the write cache because it's full. futures_core::ready!(self.poll_drain(cx))?; Poll::Pending } } /// Drains the write cache. fn poll_drain(mut self, cx: &mut Context<'_>) -> Poll<io::Result<Self>> { // If an async operation has left a write error, return it now. if let Some(err) = self.last_write_err.take() { return Poll::Ready(Err(err)); } match self.mode { Mode::Idle | Mode::Reading(..) => Poll::Ready(Ok(self)), Mode::Writing => { // Register current task's interest in the file lock. self.register(cx); // Start a write operation asynchronously. spawn_blocking(move || { match (&*self.file).write_all(&self.cache) { Ok(_) => { // Switch to idle mode. self.cache.clear(); self.mode = Mode::Idle; } Err(err) => { // Save the error. self.last_write_err = Some(err); } }; }); Poll::Pending } } } /// Flushes the write cache into the file. fn poll_flush(mut self, cx: &mut Context<'_>) -> Poll<io::Result<Self>> { // If the file is already in flushed state, return. if self.is_flushed { return Poll::Ready(Ok(self)); } // If there is data in the write cache, drain it. self = futures_core::ready!(self.poll_drain(cx))?; // Register current task's interest in the file lock. self.register(cx); // Start a flush operation asynchronously. spawn_blocking(move || { match (&*self.file).flush() { Ok(()) => { // Mark the file as flushed. self.is_flushed = true; } Err(err) => { // Save the error. self.last_write_err = Some(err); } } }); Poll::Pending } // This function does nothing because we're not sure about `AsyncWrite::poll_close()`'s exact // semantics nor whether it will stay in the `AsyncWrite` trait. fn poll_close(self, _: &mut Context<'_>) -> Poll<io::Result<()>> { Poll::Ready(Ok(())) } } #[cfg(test)] mod tests { use super::*; #[test] fn async_file_drop() { crate::task::block_on(async move { File::open(file!()).await.unwrap(); }); } }