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denoland-deno/ext/io/bi_pipe.rs

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// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
use std::rc::Rc;
use deno_core::AsyncRefCell;
use deno_core::AsyncResult;
use deno_core::CancelHandle;
use deno_core::CancelTryFuture;
use deno_core::RcRef;
use tokio::io::AsyncReadExt;
use tokio::io::AsyncWriteExt;
pub type RawBiPipeHandle = super::RawIoHandle;
/// One end of a bidirectional pipe. This implements the
/// `Resource` trait.
pub struct BiPipeResource {
read_half: AsyncRefCell<BiPipeRead>,
write_half: AsyncRefCell<BiPipeWrite>,
cancel: CancelHandle,
raw_handle: RawBiPipeHandle,
}
#[cfg(windows)]
// workaround because `RawHandle` doesn't impl `AsRawHandle`
mod as_raw_handle {
use super::RawBiPipeHandle;
pub(super) struct RawHandleWrap(pub(super) RawBiPipeHandle);
impl std::os::windows::io::AsRawHandle for RawHandleWrap {
fn as_raw_handle(&self) -> std::os::windows::prelude::RawHandle {
self.0
}
}
}
impl deno_core::Resource for BiPipeResource {
fn close(self: Rc<Self>) {
self.cancel.cancel();
}
fn backing_handle(self: Rc<Self>) -> Option<deno_core::ResourceHandle> {
#[cfg(unix)]
{
Some(deno_core::ResourceHandle::from_fd_like(&self.raw_handle))
}
#[cfg(windows)]
{
Some(deno_core::ResourceHandle::from_fd_like(
&as_raw_handle::RawHandleWrap(self.raw_handle),
))
}
}
deno_core::impl_readable_byob!();
deno_core::impl_writable!();
}
impl BiPipeResource {
pub fn from_raw_handle(raw: RawBiPipeHandle) -> Result<Self, std::io::Error> {
let pipe = BiPipe::from_raw(raw)?;
let (read, write) = pipe.split();
Ok(Self {
raw_handle: raw,
read_half: AsyncRefCell::new(read),
write_half: AsyncRefCell::new(write),
cancel: Default::default(),
})
}
pub async fn read(
self: Rc<Self>,
data: &mut [u8],
) -> Result<usize, std::io::Error> {
let mut rd = RcRef::map(&self, |r| &r.read_half).borrow_mut().await;
let cancel_handle = RcRef::map(&self, |r| &r.cancel);
rd.read(data).try_or_cancel(cancel_handle).await
}
pub async fn write(
self: Rc<Self>,
data: &[u8],
) -> Result<usize, std::io::Error> {
let mut wr = RcRef::map(self, |r| &r.write_half).borrow_mut().await;
let nwritten = wr.write(data).await?;
wr.flush().await?;
Ok(nwritten)
}
}
/// One end of a bidirectional pipe
#[pin_project::pin_project]
pub struct BiPipe {
#[pin]
read_end: BiPipeRead,
#[pin]
write_end: BiPipeWrite,
}
impl BiPipe {
pub fn from_raw(raw: RawBiPipeHandle) -> Result<Self, std::io::Error> {
let (read_end, write_end) = from_raw(raw)?;
Ok(Self {
read_end,
write_end,
})
}
pub fn split(self) -> (BiPipeRead, BiPipeWrite) {
(self.read_end, self.write_end)
}
pub fn unsplit(read_end: BiPipeRead, write_end: BiPipeWrite) -> Self {
Self {
read_end,
write_end,
}
}
}
#[pin_project::pin_project]
pub struct BiPipeRead {
#[cfg(unix)]
#[pin]
inner: tokio::net::unix::OwnedReadHalf,
#[cfg(windows)]
#[pin]
inner: tokio::io::ReadHalf<tokio::net::windows::named_pipe::NamedPipeClient>,
}
#[cfg(unix)]
impl From<tokio::net::unix::OwnedReadHalf> for BiPipeRead {
fn from(value: tokio::net::unix::OwnedReadHalf) -> Self {
Self { inner: value }
}
}
#[cfg(windows)]
impl From<tokio::io::ReadHalf<tokio::net::windows::named_pipe::NamedPipeClient>>
for BiPipeRead
{
fn from(
value: tokio::io::ReadHalf<
tokio::net::windows::named_pipe::NamedPipeClient,
>,
) -> Self {
Self { inner: value }
}
}
#[pin_project::pin_project]
pub struct BiPipeWrite {
#[cfg(unix)]
#[pin]
inner: tokio::net::unix::OwnedWriteHalf,
#[cfg(windows)]
#[pin]
inner: tokio::io::WriteHalf<tokio::net::windows::named_pipe::NamedPipeClient>,
}
#[cfg(unix)]
impl From<tokio::net::unix::OwnedWriteHalf> for BiPipeWrite {
fn from(value: tokio::net::unix::OwnedWriteHalf) -> Self {
Self { inner: value }
}
}
#[cfg(windows)]
impl
From<tokio::io::WriteHalf<tokio::net::windows::named_pipe::NamedPipeClient>>
for BiPipeWrite
{
fn from(
value: tokio::io::WriteHalf<
tokio::net::windows::named_pipe::NamedPipeClient,
>,
) -> Self {
Self { inner: value }
}
}
#[cfg(unix)]
fn from_raw(
stream: RawBiPipeHandle,
) -> Result<(BiPipeRead, BiPipeWrite), std::io::Error> {
use std::os::fd::FromRawFd;
// Safety: The fd is part of a pair of connected sockets
let unix_stream =
unsafe { std::os::unix::net::UnixStream::from_raw_fd(stream) };
unix_stream.set_nonblocking(true)?;
let unix_stream = tokio::net::UnixStream::from_std(unix_stream)?;
let (read, write) = unix_stream.into_split();
Ok((BiPipeRead { inner: read }, BiPipeWrite { inner: write }))
}
#[cfg(windows)]
fn from_raw(
handle: RawBiPipeHandle,
) -> Result<(BiPipeRead, BiPipeWrite), std::io::Error> {
// Safety: We cannot use `get_osfhandle` because Deno statically links to msvcrt. It is not guaranteed that the
// fd handle map will be the same.
let pipe = unsafe {
tokio::net::windows::named_pipe::NamedPipeClient::from_raw_handle(
handle as _,
)?
};
let (read, write) = tokio::io::split(pipe);
Ok((BiPipeRead { inner: read }, BiPipeWrite { inner: write }))
}
impl tokio::io::AsyncRead for BiPipeRead {
fn poll_read(
self: std::pin::Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
buf: &mut tokio::io::ReadBuf<'_>,
) -> std::task::Poll<std::io::Result<()>> {
self.project().inner.poll_read(cx, buf)
}
}
impl tokio::io::AsyncRead for BiPipe {
fn poll_read(
self: std::pin::Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
buf: &mut tokio::io::ReadBuf<'_>,
) -> std::task::Poll<std::io::Result<()>> {
self.project().read_end.poll_read(cx, buf)
}
}
// implement `AsyncWrite` for `$name`, delegating
// the impl to `$field`. `$name` must have a `project` method
// with a projected `$field` (e.g. with `pin_project::pin_project`)
macro_rules! impl_async_write {
(for $name: ident -> self.$field: ident) => {
impl tokio::io::AsyncWrite for $name {
fn poll_write_vectored(
self: std::pin::Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
bufs: &[std::io::IoSlice<'_>],
) -> std::task::Poll<Result<usize, std::io::Error>> {
self.project().$field.poll_write_vectored(cx, bufs)
}
fn is_write_vectored(&self) -> bool {
self.$field.is_write_vectored()
}
fn poll_write(
self: std::pin::Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
buf: &[u8],
) -> std::task::Poll<Result<usize, std::io::Error>> {
self.project().$field.poll_write(cx, buf)
}
fn poll_flush(
self: std::pin::Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
) -> std::task::Poll<Result<(), std::io::Error>> {
self.project().$field.poll_flush(cx)
}
fn poll_shutdown(
self: std::pin::Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
) -> std::task::Poll<Result<(), std::io::Error>> {
self.project().$field.poll_shutdown(cx)
}
}
};
}
impl_async_write!(for BiPipeWrite -> self.inner);
impl_async_write!(for BiPipe -> self.write_end);
/// Creates both sides of a bidirectional pipe, returning the raw
/// handles to the underlying OS resources.
pub fn bi_pipe_pair_raw(
) -> Result<(RawBiPipeHandle, RawBiPipeHandle), std::io::Error> {
#[cfg(unix)]
{
// SockFlag is broken on macOS
// https://github.com/nix-rust/nix/issues/861
let mut fds = [-1, -1];
#[cfg(not(target_os = "macos"))]
let flags = libc::SOCK_CLOEXEC;
#[cfg(target_os = "macos")]
let flags = 0;
// SAFETY: libc call, fds are correct size+align
let ret = unsafe {
libc::socketpair(
libc::AF_UNIX,
libc::SOCK_STREAM | flags,
0,
fds.as_mut_ptr(),
)
};
if ret != 0 {
return Err(std::io::Error::last_os_error());
}
if cfg!(target_os = "macos") {
let fcntl = |fd: i32, flag: libc::c_int| -> Result<(), std::io::Error> {
// SAFETY: libc call, fd is valid
let flags = unsafe { libc::fcntl(fd, libc::F_GETFD) };
if flags == -1 {
return Err(fail(fds));
}
// SAFETY: libc call, fd is valid
let ret = unsafe { libc::fcntl(fd, libc::F_SETFD, flags | flag) };
if ret == -1 {
return Err(fail(fds));
}
Ok(())
};
fn fail(fds: [i32; 2]) -> std::io::Error {
// SAFETY: libc call, fds are valid
unsafe {
libc::close(fds[0]);
libc::close(fds[1]);
}
std::io::Error::last_os_error()
}
// SOCK_CLOEXEC is not supported on macOS.
fcntl(fds[0], libc::FD_CLOEXEC)?;
fcntl(fds[1], libc::FD_CLOEXEC)?;
}
let fd1 = fds[0];
let fd2 = fds[1];
Ok((fd1, fd2))
}
#[cfg(windows)]
{
// TODO(nathanwhit): more granular unsafe blocks
// SAFETY: win32 calls
unsafe {
use windows_sys::Win32::Foundation::CloseHandle;
use windows_sys::Win32::Foundation::ERROR_ACCESS_DENIED;
use windows_sys::Win32::Foundation::ERROR_PIPE_CONNECTED;
use windows_sys::Win32::Foundation::GENERIC_READ;
use windows_sys::Win32::Foundation::GENERIC_WRITE;
use windows_sys::Win32::Foundation::INVALID_HANDLE_VALUE;
use windows_sys::Win32::Security::SECURITY_ATTRIBUTES;
use windows_sys::Win32::Storage::FileSystem::CreateFileW;
use windows_sys::Win32::Storage::FileSystem::FILE_FLAG_FIRST_PIPE_INSTANCE;
use windows_sys::Win32::Storage::FileSystem::FILE_FLAG_OVERLAPPED;
use windows_sys::Win32::Storage::FileSystem::OPEN_EXISTING;
use windows_sys::Win32::Storage::FileSystem::PIPE_ACCESS_DUPLEX;
use windows_sys::Win32::System::Pipes::ConnectNamedPipe;
use windows_sys::Win32::System::Pipes::CreateNamedPipeW;
use windows_sys::Win32::System::Pipes::PIPE_READMODE_BYTE;
use windows_sys::Win32::System::Pipes::PIPE_TYPE_BYTE;
use std::io;
use std::os::windows::ffi::OsStrExt;
use std::path::Path;
use std::ptr;
let (path, hd1) = loop {
let name = format!("\\\\.\\pipe\\{}", uuid::Uuid::new_v4());
let mut path = Path::new(&name)
.as_os_str()
.encode_wide()
.collect::<Vec<_>>();
path.push(0);
let hd1 = CreateNamedPipeW(
path.as_ptr(),
PIPE_ACCESS_DUPLEX
| FILE_FLAG_FIRST_PIPE_INSTANCE
| FILE_FLAG_OVERLAPPED,
PIPE_TYPE_BYTE | PIPE_READMODE_BYTE,
1,
65536,
65536,
0,
std::ptr::null_mut(),
);
if hd1 == INVALID_HANDLE_VALUE {
let err = io::Error::last_os_error();
/* If the pipe name is already in use, try again. */
if err.raw_os_error() == Some(ERROR_ACCESS_DENIED as i32) {
continue;
}
return Err(err);
}
break (path, hd1);
};
/* Create child pipe handle. */
let s = SECURITY_ATTRIBUTES {
nLength: std::mem::size_of::<SECURITY_ATTRIBUTES>() as u32,
lpSecurityDescriptor: ptr::null_mut(),
bInheritHandle: 1,
};
let hd2 = CreateFileW(
path.as_ptr(),
GENERIC_READ | GENERIC_WRITE,
0,
&s,
OPEN_EXISTING,
FILE_FLAG_OVERLAPPED,
0,
);
if hd2 == INVALID_HANDLE_VALUE {
return Err(io::Error::last_os_error());
}
// Will not block because we have create the pair.
if ConnectNamedPipe(hd1, ptr::null_mut()) == 0 {
let err = std::io::Error::last_os_error();
if err.raw_os_error() != Some(ERROR_PIPE_CONNECTED as i32) {
CloseHandle(hd2);
return Err(err);
}
}
Ok((hd1 as _, hd2 as _))
}
}
}