use crate::block_on_dummy_executor; #[cfg(not(windows))] use io_lifetimes::AsFd; #[cfg(windows)] use io_lifetimes::{AsHandle, BorrowedHandle}; use std::any::Any; use std::io; use wasi_common::{ file::{Advice, FdFlags, FileType, Filestat, WasiFile}, Error, }; pub struct File(wasi_cap_std_sync::file::File); impl File { pub(crate) fn from_inner(file: wasi_cap_std_sync::file::File) -> Self { File(file) } pub fn from_cap_std(file: cap_std::fs::File) -> Self { Self::from_inner(wasi_cap_std_sync::file::File::from_cap_std(file)) } } pub struct Stdin(wasi_cap_std_sync::stdio::Stdin); pub fn stdin() -> Stdin { Stdin(wasi_cap_std_sync::stdio::stdin()) } pub struct Stdout(wasi_cap_std_sync::stdio::Stdout); pub fn stdout() -> Stdout { Stdout(wasi_cap_std_sync::stdio::stdout()) } pub struct Stderr(wasi_cap_std_sync::stdio::Stderr); pub fn stderr() -> Stderr { Stderr(wasi_cap_std_sync::stdio::stderr()) } macro_rules! wasi_file_impl { ($ty:ty) => { #[wiggle::async_trait] impl WasiFile for $ty { fn as_any(&self) -> &dyn Any { self } async fn datasync(&self) -> Result<(), Error> { block_on_dummy_executor(|| self.0.datasync()) } async fn sync(&self) -> Result<(), Error> { block_on_dummy_executor(|| self.0.sync()) } async fn get_filetype(&self) -> Result { block_on_dummy_executor(|| self.0.get_filetype()) } async fn get_fdflags(&self) -> Result { block_on_dummy_executor(|| self.0.get_fdflags()) } async fn set_fdflags(&mut self, fdflags: FdFlags) -> Result<(), Error> { block_on_dummy_executor(|| self.0.set_fdflags(fdflags)) } async fn get_filestat(&self) -> Result { block_on_dummy_executor(|| self.0.get_filestat()) } async fn set_filestat_size(&self, size: u64) -> Result<(), Error> { block_on_dummy_executor(move || self.0.set_filestat_size(size)) } async fn advise(&self, offset: u64, len: u64, advice: Advice) -> Result<(), Error> { block_on_dummy_executor(move || self.0.advise(offset, len, advice)) } async fn allocate(&self, offset: u64, len: u64) -> Result<(), Error> { block_on_dummy_executor(move || self.0.allocate(offset, len)) } async fn read_vectored<'a>( &self, bufs: &mut [io::IoSliceMut<'a>], ) -> Result { block_on_dummy_executor(move || self.0.read_vectored(bufs)) } async fn read_vectored_at<'a>( &self, bufs: &mut [io::IoSliceMut<'a>], offset: u64, ) -> Result { block_on_dummy_executor(move || self.0.read_vectored_at(bufs, offset)) } async fn write_vectored<'a>(&self, bufs: &[io::IoSlice<'a>]) -> Result { block_on_dummy_executor(move || self.0.write_vectored(bufs)) } async fn write_vectored_at<'a>( &self, bufs: &[io::IoSlice<'a>], offset: u64, ) -> Result { block_on_dummy_executor(move || self.0.write_vectored_at(bufs, offset)) } async fn seek(&self, pos: std::io::SeekFrom) -> Result { block_on_dummy_executor(move || self.0.seek(pos)) } async fn peek(&self, buf: &mut [u8]) -> Result { block_on_dummy_executor(move || self.0.peek(buf)) } async fn set_times( &self, atime: Option, mtime: Option, ) -> Result<(), Error> { block_on_dummy_executor(move || self.0.set_times(atime, mtime)) } async fn num_ready_bytes(&self) -> Result { block_on_dummy_executor(|| self.0.num_ready_bytes()) } fn isatty(&self) -> bool { self.0.isatty() } #[cfg(not(windows))] async fn readable(&self) -> Result<(), Error> { // The Inner impls OwnsRaw, which asserts exclusive use of the handle by the owned object. // AsyncFd needs to wrap an owned `impl std::os::unix::io::AsRawFd`. Rather than introduce // mutability to let it own the `Inner`, we are depending on the `&mut self` bound on this // async method to ensure this is the only Future which can access the RawFd during the // lifetime of the AsyncFd. use std::os::unix::io::AsRawFd; use tokio::io::{unix::AsyncFd, Interest}; let rawfd = self.0.as_fd().as_raw_fd(); match AsyncFd::with_interest(rawfd, Interest::READABLE) { Ok(asyncfd) => { let _ = asyncfd.readable().await?; Ok(()) } Err(e) if e.kind() == std::io::ErrorKind::PermissionDenied => { // if e is EPERM, this file isnt supported by epoll because it is immediately // available for reading: Ok(()) } Err(e) => Err(e.into()), } } #[cfg(windows)] async fn readable(&self) -> Result<(), Error> { // Windows uses a rawfd based scheduler :( use wasi_common::ErrorExt; Err(Error::badf()) } #[cfg(not(windows))] async fn writable(&self) -> Result<(), Error> { // The Inner impls OwnsRaw, which asserts exclusive use of the handle by the owned object. // AsyncFd needs to wrap an owned `impl std::os::unix::io::AsRawFd`. Rather than introduce // mutability to let it own the `Inner`, we are depending on the `&mut self` bound on this // async method to ensure this is the only Future which can access the RawFd during the // lifetime of the AsyncFd. use std::os::unix::io::AsRawFd; use tokio::io::{unix::AsyncFd, Interest}; let rawfd = self.0.as_fd().as_raw_fd(); match AsyncFd::with_interest(rawfd, Interest::WRITABLE) { Ok(asyncfd) => { let _ = asyncfd.writable().await?; Ok(()) } Err(e) if e.kind() == std::io::ErrorKind::PermissionDenied => { // if e is EPERM, this file isnt supported by epoll because it is immediately // available for writing: Ok(()) } Err(e) => Err(e.into()), } } #[cfg(windows)] async fn writable(&self) -> Result<(), Error> { // Windows uses a rawfd based scheduler :( use wasi_common::ErrorExt; Err(Error::badf()) } } #[cfg(windows)] impl AsHandle for $ty { fn as_handle(&self) -> BorrowedHandle<'_> { self.0.as_handle() } } }; } wasi_file_impl!(File); wasi_file_impl!(Stdin); wasi_file_impl!(Stdout); wasi_file_impl!(Stderr);