//! Vectored I/O use crate::Result; use crate::errno::Errno; use libc::{self, c_int, c_void, size_t, off_t}; use std::marker::PhantomData; use std::os::unix::io::RawFd; /// Low-level vectored write to a raw file descriptor /// /// See also [writev(2)](https://pubs.opengroup.org/onlinepubs/9699919799/functions/writev.html) pub fn writev(fd: RawFd, iov: &[IoVec<&[u8]>]) -> Result { let res = unsafe { libc::writev(fd, iov.as_ptr() as *const libc::iovec, iov.len() as c_int) }; Errno::result(res).map(|r| r as usize) } /// Low-level vectored read from a raw file descriptor /// /// See also [readv(2)](https://pubs.opengroup.org/onlinepubs/9699919799/functions/readv.html) pub fn readv(fd: RawFd, iov: &mut [IoVec<&mut [u8]>]) -> Result { let res = unsafe { libc::readv(fd, iov.as_ptr() as *const libc::iovec, iov.len() as c_int) }; Errno::result(res).map(|r| r as usize) } /// Write to `fd` at `offset` from buffers in `iov`. /// /// Buffers in `iov` will be written in order until all buffers have been written /// or an error occurs. The file offset is not changed. /// /// See also: [`writev`](fn.writev.html) and [`pwrite`](fn.pwrite.html) #[cfg(not(target_os = "redox"))] #[cfg_attr(docsrs, doc(cfg(all())))] pub fn pwritev(fd: RawFd, iov: &[IoVec<&[u8]>], offset: off_t) -> Result { #[cfg(target_env = "uclibc")] let offset = offset as libc::off64_t; // uclibc doesn't use off_t let res = unsafe { libc::pwritev(fd, iov.as_ptr() as *const libc::iovec, iov.len() as c_int, offset) }; Errno::result(res).map(|r| r as usize) } /// Read from `fd` at `offset` filling buffers in `iov`. /// /// Buffers in `iov` will be filled in order until all buffers have been filled, /// no more bytes are available, or an error occurs. The file offset is not /// changed. /// /// See also: [`readv`](fn.readv.html) and [`pread`](fn.pread.html) #[cfg(not(target_os = "redox"))] #[cfg_attr(docsrs, doc(cfg(all())))] pub fn preadv(fd: RawFd, iov: &[IoVec<&mut [u8]>], offset: off_t) -> Result { #[cfg(target_env = "uclibc")] let offset = offset as libc::off64_t; // uclibc doesn't use off_t let res = unsafe { libc::preadv(fd, iov.as_ptr() as *const libc::iovec, iov.len() as c_int, offset) }; Errno::result(res).map(|r| r as usize) } /// Low-level write to a file, with specified offset. /// /// See also [pwrite(2)](https://pubs.opengroup.org/onlinepubs/9699919799/functions/pwrite.html) // TODO: move to unistd pub fn pwrite(fd: RawFd, buf: &[u8], offset: off_t) -> Result { let res = unsafe { libc::pwrite(fd, buf.as_ptr() as *const c_void, buf.len() as size_t, offset) }; Errno::result(res).map(|r| r as usize) } /// Low-level write to a file, with specified offset. /// /// See also [pread(2)](https://pubs.opengroup.org/onlinepubs/9699919799/functions/pread.html) // TODO: move to unistd pub fn pread(fd: RawFd, buf: &mut [u8], offset: off_t) -> Result{ let res = unsafe { libc::pread(fd, buf.as_mut_ptr() as *mut c_void, buf.len() as size_t, offset) }; Errno::result(res).map(|r| r as usize) } /// A slice of memory in a remote process, starting at address `base` /// and consisting of `len` bytes. /// /// This is the same underlying C structure as [`IoVec`](struct.IoVec.html), /// except that it refers to memory in some other process, and is /// therefore not represented in Rust by an actual slice as `IoVec` is. It /// is used with [`process_vm_readv`](fn.process_vm_readv.html) /// and [`process_vm_writev`](fn.process_vm_writev.html). #[cfg(target_os = "linux")] #[cfg_attr(docsrs, doc(cfg(all())))] #[repr(C)] #[derive(Clone, Copy, Debug, Eq, Hash, PartialEq)] pub struct RemoteIoVec { /// The starting address of this slice (`iov_base`). pub base: usize, /// The number of bytes in this slice (`iov_len`). pub len: usize, } feature! { #![feature = "process"] /// Write data directly to another process's virtual memory /// (see [`process_vm_writev`(2)]). /// /// `local_iov` is a list of [`IoVec`]s containing the data to be written, /// and `remote_iov` is a list of [`RemoteIoVec`]s identifying where the /// data should be written in the target process. On success, returns the /// number of bytes written, which will always be a whole /// number of `remote_iov` chunks. /// /// This requires the same permissions as debugging the process using /// [ptrace]: you must either be a privileged process (with /// `CAP_SYS_PTRACE`), or you must be running as the same user as the /// target process and the OS must have unprivileged debugging enabled. /// /// This function is only available on Linux. /// /// [`process_vm_writev`(2)]: https://man7.org/linux/man-pages/man2/process_vm_writev.2.html /// [ptrace]: ../ptrace/index.html /// [`IoVec`]: struct.IoVec.html /// [`RemoteIoVec`]: struct.RemoteIoVec.html #[cfg(all(target_os = "linux", not(target_env = "uclibc")))] pub fn process_vm_writev( pid: crate::unistd::Pid, local_iov: &[IoVec<&[u8]>], remote_iov: &[RemoteIoVec]) -> Result { let res = unsafe { libc::process_vm_writev(pid.into(), local_iov.as_ptr() as *const libc::iovec, local_iov.len() as libc::c_ulong, remote_iov.as_ptr() as *const libc::iovec, remote_iov.len() as libc::c_ulong, 0) }; Errno::result(res).map(|r| r as usize) } /// Read data directly from another process's virtual memory /// (see [`process_vm_readv`(2)]). /// /// `local_iov` is a list of [`IoVec`]s containing the buffer to copy /// data into, and `remote_iov` is a list of [`RemoteIoVec`]s identifying /// where the source data is in the target process. On success, /// returns the number of bytes written, which will always be a whole /// number of `remote_iov` chunks. /// /// This requires the same permissions as debugging the process using /// [`ptrace`]: you must either be a privileged process (with /// `CAP_SYS_PTRACE`), or you must be running as the same user as the /// target process and the OS must have unprivileged debugging enabled. /// /// This function is only available on Linux. /// /// [`process_vm_readv`(2)]: https://man7.org/linux/man-pages/man2/process_vm_readv.2.html /// [`ptrace`]: ../ptrace/index.html /// [`IoVec`]: struct.IoVec.html /// [`RemoteIoVec`]: struct.RemoteIoVec.html #[cfg(all(target_os = "linux", not(target_env = "uclibc")))] pub fn process_vm_readv( pid: crate::unistd::Pid, local_iov: &[IoVec<&mut [u8]>], remote_iov: &[RemoteIoVec]) -> Result { let res = unsafe { libc::process_vm_readv(pid.into(), local_iov.as_ptr() as *const libc::iovec, local_iov.len() as libc::c_ulong, remote_iov.as_ptr() as *const libc::iovec, remote_iov.len() as libc::c_ulong, 0) }; Errno::result(res).map(|r| r as usize) } } /// A vector of buffers. /// /// Vectored I/O methods like [`writev`] and [`readv`] use this structure for /// both reading and writing. Each `IoVec` specifies the base address and /// length of an area in memory. #[repr(transparent)] #[derive(Clone, Copy, Debug, Eq, Hash, PartialEq)] pub struct IoVec(pub(crate) libc::iovec, PhantomData); impl IoVec { /// View the `IoVec` as a Rust slice. #[inline] pub fn as_slice(&self) -> &[u8] { use std::slice; unsafe { slice::from_raw_parts( self.0.iov_base as *const u8, self.0.iov_len as usize) } } } impl<'a> IoVec<&'a [u8]> { #[cfg(all(feature = "mount", target_os = "freebsd"))] pub(crate) fn from_raw_parts(base: *mut c_void, len: usize) -> Self { IoVec(libc::iovec { iov_base: base, iov_len: len }, PhantomData) } /// Create an `IoVec` from a Rust slice. pub fn from_slice(buf: &'a [u8]) -> IoVec<&'a [u8]> { IoVec(libc::iovec { iov_base: buf.as_ptr() as *mut c_void, iov_len: buf.len() as size_t, }, PhantomData) } } impl<'a> IoVec<&'a mut [u8]> { /// Create an `IoVec` from a mutable Rust slice. pub fn from_mut_slice(buf: &'a mut [u8]) -> IoVec<&'a mut [u8]> { IoVec(libc::iovec { iov_base: buf.as_ptr() as *mut c_void, iov_len: buf.len() as size_t, }, PhantomData) } } // The only reason IoVec isn't automatically Send+Sync is because libc::iovec // contains raw pointers. unsafe impl Send for IoVec where T: Send {} unsafe impl Sync for IoVec where T: Sync {}