mirror of
https://github.com/cloud-hypervisor/cloud-hypervisor.git
synced 2024-11-09 05:10:07 +00:00
410 lines
16 KiB
Rust
410 lines
16 KiB
Rust
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// Copyright 2018 The Chromium OS Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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use std::fs::File;
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use std::io::{Error, ErrorKind, Result};
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use std::os::unix::io::AsRawFd;
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use vm_memory::VolatileSlice;
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use libc::{
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c_int, c_void, off64_t, pread64, preadv64, pwrite64, pwritev64, read, readv, size_t, write,
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writev,
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};
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/// A trait for setting the size of a file.
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/// This is equivalent to File's `set_len` method, but
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/// wrapped in a trait so that it can be implemented for
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/// other types.
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pub trait FileSetLen {
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// Set the size of this file.
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// This is the moral equivalent of `ftruncate()`.
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fn set_len(&self, _len: u64) -> Result<()>;
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}
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impl FileSetLen for File {
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fn set_len(&self, len: u64) -> Result<()> {
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File::set_len(self, len)
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}
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}
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/// A trait similar to `Read` and `Write`, but uses volatile memory as buffers.
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pub trait FileReadWriteVolatile {
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/// Read bytes from this file into the given slice, returning the number of bytes read on
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/// success.
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fn read_volatile(&mut self, slice: VolatileSlice) -> Result<usize>;
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/// Like `read_volatile`, except it reads to a slice of buffers. Data is copied to fill each
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/// buffer in order, with the final buffer written to possibly being only partially filled. This
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/// method must behave as a single call to `read_volatile` with the buffers concatenated would.
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/// The default implementation calls `read_volatile` with either the first nonempty buffer
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/// provided, or returns `Ok(0)` if none exists.
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fn read_vectored_volatile(&mut self, bufs: &[VolatileSlice]) -> Result<usize> {
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bufs.iter()
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.find(|b| !b.is_empty())
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.map(|&b| self.read_volatile(b))
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.unwrap_or(Ok(0))
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}
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/// Reads bytes from this into the given slice until all bytes in the slice are written, or an
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/// error is returned.
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fn read_exact_volatile(&mut self, mut slice: VolatileSlice) -> Result<()> {
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while !slice.is_empty() {
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let bytes_read = self.read_volatile(slice)?;
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if bytes_read == 0 {
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return Err(Error::from(ErrorKind::UnexpectedEof));
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}
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// Will panic if read_volatile read more bytes than we gave it, which would be worthy of
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// a panic.
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slice = slice.offset(bytes_read).unwrap();
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}
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Ok(())
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}
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/// Write bytes from the slice to the given file, returning the number of bytes written on
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/// success.
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fn write_volatile(&mut self, slice: VolatileSlice) -> Result<usize>;
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/// Like `write_volatile`, except that it writes from a slice of buffers. Data is copied from
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/// each buffer in order, with the final buffer read from possibly being only partially
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/// consumed. This method must behave as a call to `write_volatile` with the buffers
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/// concatenated would. The default implementation calls `write_volatile` with either the first
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/// nonempty buffer provided, or returns `Ok(0)` if none exists.
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fn write_vectored_volatile(&mut self, bufs: &[VolatileSlice]) -> Result<usize> {
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bufs.iter()
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.find(|b| !b.is_empty())
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.map(|&b| self.write_volatile(b))
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.unwrap_or(Ok(0))
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}
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/// Write bytes from the slice to the given file until all the bytes from the slice have been
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/// written, or an error is returned.
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fn write_all_volatile(&mut self, mut slice: VolatileSlice) -> Result<()> {
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while !slice.is_empty() {
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let bytes_written = self.write_volatile(slice)?;
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if bytes_written == 0 {
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return Err(Error::from(ErrorKind::WriteZero));
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}
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// Will panic if read_volatile read more bytes than we gave it, which would be worthy of
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// a panic.
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slice = slice.offset(bytes_written).unwrap();
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}
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Ok(())
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}
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}
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impl<'a, T: FileReadWriteVolatile + ?Sized> FileReadWriteVolatile for &'a mut T {
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fn read_volatile(&mut self, slice: VolatileSlice) -> Result<usize> {
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(**self).read_volatile(slice)
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}
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fn read_vectored_volatile(&mut self, bufs: &[VolatileSlice]) -> Result<usize> {
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(**self).read_vectored_volatile(bufs)
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}
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fn read_exact_volatile(&mut self, slice: VolatileSlice) -> Result<()> {
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(**self).read_exact_volatile(slice)
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}
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fn write_volatile(&mut self, slice: VolatileSlice) -> Result<usize> {
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(**self).write_volatile(slice)
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}
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fn write_vectored_volatile(&mut self, bufs: &[VolatileSlice]) -> Result<usize> {
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(**self).write_vectored_volatile(bufs)
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}
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fn write_all_volatile(&mut self, slice: VolatileSlice) -> Result<()> {
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(**self).write_all_volatile(slice)
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}
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}
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/// A trait similar to the unix `ReadExt` and `WriteExt` traits, but for volatile memory.
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pub trait FileReadWriteAtVolatile {
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/// Reads bytes from this file at `offset` into the given slice, returning the number of bytes
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/// read on success.
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fn read_at_volatile(&mut self, slice: VolatileSlice, offset: u64) -> Result<usize>;
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/// Like `read_at_volatile`, except it reads to a slice of buffers. Data is copied to fill each
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/// buffer in order, with the final buffer written to possibly being only partially filled. This
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/// method must behave as a single call to `read_at_volatile` with the buffers concatenated
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/// would. The default implementation calls `read_at_volatile` with either the first nonempty
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/// buffer provided, or returns `Ok(0)` if none exists.
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fn read_vectored_at_volatile(&mut self, bufs: &[VolatileSlice], offset: u64) -> Result<usize> {
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if let Some(&slice) = bufs.first() {
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self.read_at_volatile(slice, offset)
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} else {
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Ok(0)
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}
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}
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/// Reads bytes from this file at `offset` into the given slice until all bytes in the slice are
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/// read, or an error is returned.
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fn read_exact_at_volatile(&mut self, mut slice: VolatileSlice, mut offset: u64) -> Result<()> {
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while !slice.is_empty() {
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match self.read_at_volatile(slice, offset) {
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Ok(0) => return Err(Error::from(ErrorKind::UnexpectedEof)),
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Ok(n) => {
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slice = slice.offset(n).unwrap();
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offset = offset.checked_add(n as u64).unwrap();
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}
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Err(ref e) if e.kind() == ErrorKind::Interrupted => {}
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Err(e) => return Err(e),
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}
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}
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Ok(())
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}
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/// Writes bytes from this file at `offset` into the given slice, returning the number of bytes
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/// written on success.
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fn write_at_volatile(&mut self, slice: VolatileSlice, offset: u64) -> Result<usize>;
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/// Like `write_at_at_volatile`, except that it writes from a slice of buffers. Data is copied
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/// from each buffer in order, with the final buffer read from possibly being only partially
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/// consumed. This method must behave as a call to `write_at_volatile` with the buffers
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/// concatenated would. The default implementation calls `write_at_volatile` with either the
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/// first nonempty buffer provided, or returns `Ok(0)` if none exists.
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fn write_vectored_at_volatile(&mut self, bufs: &[VolatileSlice], offset: u64) -> Result<usize> {
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if let Some(&slice) = bufs.first() {
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self.write_at_volatile(slice, offset)
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} else {
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Ok(0)
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}
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}
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/// Writes bytes from this file at `offset` into the given slice until all bytes in the slice
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/// are written, or an error is returned.
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fn write_all_at_volatile(&mut self, mut slice: VolatileSlice, mut offset: u64) -> Result<()> {
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while !slice.is_empty() {
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match self.write_at_volatile(slice, offset) {
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Ok(0) => return Err(Error::from(ErrorKind::WriteZero)),
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Ok(n) => {
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slice = slice.offset(n).unwrap();
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offset = offset.checked_add(n as u64).unwrap();
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}
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Err(ref e) if e.kind() == ErrorKind::Interrupted => {}
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Err(e) => return Err(e),
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}
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}
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Ok(())
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}
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}
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impl<'a, T: FileReadWriteAtVolatile + ?Sized> FileReadWriteAtVolatile for &'a mut T {
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fn read_at_volatile(&mut self, slice: VolatileSlice, offset: u64) -> Result<usize> {
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(**self).read_at_volatile(slice, offset)
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}
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fn read_vectored_at_volatile(&mut self, bufs: &[VolatileSlice], offset: u64) -> Result<usize> {
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(**self).read_vectored_at_volatile(bufs, offset)
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}
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fn read_exact_at_volatile(&mut self, slice: VolatileSlice, offset: u64) -> Result<()> {
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(**self).read_exact_at_volatile(slice, offset)
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}
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fn write_at_volatile(&mut self, slice: VolatileSlice, offset: u64) -> Result<usize> {
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(**self).write_at_volatile(slice, offset)
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}
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fn write_vectored_at_volatile(&mut self, bufs: &[VolatileSlice], offset: u64) -> Result<usize> {
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(**self).write_vectored_at_volatile(bufs, offset)
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}
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fn write_all_at_volatile(&mut self, slice: VolatileSlice, offset: u64) -> Result<()> {
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(**self).write_all_at_volatile(slice, offset)
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}
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}
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macro_rules! volatile_impl {
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($ty:ty) => {
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impl FileReadWriteVolatile for $ty {
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fn read_volatile(&mut self, slice: VolatileSlice) -> Result<usize> {
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// Safe because only bytes inside the slice are accessed and the kernel is expected
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// to handle arbitrary memory for I/O.
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let ret =
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unsafe { read(self.as_raw_fd(), slice.as_ptr() as *mut c_void, slice.len()) };
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if ret >= 0 {
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Ok(ret as usize)
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} else {
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Err(Error::last_os_error())
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}
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}
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fn read_vectored_volatile(&mut self, bufs: &[VolatileSlice]) -> Result<usize> {
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let iovecs: Vec<libc::iovec> = bufs
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.iter()
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.map(|s| libc::iovec {
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iov_base: s.as_ptr() as *mut c_void,
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iov_len: s.len() as size_t,
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})
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.collect();
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if iovecs.is_empty() {
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return Ok(0);
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}
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// Safe because only bytes inside the buffers are accessed and the kernel is
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// expected to handle arbitrary memory for I/O.
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let ret = unsafe { readv(self.as_raw_fd(), &iovecs[0], iovecs.len() as c_int) };
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if ret >= 0 {
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Ok(ret as usize)
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} else {
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Err(Error::last_os_error())
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}
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}
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fn write_volatile(&mut self, slice: VolatileSlice) -> Result<usize> {
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// Safe because only bytes inside the slice are accessed and the kernel is expected
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// to handle arbitrary memory for I/O.
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let ret = unsafe {
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write(
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self.as_raw_fd(),
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slice.as_ptr() as *const c_void,
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slice.len(),
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)
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};
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if ret >= 0 {
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Ok(ret as usize)
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} else {
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Err(Error::last_os_error())
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}
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}
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fn write_vectored_volatile(&mut self, bufs: &[VolatileSlice]) -> Result<usize> {
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let iovecs: Vec<libc::iovec> = bufs
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.iter()
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.map(|s| libc::iovec {
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iov_base: s.as_ptr() as *mut c_void,
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iov_len: s.len() as size_t,
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})
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.collect();
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if iovecs.is_empty() {
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return Ok(0);
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}
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// Safe because only bytes inside the buffers are accessed and the kernel is
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// expected to handle arbitrary memory for I/O.
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let ret = unsafe { writev(self.as_raw_fd(), &iovecs[0], iovecs.len() as c_int) };
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if ret >= 0 {
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Ok(ret as usize)
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} else {
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Err(Error::last_os_error())
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}
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}
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}
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impl FileReadWriteAtVolatile for $ty {
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fn read_at_volatile(&mut self, slice: VolatileSlice, offset: u64) -> Result<usize> {
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// Safe because only bytes inside the slice are accessed and the kernel is expected
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// to handle arbitrary memory for I/O.
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let ret = unsafe {
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pread64(
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self.as_raw_fd(),
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slice.as_ptr() as *mut c_void,
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slice.len(),
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offset as off64_t,
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)
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};
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if ret >= 0 {
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Ok(ret as usize)
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} else {
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Err(Error::last_os_error())
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}
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}
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fn read_vectored_at_volatile(
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&mut self,
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bufs: &[VolatileSlice],
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offset: u64,
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) -> Result<usize> {
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let iovecs: Vec<libc::iovec> = bufs
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.iter()
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.map(|s| libc::iovec {
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iov_base: s.as_ptr() as *mut c_void,
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iov_len: s.len() as size_t,
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})
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.collect();
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if iovecs.is_empty() {
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return Ok(0);
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}
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// Safe because only bytes inside the buffers are accessed and the kernel is
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// expected to handle arbitrary memory for I/O.
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let ret = unsafe {
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preadv64(
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self.as_raw_fd(),
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&iovecs[0],
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iovecs.len() as c_int,
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offset as off64_t,
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)
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};
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if ret >= 0 {
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Ok(ret as usize)
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} else {
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Err(Error::last_os_error())
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}
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}
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fn write_at_volatile(&mut self, slice: VolatileSlice, offset: u64) -> Result<usize> {
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// Safe because only bytes inside the slice are accessed and the kernel is expected
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// to handle arbitrary memory for I/O.
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let ret = unsafe {
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pwrite64(
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self.as_raw_fd(),
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slice.as_ptr() as *const c_void,
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slice.len(),
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offset as off64_t,
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)
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};
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if ret >= 0 {
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Ok(ret as usize)
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} else {
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Err(Error::last_os_error())
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}
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}
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fn write_vectored_at_volatile(
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&mut self,
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bufs: &[VolatileSlice],
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offset: u64,
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) -> Result<usize> {
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let iovecs: Vec<libc::iovec> = bufs
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.iter()
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.map(|s| libc::iovec {
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iov_base: s.as_ptr() as *mut c_void,
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iov_len: s.len() as size_t,
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})
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.collect();
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if iovecs.is_empty() {
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return Ok(0);
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}
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// Safe because only bytes inside the buffers are accessed and the kernel is
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// expected to handle arbitrary memory for I/O.
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let ret = unsafe {
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pwritev64(
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self.as_raw_fd(),
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&iovecs[0],
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iovecs.len() as c_int,
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offset as off64_t,
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)
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};
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if ret >= 0 {
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Ok(ret as usize)
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} else {
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Err(Error::last_os_error())
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}
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}
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}
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};
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}
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volatile_impl!(File);
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