src/linux/write_zeroes.rs - platform/external/rust/crates/vmm-sys-util - Git at Google

 // Copyright 2020 Amazon.com, Inc. or its affiliates. All Rights Reserved.
 //
 // Copyright 2019 Intel Corporation. All Rights Reserved.
 //
 // Copyright 2018 The Chromium OS Authors. All rights reserved.
 //
 // SPDX-License-Identifier: BSD-3-Clause

 //! Traits for replacing a range with a hole and writing zeroes in a file.

 use std::cmp::min;
 use std::fs::File;
 use std::io::{Error, ErrorKind, Result, Seek, SeekFrom};
 use std::os::unix::fs::FileExt;

 use crate::fallocate::{fallocate, FallocateMode};

 /// A trait for deallocating space in a file.
 pub trait PunchHole {
     /// Replace a range of bytes with a hole.
     ///
     /// # Arguments
     ///
     /// * `offset`: offset of the file where to replace with a hole.
     /// * `length`: the number of bytes of the hole to replace with.
     fn punch_hole(&mut self, offset: u64, length: u64) -> Result<()>;
 }

 impl PunchHole for File {
     fn punch_hole(&mut self, offset: u64, length: u64) -> Result<()> {
         fallocate(self, FallocateMode::PunchHole, true, offset, length)
             .map_err(|e| Error::from_raw_os_error(e.errno()))
     }
 }

 /// A trait for writing zeroes to a stream.
 pub trait WriteZeroes {
     /// Write up to `length` bytes of zeroes to the stream, returning how many bytes were written.
     ///
     /// # Arguments
     ///
     /// * `length`: the number of bytes of zeroes to write to the stream.
     fn write_zeroes(&mut self, length: usize) -> Result<usize>;

     /// Write zeroes to the stream until `length` bytes have been written.
     ///
     /// This method will continuously write zeroes until the requested `length` is satisfied or an
     /// unrecoverable error is encountered.
     ///
     /// # Arguments
     ///
     /// * `length`: the exact number of bytes of zeroes to write to the stream.
     fn write_all_zeroes(&mut self, mut length: usize) -> Result<()> {
         while length > 0 {
             match self.write_zeroes(length) {
                 Ok(0) => return Err(Error::from(ErrorKind::WriteZero)),
                 Ok(bytes_written) => {
                     length = length
                         .checked_sub(bytes_written)
                         .ok_or_else(|| Error::from(ErrorKind::Other))?
                 }
                 // If the operation was interrupted, we should retry it.
                 Err(e) => {
                     if e.kind() != ErrorKind::Interrupted {
                         return Err(e);
                     }
                 }
             }
         }
         Ok(())
     }
 }

 /// A trait for writing zeroes to an arbitrary position in a file.
 pub trait WriteZeroesAt {
     /// Write up to `length` bytes of zeroes starting at `offset`, returning how many bytes were
     /// written.
     ///
     /// # Arguments
     ///
     /// * `offset`: offset of the file where to write zeroes.
     /// * `length`: the number of bytes of zeroes to write to the stream.
     fn write_zeroes_at(&mut self, offset: u64, length: usize) -> Result<usize>;

     /// Write zeroes starting at `offset` until `length` bytes have been written.
     ///
     /// This method will continuously write zeroes until the requested `length` is satisfied or an
     /// unrecoverable error is encountered.
     ///
     /// # Arguments
     ///
     /// * `offset`: offset of the file where to write zeroes.
     /// * `length`: the exact number of bytes of zeroes to write to the stream.
     fn write_all_zeroes_at(&mut self, mut offset: u64, mut length: usize) -> Result<()> {
         while length > 0 {
             match self.write_zeroes_at(offset, length) {
                 Ok(0) => return Err(Error::from(ErrorKind::WriteZero)),
                 Ok(bytes_written) => {
                     length = length
                         .checked_sub(bytes_written)
                         .ok_or_else(|| Error::from(ErrorKind::Other))?;
                     offset = offset
                         .checked_add(bytes_written as u64)
                         .ok_or_else(|| Error::from(ErrorKind::Other))?;
                 }
                 Err(e) => {
                     // If the operation was interrupted, we should retry it.
                     if e.kind() != ErrorKind::Interrupted {
                         return Err(e);
                     }
                 }
             }
         }
         Ok(())
     }
 }

 impl WriteZeroesAt for File {
     fn write_zeroes_at(&mut self, offset: u64, length: usize) -> Result<usize> {
         // Try to use fallocate() first, since it is more efficient than writing zeroes with
         // write().
         if fallocate(self, FallocateMode::ZeroRange, true, offset, length as u64).is_ok() {
             return Ok(length);
         }

         // Fall back to write().
         // fallocate() failed; fall back to writing a buffer of zeroes until we have written up
         // to `length`.
         let buf_size = min(length, 0x10000);
         let buf = vec![0u8; buf_size];
         let mut num_written: usize = 0;
         while num_written < length {
             let remaining = length - num_written;
             let write_size = min(remaining, buf_size);
             num_written += self.write_at(&buf[0..write_size], offset + num_written as u64)?;
         }
         Ok(length)
     }
 }

 impl<T: WriteZeroesAt + Seek> WriteZeroes for T {
     fn write_zeroes(&mut self, length: usize) -> Result<usize> {
         let offset = self.stream_position()?;
         let num_written = self.write_zeroes_at(offset, length)?;
         // Advance the seek cursor as if we had done a real write().
         self.seek(SeekFrom::Current(num_written as i64))?;
         Ok(length)
     }
 }

 #[cfg(test)]
 mod tests {
     use super::*;

     use std::io::{Read, Seek, SeekFrom, Write};

     use crate::tempfile::TempFile;

     #[test]
     fn test_small_write_zeroes() {
         const NON_ZERO_VALUE: u8 = 0x55;
         const BUF_SIZE: usize = 5678;

         let mut f = TempFile::new().unwrap().into_file();
         f.set_len(16384).unwrap();

         // Write buffer of non-zero bytes to offset 1234.
         let orig_data = [NON_ZERO_VALUE; BUF_SIZE];
         f.seek(SeekFrom::Start(1234)).unwrap();
         f.write_all(&orig_data).unwrap();

         // Read back the data plus some overlap on each side.
         let mut readback = [0u8; 16384];
         f.rewind().unwrap();
         f.read_exact(&mut readback).unwrap();
         // Bytes before the write should still be 0.
         for read in &readback[0..1234] {
             assert_eq!(*read, 0);
         }
         // Bytes that were just written should have `NON_ZERO_VALUE` value.
         for read in &readback[1234..(1234 + BUF_SIZE)] {
             assert_eq!(*read, NON_ZERO_VALUE);
         }
         // Bytes after the written area should still be 0.
         for read in &readback[(1234 + BUF_SIZE)..] {
             assert_eq!(*read, 0);
         }

         // Overwrite some of the data with zeroes.
         f.seek(SeekFrom::Start(2345)).unwrap();
         f.write_all_zeroes(4321).unwrap();
         // Verify seek position after `write_all_zeroes()`.
         assert_eq!(f.stream_position().unwrap(), 2345 + 4321);

         // Read back the data and verify that it is now zero.
         f.rewind().unwrap();
         f.read_exact(&mut readback).unwrap();
         // Bytes before the write should still be 0.
         for read in &readback[0..1234] {
             assert_eq!(*read, 0);
         }
         // Original data should still exist before the zeroed region.
         for read in &readback[1234..2345] {
             assert_eq!(*read, NON_ZERO_VALUE);
         }
         // Verify that `write_all_zeroes()` zeroed the intended region.
         for read in &readback[2345..(2345 + 4321)] {
             assert_eq!(*read, 0);
         }
         // Original data should still exist after the zeroed region.
         for read in &readback[(2345 + 4321)..(1234 + BUF_SIZE)] {
             assert_eq!(*read, NON_ZERO_VALUE);
         }
         // The rest of the file should still be 0.
         for read in &readback[(1234 + BUF_SIZE)..] {
             assert_eq!(*read, 0);
         }
     }

     #[test]
     fn test_large_write_zeroes() {
         const NON_ZERO_VALUE: u8 = 0x55;
         const SIZE: usize = 0x2_0000;

         let mut f = TempFile::new().unwrap().into_file();
         f.set_len(16384).unwrap();

         // Write buffer of non-zero bytes. The size of the buffer will be the new
         // size of the file.
         let orig_data = [NON_ZERO_VALUE; SIZE];
         f.rewind().unwrap();
         f.write_all(&orig_data).unwrap();
         assert_eq!(f.metadata().unwrap().len(), SIZE as u64);

         // Overwrite some of the data with zeroes.
         f.rewind().unwrap();
         f.write_all_zeroes(0x1_0001).unwrap();
         // Verify seek position after `write_all_zeroes()`.
         assert_eq!(f.stream_position().unwrap(), 0x1_0001);

         // Read back the data and verify that it is now zero.
         let mut readback = [0u8; SIZE];
         f.rewind().unwrap();
         f.read_exact(&mut readback).unwrap();
         // Verify that `write_all_zeroes()` zeroed the intended region.
         for read in &readback[0..0x1_0001] {
             assert_eq!(*read, 0);
         }
         // Original data should still exist after the zeroed region.
         for read in &readback[0x1_0001..SIZE] {
             assert_eq!(*read, NON_ZERO_VALUE);
         }

         // Now let's zero a certain region by using `write_all_zeroes_at()`.
         f.write_all_zeroes_at(0x1_8001, 0x200).unwrap();
         f.rewind().unwrap();
         f.read_exact(&mut readback).unwrap();

         // Original data should still exist before the zeroed region.
         for read in &readback[0x1_0001..0x1_8001] {
             assert_eq!(*read, NON_ZERO_VALUE);
         }
         // Verify that `write_all_zeroes_at()` zeroed the intended region.
         for read in &readback[0x1_8001..(0x1_8001 + 0x200)] {
             assert_eq!(*read, 0);
         }
         // Original data should still exist after the zeroed region.
         for read in &readback[(0x1_8001 + 0x200)..SIZE] {
             assert_eq!(*read, NON_ZERO_VALUE);
         }
     }

     #[test]
     fn test_punch_hole() {
         const NON_ZERO_VALUE: u8 = 0x55;
         const SIZE: usize = 0x2_0000;

         let mut f = TempFile::new().unwrap().into_file();
         f.set_len(16384).unwrap();

         // Write buffer of non-zero bytes. The size of the buffer will be the new
         // size of the file.
         let orig_data = [NON_ZERO_VALUE; SIZE];
         f.rewind().unwrap();
         f.write_all(&orig_data).unwrap();
         assert_eq!(f.metadata().unwrap().len(), SIZE as u64);

         // Punch a hole at offset 0x10001.
         // Subsequent reads from this range will return zeros.
         f.punch_hole(0x1_0001, 0x200).unwrap();

         // Read back the data.
         let mut readback = [0u8; SIZE];
         f.rewind().unwrap();
         f.read_exact(&mut readback).unwrap();
         // Original data should still exist before the hole.
         for read in &readback[0..0x1_0001] {
             assert_eq!(*read, NON_ZERO_VALUE);
         }
         // Verify that `punch_hole()` zeroed the intended region.
         for read in &readback[0x1_0001..(0x1_0001 + 0x200)] {
             assert_eq!(*read, 0);
         }
         // Original data should still exist after the hole.
         for read in &readback[(0x1_0001 + 0x200)..] {
             assert_eq!(*read, NON_ZERO_VALUE);
         }

         // Punch a hole at the end of the file.
         // Subsequent reads from this range should return zeros.
         f.punch_hole(SIZE as u64 - 0x400, 0x400).unwrap();
         // Even though we punched a hole at the end of the file, the file size should remain the
         // same since FALLOC_FL_PUNCH_HOLE must be used with FALLOC_FL_KEEP_SIZE.
         assert_eq!(f.metadata().unwrap().len(), SIZE as u64);

         let mut readback = [0u8; 0x400];
         f.seek(SeekFrom::Start(SIZE as u64 - 0x400)).unwrap();
         f.read_exact(&mut readback).unwrap();
         // Verify that `punch_hole()` zeroed the intended region.
         for read in &readback[0..0x400] {
             assert_eq!(*read, 0);
         }

         // Punching a hole of len 0 should return an error.
         assert!(f.punch_hole(0x200, 0x0).is_err());
         // Zeroing a region of len 0 should not return an error since we have a fallback path
         // in `write_zeroes_at()` for `fallocate()` failure.
         assert!(f.write_zeroes_at(0x200, 0x0).is_ok());
     }
 }
	// Copyright 2020 Amazon.com, Inc. or its affiliates. All Rights Reserved.
	//
	// Copyright 2019 Intel Corporation. All Rights Reserved.
	//
	// Copyright 2018 The Chromium OS Authors. All rights reserved.
	//
	// SPDX-License-Identifier: BSD-3-Clause

	//! Traits for replacing a range with a hole and writing zeroes in a file.

	use std::cmp::min;
	use std::fs::File;
	use std::io::{Error, ErrorKind, Result, Seek, SeekFrom};
	use std::os::unix::fs::FileExt;

	use crate::fallocate::{fallocate, FallocateMode};

	/// A trait for deallocating space in a file.
	pub trait PunchHole {
	/// Replace a range of bytes with a hole.
	///
	/// # Arguments
	///
	/// * `offset`: offset of the file where to replace with a hole.
	/// * `length`: the number of bytes of the hole to replace with.
	fn punch_hole(&mut self, offset: u64, length: u64) -> Result<()>;
	}

	impl PunchHole for File {
	fn punch_hole(&mut self, offset: u64, length: u64) -> Result<()> {
	fallocate(self, FallocateMode::PunchHole, true, offset, length)
	.map_err(\|e\| Error::from_raw_os_error(e.errno()))
	}
	}

	/// A trait for writing zeroes to a stream.
	pub trait WriteZeroes {
	/// Write up to `length` bytes of zeroes to the stream, returning how many bytes were written.
	///
	/// # Arguments
	///
	/// * `length`: the number of bytes of zeroes to write to the stream.
	fn write_zeroes(&mut self, length: usize) -> Result<usize>;

	/// Write zeroes to the stream until `length` bytes have been written.
	///
	/// This method will continuously write zeroes until the requested `length` is satisfied or an
	/// unrecoverable error is encountered.
	///
	/// # Arguments
	///
	/// * `length`: the exact number of bytes of zeroes to write to the stream.
	fn write_all_zeroes(&mut self, mut length: usize) -> Result<()> {
	while length > 0 {
	match self.write_zeroes(length) {
	Ok(0) => return Err(Error::from(ErrorKind::WriteZero)),
	Ok(bytes_written) => {
	length = length
	.checked_sub(bytes_written)
	.ok_or_else(\|\| Error::from(ErrorKind::Other))?
	}
	// If the operation was interrupted, we should retry it.
	Err(e) => {
	if e.kind() != ErrorKind::Interrupted {
	return Err(e);
	}
	}
	}
	}
	Ok(())
	}
	}

	/// A trait for writing zeroes to an arbitrary position in a file.
	pub trait WriteZeroesAt {
	/// Write up to `length` bytes of zeroes starting at `offset`, returning how many bytes were
	/// written.
	///
	/// # Arguments
	///
	/// * `offset`: offset of the file where to write zeroes.
	/// * `length`: the number of bytes of zeroes to write to the stream.
	fn write_zeroes_at(&mut self, offset: u64, length: usize) -> Result<usize>;

	/// Write zeroes starting at `offset` until `length` bytes have been written.
	///
	/// This method will continuously write zeroes until the requested `length` is satisfied or an
	/// unrecoverable error is encountered.
	///
	/// # Arguments
	///
	/// * `offset`: offset of the file where to write zeroes.
	/// * `length`: the exact number of bytes of zeroes to write to the stream.
	fn write_all_zeroes_at(&mut self, mut offset: u64, mut length: usize) -> Result<()> {
	while length > 0 {
	match self.write_zeroes_at(offset, length) {
	Ok(0) => return Err(Error::from(ErrorKind::WriteZero)),
	Ok(bytes_written) => {
	length = length
	.checked_sub(bytes_written)
	.ok_or_else(\|\| Error::from(ErrorKind::Other))?;
	offset = offset
	.checked_add(bytes_written as u64)
	.ok_or_else(\|\| Error::from(ErrorKind::Other))?;
	}
	Err(e) => {
	// If the operation was interrupted, we should retry it.
	if e.kind() != ErrorKind::Interrupted {
	return Err(e);
	}
	}
	}
	}
	Ok(())
	}
	}

	impl WriteZeroesAt for File {
	fn write_zeroes_at(&mut self, offset: u64, length: usize) -> Result<usize> {
	// Try to use fallocate() first, since it is more efficient than writing zeroes with
	// write().
	if fallocate(self, FallocateMode::ZeroRange, true, offset, length as u64).is_ok() {
	return Ok(length);
	}

	// Fall back to write().
	// fallocate() failed; fall back to writing a buffer of zeroes until we have written up
	// to `length`.
	let buf_size = min(length, 0x10000);
	let buf = vec![0u8; buf_size];
	let mut num_written: usize = 0;
	while num_written < length {
	let remaining = length - num_written;
	let write_size = min(remaining, buf_size);
	num_written += self.write_at(&buf[0..write_size], offset + num_written as u64)?;
	}
	Ok(length)
	}
	}

	impl<T: WriteZeroesAt + Seek> WriteZeroes for T {
	fn write_zeroes(&mut self, length: usize) -> Result<usize> {
	let offset = self.stream_position()?;
	let num_written = self.write_zeroes_at(offset, length)?;
	// Advance the seek cursor as if we had done a real write().
	self.seek(SeekFrom::Current(num_written as i64))?;
	Ok(length)
	}
	}

	#[cfg(test)]
	mod tests {
	use super::*;

	use std::io::{Read, Seek, SeekFrom, Write};

	use crate::tempfile::TempFile;

	#[test]
	fn test_small_write_zeroes() {
	const NON_ZERO_VALUE: u8 = 0x55;
	const BUF_SIZE: usize = 5678;

	let mut f = TempFile::new().unwrap().into_file();
	f.set_len(16384).unwrap();

	// Write buffer of non-zero bytes to offset 1234.
	let orig_data = [NON_ZERO_VALUE; BUF_SIZE];
	f.seek(SeekFrom::Start(1234)).unwrap();
	f.write_all(&orig_data).unwrap();

	// Read back the data plus some overlap on each side.
	let mut readback = [0u8; 16384];
	f.rewind().unwrap();
	f.read_exact(&mut readback).unwrap();
	// Bytes before the write should still be 0.
	for read in &readback[0..1234] {
	assert_eq!(*read, 0);
	}
	// Bytes that were just written should have `NON_ZERO_VALUE` value.
	for read in &readback[1234..(1234 + BUF_SIZE)] {
	assert_eq!(*read, NON_ZERO_VALUE);
	}
	// Bytes after the written area should still be 0.
	for read in &readback[(1234 + BUF_SIZE)..] {
	assert_eq!(*read, 0);
	}

	// Overwrite some of the data with zeroes.
	f.seek(SeekFrom::Start(2345)).unwrap();
	f.write_all_zeroes(4321).unwrap();
	// Verify seek position after `write_all_zeroes()`.
	assert_eq!(f.stream_position().unwrap(), 2345 + 4321);

	// Read back the data and verify that it is now zero.
	f.rewind().unwrap();
	f.read_exact(&mut readback).unwrap();
	// Bytes before the write should still be 0.
	for read in &readback[0..1234] {
	assert_eq!(*read, 0);
	}
	// Original data should still exist before the zeroed region.
	for read in &readback[1234..2345] {
	assert_eq!(*read, NON_ZERO_VALUE);
	}
	// Verify that `write_all_zeroes()` zeroed the intended region.
	for read in &readback[2345..(2345 + 4321)] {
	assert_eq!(*read, 0);
	}
	// Original data should still exist after the zeroed region.
	for read in &readback[(2345 + 4321)..(1234 + BUF_SIZE)] {
	assert_eq!(*read, NON_ZERO_VALUE);
	}
	// The rest of the file should still be 0.
	for read in &readback[(1234 + BUF_SIZE)..] {
	assert_eq!(*read, 0);
	}
	}

	#[test]
	fn test_large_write_zeroes() {
	const NON_ZERO_VALUE: u8 = 0x55;
	const SIZE: usize = 0x2_0000;

	let mut f = TempFile::new().unwrap().into_file();
	f.set_len(16384).unwrap();

	// Write buffer of non-zero bytes. The size of the buffer will be the new
	// size of the file.
	let orig_data = [NON_ZERO_VALUE; SIZE];
	f.rewind().unwrap();
	f.write_all(&orig_data).unwrap();
	assert_eq!(f.metadata().unwrap().len(), SIZE as u64);

	// Overwrite some of the data with zeroes.
	f.rewind().unwrap();
	f.write_all_zeroes(0x1_0001).unwrap();
	// Verify seek position after `write_all_zeroes()`.
	assert_eq!(f.stream_position().unwrap(), 0x1_0001);

	// Read back the data and verify that it is now zero.
	let mut readback = [0u8; SIZE];
	f.rewind().unwrap();
	f.read_exact(&mut readback).unwrap();
	// Verify that `write_all_zeroes()` zeroed the intended region.
	for read in &readback[0..0x1_0001] {
	assert_eq!(*read, 0);
	}
	// Original data should still exist after the zeroed region.
	for read in &readback[0x1_0001..SIZE] {
	assert_eq!(*read, NON_ZERO_VALUE);
	}

	// Now let's zero a certain region by using `write_all_zeroes_at()`.
	f.write_all_zeroes_at(0x1_8001, 0x200).unwrap();
	f.rewind().unwrap();
	f.read_exact(&mut readback).unwrap();

	// Original data should still exist before the zeroed region.
	for read in &readback[0x1_0001..0x1_8001] {
	assert_eq!(*read, NON_ZERO_VALUE);
	}
	// Verify that `write_all_zeroes_at()` zeroed the intended region.
	for read in &readback[0x1_8001..(0x1_8001 + 0x200)] {
	assert_eq!(*read, 0);
	}
	// Original data should still exist after the zeroed region.
	for read in &readback[(0x1_8001 + 0x200)..SIZE] {
	assert_eq!(*read, NON_ZERO_VALUE);
	}
	}

	#[test]
	fn test_punch_hole() {
	const NON_ZERO_VALUE: u8 = 0x55;
	const SIZE: usize = 0x2_0000;

	let mut f = TempFile::new().unwrap().into_file();
	f.set_len(16384).unwrap();

	// Write buffer of non-zero bytes. The size of the buffer will be the new
	// size of the file.
	let orig_data = [NON_ZERO_VALUE; SIZE];
	f.rewind().unwrap();
	f.write_all(&orig_data).unwrap();
	assert_eq!(f.metadata().unwrap().len(), SIZE as u64);

	// Punch a hole at offset 0x10001.
	// Subsequent reads from this range will return zeros.
	f.punch_hole(0x1_0001, 0x200).unwrap();

	// Read back the data.
	let mut readback = [0u8; SIZE];
	f.rewind().unwrap();
	f.read_exact(&mut readback).unwrap();
	// Original data should still exist before the hole.
	for read in &readback[0..0x1_0001] {
	assert_eq!(*read, NON_ZERO_VALUE);
	}
	// Verify that `punch_hole()` zeroed the intended region.
	for read in &readback[0x1_0001..(0x1_0001 + 0x200)] {
	assert_eq!(*read, 0);
	}
	// Original data should still exist after the hole.
	for read in &readback[(0x1_0001 + 0x200)..] {
	assert_eq!(*read, NON_ZERO_VALUE);
	}

	// Punch a hole at the end of the file.
	// Subsequent reads from this range should return zeros.
	f.punch_hole(SIZE as u64 - 0x400, 0x400).unwrap();
	// Even though we punched a hole at the end of the file, the file size should remain the
	// same since FALLOC_FL_PUNCH_HOLE must be used with FALLOC_FL_KEEP_SIZE.
	assert_eq!(f.metadata().unwrap().len(), SIZE as u64);

	let mut readback = [0u8; 0x400];
	f.seek(SeekFrom::Start(SIZE as u64 - 0x400)).unwrap();
	f.read_exact(&mut readback).unwrap();
	// Verify that `punch_hole()` zeroed the intended region.
	for read in &readback[0..0x400] {
	assert_eq!(*read, 0);
	}

	// Punching a hole of len 0 should return an error.
	assert!(f.punch_hole(0x200, 0x0).is_err());
	// Zeroing a region of len 0 should not return an error since we have a fallback path
	// in `write_zeroes_at()` for `fallocate()` failure.
	assert!(f.write_zeroes_at(0x200, 0x0).is_ok());
	}
	}