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//! A cross-platform Rust API for memory mapped buffers.
//!
//! The core functionality is provided by either [`Mmap`] or [`MmapMut`],
//! which correspond to mapping a [`File`] to a [`&[u8]`](https://doc.rust-lang.org/std/primitive.slice.html)
//! respectively. Both function by dereferencing to a slice, allowing the
//! [`Mmap`]/[`MmapMut`] to be used in the same way you would the equivalent slice
//! types.
//!
//! [`File`]: std::fs::File
//!
//! # Examples
//!
//! For simple cases [`Mmap`] can be used directly:
//!
//! ```
//! use std::fs::File;
//! use std::io::Read;
//!
//! use memmap2::Mmap;
//!
//! # fn main() -> std::io::Result<()> {
//! let mut file = File::open("LICENSE-APACHE")?;
//!
//! let mut contents = Vec::new();
//! file.read_to_end(&mut contents)?;
//!
//! let mmap = unsafe { Mmap::map(&file)? };
//!
//! assert_eq!(&contents[..], &mmap[..]);
//! # Ok(())
//! # }
//! ```
//!
//! However for cases which require configuration of the mapping, then
//! you can use [`MmapOptions`] in order to further configure a mapping
//! before you create it.
#![allow(clippy::len_without_is_empty, clippy::missing_safety_doc)]
#[cfg_attr(unix, path = "unix.rs")]
#[cfg_attr(windows, path = "windows.rs")]
#[cfg_attr(not(any(unix, windows)), path = "stub.rs")]
mod os;
use crate::os::{file_len, MmapInner};
#[cfg(unix)]
mod advice;
#[cfg(unix)]
pub use crate::advice::{Advice, UncheckedAdvice};
use std::fmt;
#[cfg(not(any(unix, windows)))]
use std::fs::File;
use std::io::{Error, ErrorKind, Result};
use std::isize;
use std::mem;
use std::ops::{Deref, DerefMut};
#[cfg(unix)]
use std::os::unix::io::{AsRawFd, RawFd};
#[cfg(windows)]
use std::os::windows::io::{AsRawHandle, RawHandle};
use std::slice;
#[cfg(not(any(unix, windows)))]
pub struct MmapRawDescriptor<'a>(&'a File);
#[cfg(unix)]
pub struct MmapRawDescriptor(RawFd);
#[cfg(windows)]
pub struct MmapRawDescriptor(RawHandle);
pub trait MmapAsRawDesc {
fn as_raw_desc(&self) -> MmapRawDescriptor;
}
#[cfg(not(any(unix, windows)))]
impl MmapAsRawDesc for &File {
fn as_raw_desc(&self) -> MmapRawDescriptor {
MmapRawDescriptor(self)
}
}
#[cfg(unix)]
impl MmapAsRawDesc for RawFd {
fn as_raw_desc(&self) -> MmapRawDescriptor {
MmapRawDescriptor(*self)
}
}
#[cfg(unix)]
impl<'a, T> MmapAsRawDesc for &'a T
where
T: AsRawFd,
{
fn as_raw_desc(&self) -> MmapRawDescriptor {
MmapRawDescriptor(self.as_raw_fd())
}
}
#[cfg(windows)]
impl MmapAsRawDesc for RawHandle {
fn as_raw_desc(&self) -> MmapRawDescriptor {
MmapRawDescriptor(*self)
}
}
#[cfg(windows)]
impl<'a, T> MmapAsRawDesc for &'a T
where
T: AsRawHandle,
{
fn as_raw_desc(&self) -> MmapRawDescriptor {
MmapRawDescriptor(self.as_raw_handle())
}
}
/// A memory map builder, providing advanced options and flags for specifying memory map behavior.
///
/// `MmapOptions` can be used to create an anonymous memory map using [`map_anon()`], or a
/// file-backed memory map using one of [`map()`], [`map_mut()`], [`map_exec()`],
/// [`map_copy()`], or [`map_copy_read_only()`].
///
/// ## Safety
///
/// All file-backed memory map constructors are marked `unsafe` because of the potential for
/// *Undefined Behavior* (UB) using the map if the underlying file is subsequently modified, in or
/// out of process. Applications must consider the risk and take appropriate precautions when
/// using file-backed maps. Solutions such as file permissions, locks or process-private (e.g.
/// unlinked) files exist but are platform specific and limited.
///
/// [`map_anon()`]: MmapOptions::map_anon()
/// [`map()`]: MmapOptions::map()
/// [`map_mut()`]: MmapOptions::map_mut()
/// [`map_exec()`]: MmapOptions::map_exec()
/// [`map_copy()`]: MmapOptions::map_copy()
/// [`map_copy_read_only()`]: MmapOptions::map_copy_read_only()
#[derive(Clone, Debug, Default)]
pub struct MmapOptions {
offset: u64,
len: Option<usize>,
huge: Option<u8>,
stack: bool,
populate: bool,
}
impl MmapOptions {
/// Creates a new set of options for configuring and creating a memory map.
///
/// # Example
///
/// ```
/// use memmap2::{MmapMut, MmapOptions};
/// # use std::io::Result;
///
/// # fn main() -> Result<()> {
/// // Create a new memory map builder.
/// let mut mmap_options = MmapOptions::new();
///
/// // Configure the memory map builder using option setters, then create
/// // a memory map using one of `mmap_options.map_anon`, `mmap_options.map`,
/// // `mmap_options.map_mut`, `mmap_options.map_exec`, or `mmap_options.map_copy`:
/// let mut mmap: MmapMut = mmap_options.len(36).map_anon()?;
///
/// // Use the memory map:
/// mmap.copy_from_slice(b"...data to copy to the memory map...");
/// # Ok(())
/// # }
/// ```
pub fn new() -> MmapOptions {
MmapOptions::default()
}
/// Configures the memory map to start at byte `offset` from the beginning of the file.
///
/// This option has no effect on anonymous memory maps.
///
/// By default, the offset is 0.
///
/// # Example
///
/// ```
/// use memmap2::MmapOptions;
/// use std::fs::File;
///
/// # fn main() -> std::io::Result<()> {
/// let mmap = unsafe {
/// MmapOptions::new()
/// .offset(30)
/// .map(&File::open("LICENSE-APACHE")?)?
/// };
/// assert_eq!(&b"Apache License"[..],
/// &mmap[..14]);
/// # Ok(())
/// # }
/// ```
pub fn offset(&mut self, offset: u64) -> &mut Self {
self.offset = offset;
self
}
/// Configures the created memory mapped buffer to be `len` bytes long.
///
/// This option is mandatory for anonymous memory maps.
///
/// For file-backed memory maps, the length will default to the file length.
///
/// # Example
///
/// ```
/// use memmap2::MmapOptions;
/// use std::fs::File;
///
/// # fn main() -> std::io::Result<()> {
/// let mmap = unsafe {
/// MmapOptions::new()
/// .len(9)
/// .map(&File::open("README.md")?)?
/// };
/// assert_eq!(&b"# memmap2"[..], &mmap[..]);
/// # Ok(())
/// # }
/// ```
pub fn len(&mut self, len: usize) -> &mut Self {
self.len = Some(len);
self
}
/// Returns the configured length, or the length of the provided file.
fn get_len<T: MmapAsRawDesc>(&self, file: &T) -> Result<usize> {
self.len.map(Ok).unwrap_or_else(|| {
let desc = file.as_raw_desc();
let file_len = file_len(desc.0)?;
if file_len < self.offset {
return Err(Error::new(
ErrorKind::InvalidData,
"memory map offset is larger than length",
));
}
let len = file_len - self.offset;
// Rust's slice cannot be larger than isize::MAX.
//
// This is not a problem on 64-bit targets, but on 32-bit one
// having a file or an anonymous mapping larger than 2GB is quite normal
// and we have to prevent it.
//
// The code below is essentially the same as in Rust's std:
if mem::size_of::<usize>() < 8 && len > isize::MAX as u64 {
return Err(Error::new(
ErrorKind::InvalidData,
"memory map length overflows isize",
));
}
Ok(len as usize)
})
}
/// Configures the anonymous memory map to be suitable for a process or thread stack.
///
/// This option corresponds to the `MAP_STACK` flag on Linux. It has no effect on Windows.
///
/// This option has no effect on file-backed memory maps.
///
/// # Example
///
/// ```
/// use memmap2::MmapOptions;
///
/// # fn main() -> std::io::Result<()> {
/// let stack = MmapOptions::new().stack().len(4096).map_anon();
/// # Ok(())
/// # }
/// ```
pub fn stack(&mut self) -> &mut Self {
self.stack = true;
self
}
/// Configures the anonymous memory map to be allocated using huge pages.
///
/// This option corresponds to the `MAP_HUGETLB` flag on Linux. It has no effect on Windows.
///
/// The size of the requested page can be specified in page bits. If not provided, the system
/// default is requested. The requested length should be a multiple of this, or the mapping
/// will fail.
///
/// This option has no effect on file-backed memory maps.
///
/// # Example
///
/// ```
/// use memmap2::MmapOptions;
///
/// # fn main() -> std::io::Result<()> {
/// let stack = MmapOptions::new().huge(Some(21)).len(2*1024*1024).map_anon();
/// # Ok(())
/// # }
/// ```
pub fn huge(&mut self, page_bits: Option<u8>) -> &mut Self {
self.huge = Some(page_bits.unwrap_or(0));
self
}
/// Populate (prefault) page tables for a mapping.
///
/// For a file mapping, this causes read-ahead on the file. This will help to reduce blocking on page faults later.
///
/// This option corresponds to the `MAP_POPULATE` flag on Linux. It has no effect on Windows.
///
/// # Example
///
/// ```
/// use memmap2::MmapOptions;
/// use std::fs::File;
///
/// # fn main() -> std::io::Result<()> {
/// let file = File::open("LICENSE-MIT")?;
///
/// let mmap = unsafe {
/// MmapOptions::new().populate().map(&file)?
/// };
///
/// assert_eq!(&b"Copyright"[..], &mmap[..9]);
/// # Ok(())
/// # }
/// ```
pub fn populate(&mut self) -> &mut Self {
self.populate = true;
self
}
/// Creates a read-only memory map backed by a file.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails, which can happen for a
/// variety of reasons, such as when the file is not open with read permissions.
///
/// # Example
///
/// ```
/// use memmap2::MmapOptions;
/// use std::fs::File;
/// use std::io::Read;
///
/// # fn main() -> std::io::Result<()> {
/// let mut file = File::open("LICENSE-APACHE")?;
///
/// let mut contents = Vec::new();
/// file.read_to_end(&mut contents)?;
///
/// let mmap = unsafe {
/// MmapOptions::new().map(&file)?
/// };
///
/// assert_eq!(&contents[..], &mmap[..]);
/// # Ok(())
/// # }
/// ```
pub unsafe fn map<T: MmapAsRawDesc>(&self, file: T) -> Result<Mmap> {
let desc = file.as_raw_desc();
MmapInner::map(self.get_len(&file)?, desc.0, self.offset, self.populate)
.map(|inner| Mmap { inner })
}
/// Creates a readable and executable memory map backed by a file.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails, which can happen for a
/// variety of reasons, such as when the file is not open with read permissions.
pub unsafe fn map_exec<T: MmapAsRawDesc>(&self, file: T) -> Result<Mmap> {
let desc = file.as_raw_desc();
MmapInner::map_exec(self.get_len(&file)?, desc.0, self.offset, self.populate)
.map(|inner| Mmap { inner })
}
/// Creates a writeable memory map backed by a file.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails, which can happen for a
/// variety of reasons, such as when the file is not open with read and write permissions.
///
/// # Example
///
/// ```
/// # extern crate memmap2;
/// # extern crate tempfile;
/// #
/// use std::fs::OpenOptions;
/// use std::path::PathBuf;
///
/// use memmap2::MmapOptions;
/// #
/// # fn main() -> std::io::Result<()> {
/// # let tempdir = tempfile::tempdir()?;
/// let path: PathBuf = /* path to file */
/// # tempdir.path().join("map_mut");
/// let file = OpenOptions::new().read(true).write(true).create(true).open(&path)?;
/// file.set_len(13)?;
///
/// let mut mmap = unsafe {
/// MmapOptions::new().map_mut(&file)?
/// };
///
/// mmap.copy_from_slice(b"Hello, world!");
/// # Ok(())
/// # }
/// ```
pub unsafe fn map_mut<T: MmapAsRawDesc>(&self, file: T) -> Result<MmapMut> {
let desc = file.as_raw_desc();
MmapInner::map_mut(self.get_len(&file)?, desc.0, self.offset, self.populate)
.map(|inner| MmapMut { inner })
}
/// Creates a copy-on-write memory map backed by a file.
///
/// Data written to the memory map will not be visible by other processes,
/// and will not be carried through to the underlying file.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails, which can happen for a
/// variety of reasons, such as when the file is not open with writable permissions.
///
/// # Example
///
/// ```
/// use memmap2::MmapOptions;
/// use std::fs::File;
/// use std::io::Write;
///
/// # fn main() -> std::io::Result<()> {
/// let file = File::open("LICENSE-APACHE")?;
/// let mut mmap = unsafe { MmapOptions::new().map_copy(&file)? };
/// (&mut mmap[..]).write_all(b"Hello, world!")?;
/// # Ok(())
/// # }
/// ```
pub unsafe fn map_copy<T: MmapAsRawDesc>(&self, file: T) -> Result<MmapMut> {
let desc = file.as_raw_desc();
MmapInner::map_copy(self.get_len(&file)?, desc.0, self.offset, self.populate)
.map(|inner| MmapMut { inner })
}
/// Creates a copy-on-write read-only memory map backed by a file.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails, which can happen for a
/// variety of reasons, such as when the file is not open with read permissions.
///
/// # Example
///
/// ```
/// use memmap2::MmapOptions;
/// use std::fs::File;
/// use std::io::Read;
///
/// # fn main() -> std::io::Result<()> {
/// let mut file = File::open("README.md")?;
///
/// let mut contents = Vec::new();
/// file.read_to_end(&mut contents)?;
///
/// let mmap = unsafe {
/// MmapOptions::new().map_copy_read_only(&file)?
/// };
///
/// assert_eq!(&contents[..], &mmap[..]);
/// # Ok(())
/// # }
/// ```
pub unsafe fn map_copy_read_only<T: MmapAsRawDesc>(&self, file: T) -> Result<Mmap> {
let desc = file.as_raw_desc();
MmapInner::map_copy_read_only(self.get_len(&file)?, desc.0, self.offset, self.populate)
.map(|inner| Mmap { inner })
}
/// Creates an anonymous memory map.
///
/// The memory map length should be configured using [`MmapOptions::len()`]
/// before creating an anonymous memory map, otherwise a zero-length mapping
/// will be crated.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails or
/// when `len > isize::MAX`.
pub fn map_anon(&self) -> Result<MmapMut> {
let len = self.len.unwrap_or(0);
// See get_len() for details.
if mem::size_of::<usize>() < 8 && len > isize::MAX as usize {
return Err(Error::new(
ErrorKind::InvalidData,
"memory map length overflows isize",
));
}
MmapInner::map_anon(len, self.stack, self.populate, self.huge)
.map(|inner| MmapMut { inner })
}
/// Creates a raw memory map.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails, which can happen for a
/// variety of reasons, such as when the file is not open with read and write permissions.
pub fn map_raw<T: MmapAsRawDesc>(&self, file: T) -> Result<MmapRaw> {
let desc = file.as_raw_desc();
MmapInner::map_mut(self.get_len(&file)?, desc.0, self.offset, self.populate)
.map(|inner| MmapRaw { inner })
}
/// Creates a read-only raw memory map
///
/// This is primarily useful to avoid intermediate `Mmap` instances when
/// read-only access to files modified elsewhere are required.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails
pub fn map_raw_read_only<T: MmapAsRawDesc>(&self, file: T) -> Result<MmapRaw> {
let desc = file.as_raw_desc();
MmapInner::map(self.get_len(&file)?, desc.0, self.offset, self.populate)
.map(|inner| MmapRaw { inner })
}
}
/// A handle to an immutable memory mapped buffer.
///
/// A `Mmap` may be backed by a file, or it can be anonymous map, backed by volatile memory. Use
/// [`MmapOptions`] or [`map()`] to create a file-backed memory map. To create an immutable
/// anonymous memory map, first create a mutable anonymous memory map, and then make it immutable
/// with [`MmapMut::make_read_only()`].
///
/// A file backed `Mmap` is created by `&File` reference, and will remain valid even after the
/// `File` is dropped. In other words, the `Mmap` handle is completely independent of the `File`
/// used to create it. For consistency, on some platforms this is achieved by duplicating the
/// underlying file handle. The memory will be unmapped when the `Mmap` handle is dropped.
///
/// Dereferencing and accessing the bytes of the buffer may result in page faults (e.g. swapping
/// the mapped pages into physical memory) though the details of this are platform specific.
///
/// `Mmap` is [`Sync`] and [`Send`].
///
/// ## Safety
///
/// All file-backed memory map constructors are marked `unsafe` because of the potential for
/// *Undefined Behavior* (UB) using the map if the underlying file is subsequently modified, in or
/// out of process. Applications must consider the risk and take appropriate precautions when using
/// file-backed maps. Solutions such as file permissions, locks or process-private (e.g. unlinked)
/// files exist but are platform specific and limited.
///
/// ## Example
///
/// ```
/// use memmap2::MmapOptions;
/// use std::io::Write;
/// use std::fs::File;
///
/// # fn main() -> std::io::Result<()> {
/// let file = File::open("README.md")?;
/// let mmap = unsafe { MmapOptions::new().map(&file)? };
/// assert_eq!(b"# memmap2", &mmap[0..9]);
/// # Ok(())
/// # }
/// ```
///
/// See [`MmapMut`] for the mutable version.
///
/// [`map()`]: Mmap::map()
pub struct Mmap {
inner: MmapInner,
}
impl Mmap {
/// Creates a read-only memory map backed by a file.
///
/// This is equivalent to calling `MmapOptions::new().map(file)`.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails, which can happen for a
/// variety of reasons, such as when the file is not open with read permissions.
///
/// # Example
///
/// ```
/// use std::fs::File;
/// use std::io::Read;
///
/// use memmap2::Mmap;
///
/// # fn main() -> std::io::Result<()> {
/// let mut file = File::open("LICENSE-APACHE")?;
///
/// let mut contents = Vec::new();
/// file.read_to_end(&mut contents)?;
///
/// let mmap = unsafe { Mmap::map(&file)? };
///
/// assert_eq!(&contents[..], &mmap[..]);
/// # Ok(())
/// # }
/// ```
pub unsafe fn map<T: MmapAsRawDesc>(file: T) -> Result<Mmap> {
MmapOptions::new().map(file)
}
/// Transition the memory map to be writable.
///
/// If the memory map is file-backed, the file must have been opened with write permissions.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails, which can happen for a
/// variety of reasons, such as when the file is not open with writable permissions.
///
/// # Example
///
/// ```
/// # extern crate memmap2;
/// # extern crate tempfile;
/// #
/// use memmap2::Mmap;
/// use std::ops::DerefMut;
/// use std::io::Write;
/// # use std::fs::OpenOptions;
///
/// # fn main() -> std::io::Result<()> {
/// # let tempdir = tempfile::tempdir()?;
/// let file = /* file opened with write permissions */
/// # OpenOptions::new()
/// # .read(true)
/// # .write(true)
/// # .create(true)
/// # .open(tempdir.path()
/// # .join("make_mut"))?;
/// # file.set_len(128)?;
/// let mmap = unsafe { Mmap::map(&file)? };
/// // ... use the read-only memory map ...
/// let mut mut_mmap = mmap.make_mut()?;
/// mut_mmap.deref_mut().write_all(b"hello, world!")?;
/// # Ok(())
/// # }
/// ```
pub fn make_mut(mut self) -> Result<MmapMut> {
self.inner.make_mut()?;
Ok(MmapMut { inner: self.inner })
}
/// Advise OS how this memory map will be accessed.
///
/// Only supported on Unix.
///
#[cfg(unix)]
pub fn advise(&self, advice: Advice) -> Result<()> {
self.inner
.advise(advice as libc::c_int, 0, self.inner.len())
}
/// Advise OS how this memory map will be accessed.
///
/// Used with the [unchecked flags][UncheckedAdvice]. Only supported on Unix.
///
#[cfg(unix)]
pub unsafe fn unchecked_advise(&self, advice: UncheckedAdvice) -> Result<()> {
self.inner
.advise(advice as libc::c_int, 0, self.inner.len())
}
/// Advise OS how this range of memory map will be accessed.
///
/// Only supported on Unix.
///
/// The offset and length must be in the bounds of the memory map.
///
#[cfg(unix)]
pub fn advise_range(&self, advice: Advice, offset: usize, len: usize) -> Result<()> {
self.inner.advise(advice as libc::c_int, offset, len)
}
/// Advise OS how this range of memory map will be accessed.
///
/// Used with the [unchecked flags][UncheckedAdvice]. Only supported on Unix.
///
/// The offset and length must be in the bounds of the memory map.
///
#[cfg(unix)]
pub unsafe fn unchecked_advise_range(
&self,
advice: UncheckedAdvice,
offset: usize,
len: usize,
) -> Result<()> {
self.inner.advise(advice as libc::c_int, offset, len)
}
/// Lock the whole memory map into RAM. Only supported on Unix.
///
#[cfg(unix)]
pub fn lock(&self) -> Result<()> {
self.inner.lock()
}
/// Unlock the whole memory map. Only supported on Unix.
///
#[cfg(unix)]
pub fn unlock(&self) -> Result<()> {
self.inner.unlock()
}
/// Adjust the size of the memory mapping.
///
/// This will try to resize the memory mapping in place. If
/// [`RemapOptions::may_move`] is specified it will move the mapping if it
/// could not resize in place, otherwise it will error.
///
/// Only supported on Linux.
///
/// See the [`mremap(2)`] man page.
///
/// # Safety
///
/// Resizing the memory mapping beyond the end of the mapped file will
/// result in UB should you happen to access memory beyond the end of the
/// file.
///
#[cfg(target_os = "linux")]
pub unsafe fn remap(&mut self, new_len: usize, options: RemapOptions) -> Result<()> {
self.inner.remap(new_len, options)
}
}
#[cfg(feature = "stable_deref_trait")]
unsafe impl stable_deref_trait::StableDeref for Mmap {}
impl Deref for Mmap {
type Target = [u8];
#[inline]
fn deref(&self) -> &[u8] {
unsafe { slice::from_raw_parts(self.inner.ptr(), self.inner.len()) }
}
}
impl AsRef<[u8]> for Mmap {
#[inline]
fn as_ref(&self) -> &[u8] {
self.deref()
}
}
impl fmt::Debug for Mmap {
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
fmt.debug_struct("Mmap")
.field("ptr", &self.as_ptr())
.field("len", &self.len())
.finish()
}
}
/// A handle to a raw memory mapped buffer.
///
/// This struct never hands out references to its interior, only raw pointers.
/// This can be helpful when creating shared memory maps between untrusted processes.
pub struct MmapRaw {
inner: MmapInner,
}
impl MmapRaw {
/// Creates a writeable memory map backed by a file.
///
/// This is equivalent to calling `MmapOptions::new().map_raw(file)`.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails, which can happen for a
/// variety of reasons, such as when the file is not open with read and write permissions.
pub fn map_raw<T: MmapAsRawDesc>(file: T) -> Result<MmapRaw> {
MmapOptions::new().map_raw(file)
}
/// Returns a raw pointer to the memory mapped file.
///
/// Before dereferencing this pointer, you have to make sure that the file has not been
/// truncated since the memory map was created.
/// Avoiding this will not introduce memory safety issues in Rust terms,
/// but will cause SIGBUS (or equivalent) signal.
#[inline]
pub fn as_ptr(&self) -> *const u8 {
self.inner.ptr()
}
/// Returns an unsafe mutable pointer to the memory mapped file.
///
/// Before dereferencing this pointer, you have to make sure that the file has not been
/// truncated since the memory map was created.
/// Avoiding this will not introduce memory safety issues in Rust terms,
/// but will cause SIGBUS (or equivalent) signal.
#[inline]
pub fn as_mut_ptr(&self) -> *mut u8 {
self.inner.ptr() as _
}
/// Returns the length in bytes of the memory map.
///
/// Note that truncating the file can cause the length to change (and render this value unusable).
#[inline]
pub fn len(&self) -> usize {
self.inner.len()
}
/// Flushes outstanding memory map modifications to disk.
///
/// When this method returns with a non-error result, all outstanding changes to a file-backed
/// memory map are guaranteed to be durably stored. The file's metadata (including last
/// modification timestamp) may not be updated.
///
/// # Example
///
/// ```
/// # extern crate memmap2;
/// # extern crate tempfile;
/// #
/// use std::fs::OpenOptions;
/// use std::io::Write;
/// use std::path::PathBuf;
/// use std::slice;
///
/// use memmap2::MmapRaw;
///
/// # fn main() -> std::io::Result<()> {
/// let tempdir = tempfile::tempdir()?;
/// let path: PathBuf = /* path to file */
/// # tempdir.path().join("flush");
/// let file = OpenOptions::new().read(true).write(true).create(true).open(&path)?;
/// file.set_len(128)?;
///
/// let mut mmap = unsafe { MmapRaw::map_raw(&file)? };
///
/// let mut memory = unsafe { slice::from_raw_parts_mut(mmap.as_mut_ptr(), 128) };
/// memory.write_all(b"Hello, world!")?;
/// mmap.flush()?;
/// # Ok(())
/// # }
/// ```
pub fn flush(&self) -> Result<()> {
let len = self.len();
self.inner.flush(0, len)
}
/// Asynchronously flushes outstanding memory map modifications to disk.
///
/// This method initiates flushing modified pages to durable storage, but it will not wait for
/// the operation to complete before returning. The file's metadata (including last
/// modification timestamp) may not be updated.
pub fn flush_async(&self) -> Result<()> {
let len = self.len();
self.inner.flush_async(0, len)
}
/// Flushes outstanding memory map modifications in the range to disk.
///
/// The offset and length must be in the bounds of the memory map.
///
/// When this method returns with a non-error result, all outstanding changes to a file-backed
/// memory in the range are guaranteed to be durable stored. The file's metadata (including
/// last modification timestamp) may not be updated. It is not guaranteed the only the changes
/// in the specified range are flushed; other outstanding changes to the memory map may be
/// flushed as well.
pub fn flush_range(&self, offset: usize, len: usize) -> Result<()> {
self.inner.flush(offset, len)
}
/// Asynchronously flushes outstanding memory map modifications in the range to disk.
///
/// The offset and length must be in the bounds of the memory map.
///
/// This method initiates flushing modified pages to durable storage, but it will not wait for
/// the operation to complete before returning. The file's metadata (including last
/// modification timestamp) may not be updated. It is not guaranteed that the only changes
/// flushed are those in the specified range; other outstanding changes to the memory map may
/// be flushed as well.
pub fn flush_async_range(&self, offset: usize, len: usize) -> Result<()> {
self.inner.flush_async(offset, len)
}
/// Advise OS how this memory map will be accessed.
///
/// Only supported on Unix.
///
#[cfg(unix)]
pub fn advise(&self, advice: Advice) -> Result<()> {
self.inner
.advise(advice as libc::c_int, 0, self.inner.len())
}
/// Advise OS how this memory map will be accessed.
///
/// Used with the [unchecked flags][UncheckedAdvice]. Only supported on Unix.
///
#[cfg(unix)]
pub unsafe fn unchecked_advise(&self, advice: UncheckedAdvice) -> Result<()> {
self.inner
.advise(advice as libc::c_int, 0, self.inner.len())
}
/// Advise OS how this range of memory map will be accessed.
///
/// The offset and length must be in the bounds of the memory map.
///
/// Only supported on Unix.
///
#[cfg(unix)]
pub fn advise_range(&self, advice: Advice, offset: usize, len: usize) -> Result<()> {
self.inner.advise(advice as libc::c_int, offset, len)
}
/// Advise OS how this range of memory map will be accessed.
///
/// Used with the [unchecked flags][UncheckedAdvice]. Only supported on Unix.
///
/// The offset and length must be in the bounds of the memory map.
///
#[cfg(unix)]
pub unsafe fn unchecked_advise_range(
&self,
advice: UncheckedAdvice,
offset: usize,
len: usize,
) -> Result<()> {
self.inner.advise(advice as libc::c_int, offset, len)
}
/// Lock the whole memory map into RAM. Only supported on Unix.
///
#[cfg(unix)]
pub fn lock(&self) -> Result<()> {
self.inner.lock()
}
/// Unlock the whole memory map. Only supported on Unix.
///
#[cfg(unix)]
pub fn unlock(&self) -> Result<()> {
self.inner.unlock()
}
/// Adjust the size of the memory mapping.
///
/// This will try to resize the memory mapping in place. If
/// [`RemapOptions::may_move`] is specified it will move the mapping if it
/// could not resize in place, otherwise it will error.
///
/// Only supported on Linux.
///
/// See the [`mremap(2)`] man page.
///
/// # Safety
///
/// Resizing the memory mapping beyond the end of the mapped file will
/// result in UB should you happen to access memory beyond the end of the
/// file.
///
#[cfg(target_os = "linux")]
pub unsafe fn remap(&mut self, new_len: usize, options: RemapOptions) -> Result<()> {
self.inner.remap(new_len, options)
}
}
impl fmt::Debug for MmapRaw {
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
fmt.debug_struct("MmapRaw")
.field("ptr", &self.as_ptr())
.field("len", &self.len())
.finish()
}
}
impl From<Mmap> for MmapRaw {
fn from(value: Mmap) -> Self {
Self { inner: value.inner }
}
}
impl From<MmapMut> for MmapRaw {
fn from(value: MmapMut) -> Self {
Self { inner: value.inner }
}
}
/// A handle to a mutable memory mapped buffer.
///
/// A file-backed `MmapMut` buffer may be used to read from or write to a file. An anonymous
/// `MmapMut` buffer may be used any place that an in-memory byte buffer is needed. Use
/// [`MmapMut::map_mut()`] and [`MmapMut::map_anon()`] to create a mutable memory map of the
/// respective types, or [`MmapOptions::map_mut()`] and [`MmapOptions::map_anon()`] if non-default
/// options are required.
///
/// A file backed `MmapMut` is created by `&File` reference, and will remain valid even after the
/// `File` is dropped. In other words, the `MmapMut` handle is completely independent of the `File`
/// used to create it. For consistency, on some platforms this is achieved by duplicating the
/// underlying file handle. The memory will be unmapped when the `MmapMut` handle is dropped.
///
/// Dereferencing and accessing the bytes of the buffer may result in page faults (e.g. swapping
/// the mapped pages into physical memory) though the details of this are platform specific.
///
/// `Mmap` is [`Sync`] and [`Send`].
///
/// See [`Mmap`] for the immutable version.
///
/// ## Safety
///
/// All file-backed memory map constructors are marked `unsafe` because of the potential for
/// *Undefined Behavior* (UB) using the map if the underlying file is subsequently modified, in or
/// out of process. Applications must consider the risk and take appropriate precautions when using
/// file-backed maps. Solutions such as file permissions, locks or process-private (e.g. unlinked)
/// files exist but are platform specific and limited.
pub struct MmapMut {
inner: MmapInner,
}
impl MmapMut {
/// Creates a writeable memory map backed by a file.
///
/// This is equivalent to calling `MmapOptions::new().map_mut(file)`.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails, which can happen for a
/// variety of reasons, such as when the file is not open with read and write permissions.
///
/// # Example
///
/// ```
/// # extern crate memmap2;
/// # extern crate tempfile;
/// #
/// use std::fs::OpenOptions;
/// use std::path::PathBuf;
///
/// use memmap2::MmapMut;
/// #
/// # fn main() -> std::io::Result<()> {
/// # let tempdir = tempfile::tempdir()?;
/// let path: PathBuf = /* path to file */
/// # tempdir.path().join("map_mut");
/// let file = OpenOptions::new()
/// .read(true)
/// .write(true)
/// .create(true)
/// .open(&path)?;
/// file.set_len(13)?;
///
/// let mut mmap = unsafe { MmapMut::map_mut(&file)? };
///
/// mmap.copy_from_slice(b"Hello, world!");
/// # Ok(())
/// # }
/// ```
pub unsafe fn map_mut<T: MmapAsRawDesc>(file: T) -> Result<MmapMut> {
MmapOptions::new().map_mut(file)
}
/// Creates an anonymous memory map.
///
/// This is equivalent to calling `MmapOptions::new().len(length).map_anon()`.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails or
/// when `len > isize::MAX`.
pub fn map_anon(length: usize) -> Result<MmapMut> {
MmapOptions::new().len(length).map_anon()
}
/// Flushes outstanding memory map modifications to disk.
///
/// When this method returns with a non-error result, all outstanding changes to a file-backed
/// memory map are guaranteed to be durably stored. The file's metadata (including last
/// modification timestamp) may not be updated.
///
/// # Example
///
/// ```
/// # extern crate memmap2;
/// # extern crate tempfile;
/// #
/// use std::fs::OpenOptions;
/// use std::io::Write;
/// use std::path::PathBuf;
///
/// use memmap2::MmapMut;
///
/// # fn main() -> std::io::Result<()> {
/// # let tempdir = tempfile::tempdir()?;
/// let path: PathBuf = /* path to file */
/// # tempdir.path().join("flush");
/// let file = OpenOptions::new().read(true).write(true).create(true).open(&path)?;
/// file.set_len(128)?;
///
/// let mut mmap = unsafe { MmapMut::map_mut(&file)? };
///
/// (&mut mmap[..]).write_all(b"Hello, world!")?;
/// mmap.flush()?;
/// # Ok(())
/// # }
/// ```
pub fn flush(&self) -> Result<()> {
let len = self.len();
self.inner.flush(0, len)
}
/// Asynchronously flushes outstanding memory map modifications to disk.
///
/// This method initiates flushing modified pages to durable storage, but it will not wait for
/// the operation to complete before returning. The file's metadata (including last
/// modification timestamp) may not be updated.
pub fn flush_async(&self) -> Result<()> {
let len = self.len();
self.inner.flush_async(0, len)
}
/// Flushes outstanding memory map modifications in the range to disk.
///
/// The offset and length must be in the bounds of the memory map.
///
/// When this method returns with a non-error result, all outstanding changes to a file-backed
/// memory in the range are guaranteed to be durable stored. The file's metadata (including
/// last modification timestamp) may not be updated. It is not guaranteed the only the changes
/// in the specified range are flushed; other outstanding changes to the memory map may be
/// flushed as well.
pub fn flush_range(&self, offset: usize, len: usize) -> Result<()> {
self.inner.flush(offset, len)
}
/// Asynchronously flushes outstanding memory map modifications in the range to disk.
///
/// The offset and length must be in the bounds of the memory map.
///
/// This method initiates flushing modified pages to durable storage, but it will not wait for
/// the operation to complete before returning. The file's metadata (including last
/// modification timestamp) may not be updated. It is not guaranteed that the only changes
/// flushed are those in the specified range; other outstanding changes to the memory map may
/// be flushed as well.
pub fn flush_async_range(&self, offset: usize, len: usize) -> Result<()> {
self.inner.flush_async(offset, len)
}
/// Returns an immutable version of this memory mapped buffer.
///
/// If the memory map is file-backed, the file must have been opened with read permissions.
///
/// # Errors
///
/// This method returns an error when the underlying system call fails, which can happen for a
/// variety of reasons, such as when the file has not been opened with read permissions.
///
/// # Example
///
/// ```
/// # extern crate memmap2;
/// #
/// use std::io::Write;
/// use std::path::PathBuf;
///
/// use memmap2::{Mmap, MmapMut};
///
/// # fn main() -> std::io::Result<()> {
/// let mut mmap = MmapMut::map_anon(128)?;
///
/// (&mut mmap[..]).write(b"Hello, world!")?;
///
/// let mmap: Mmap = mmap.make_read_only()?;
/// # Ok(())
/// # }
/// ```
pub fn make_read_only(mut self) -> Result<Mmap> {
self.inner.make_read_only()?;
Ok(Mmap { inner: self.inner })
}
/// Transition the memory map to be readable and executable.
///
/// If the memory map is file-backed, the file must have been opened with execute permissions.
///
/// On systems with separate instructions and data caches (a category that includes many ARM
/// chips), a platform-specific call may be needed to ensure that the changes are visible to the
/// execution unit (e.g. when using this function to implement a JIT compiler). For more
///
/// # Errors
///
/// This method returns an error when the underlying system call fails, which can happen for a
/// variety of reasons, such as when the file has not been opened with execute permissions.
pub fn make_exec(mut self) -> Result<Mmap> {
self.inner.make_exec()?;
Ok(Mmap { inner: self.inner })
}
/// Advise OS how this memory map will be accessed.
///
/// Only supported on Unix.
///
#[cfg(unix)]
pub fn advise(&self, advice: Advice) -> Result<()> {
self.inner
.advise(advice as libc::c_int, 0, self.inner.len())
}
/// Advise OS how this memory map will be accessed.
///
/// Used with the [unchecked flags][UncheckedAdvice]. Only supported on Unix.
///
#[cfg(unix)]
pub unsafe fn unchecked_advise(&self, advice: UncheckedAdvice) -> Result<()> {
self.inner
.advise(advice as libc::c_int, 0, self.inner.len())
}
/// Advise OS how this range of memory map will be accessed.
///
/// Only supported on Unix.
///
/// The offset and length must be in the bounds of the memory map.
///
#[cfg(unix)]
pub fn advise_range(&self, advice: Advice, offset: usize, len: usize) -> Result<()> {
self.inner.advise(advice as libc::c_int, offset, len)
}
/// Advise OS how this range of memory map will be accessed.
///
/// Used with the [unchecked flags][UncheckedAdvice]. Only supported on Unix.
///
/// The offset and length must be in the bounds of the memory map.
///
#[cfg(unix)]
pub fn unchecked_advise_range(
&self,
advice: UncheckedAdvice,
offset: usize,
len: usize,
) -> Result<()> {
self.inner.advise(advice as libc::c_int, offset, len)
}
/// Lock the whole memory map into RAM. Only supported on Unix.
///
#[cfg(unix)]
pub fn lock(&self) -> Result<()> {
self.inner.lock()
}
/// Unlock the whole memory map. Only supported on Unix.
///
#[cfg(unix)]
pub fn unlock(&self) -> Result<()> {
self.inner.unlock()
}
/// Adjust the size of the memory mapping.
///
/// This will try to resize the memory mapping in place. If
/// [`RemapOptions::may_move`] is specified it will move the mapping if it
/// could not resize in place, otherwise it will error.
///
/// Only supported on Linux.
///
/// See the [`mremap(2)`] man page.
///
/// # Safety
///
/// Resizing the memory mapping beyond the end of the mapped file will
/// result in UB should you happen to access memory beyond the end of the
/// file.
///
#[cfg(target_os = "linux")]
pub unsafe fn remap(&mut self, new_len: usize, options: RemapOptions) -> Result<()> {
self.inner.remap(new_len, options)
}
}
#[cfg(feature = "stable_deref_trait")]
unsafe impl stable_deref_trait::StableDeref for MmapMut {}
impl Deref for MmapMut {
type Target = [u8];
#[inline]
fn deref(&self) -> &[u8] {
unsafe { slice::from_raw_parts(self.inner.ptr(), self.inner.len()) }
}
}
impl DerefMut for MmapMut {
#[inline]
fn deref_mut(&mut self) -> &mut [u8] {
unsafe { slice::from_raw_parts_mut(self.inner.mut_ptr(), self.inner.len()) }
}
}
impl AsRef<[u8]> for MmapMut {
#[inline]
fn as_ref(&self) -> &[u8] {
self.deref()
}
}
impl AsMut<[u8]> for MmapMut {
#[inline]
fn as_mut(&mut self) -> &mut [u8] {
self.deref_mut()
}
}
impl fmt::Debug for MmapMut {
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
fmt.debug_struct("MmapMut")
.field("ptr", &self.as_ptr())
.field("len", &self.len())
.finish()
}
}
/// Options for [`Mmap::remap`] and [`MmapMut::remap`].
#[derive(Copy, Clone, Default, Debug)]
#[cfg(target_os = "linux")]
pub struct RemapOptions {
may_move: bool,
}
#[cfg(target_os = "linux")]
impl RemapOptions {
/// Creates a mew set of options for resizing a memory map.
pub fn new() -> Self {
Self::default()
}
/// Controls whether the memory map can be moved if it is not possible to
/// resize it in place.
///
/// If false then the memory map is guaranteed to remain at the same
/// address when being resized but attempting to resize will return an
/// error if the new memory map would overlap with something else in the
/// current process' memory.
///
/// By default this is false.
///
/// # `may_move` and `StableDeref`
/// If the `stable_deref_trait` feature is enabled then [`Mmap`] and
/// [`MmapMut`] implement `StableDeref`. `StableDeref` promises that the
/// memory map dereferences to a fixed address, however, calling `remap`
/// with `may_move` set may result in the backing memory of the mapping
/// being moved to a new address. This may cause UB in other code
/// depending on the `StableDeref` guarantees.
pub fn may_move(mut self, may_move: bool) -> Self {
self.may_move = may_move;
self
}
pub(crate) fn into_flags(self) -> libc::c_int {
if self.may_move {
libc::MREMAP_MAYMOVE
} else {
0
}
}
}
#[cfg(test)]
mod test {
extern crate tempfile;
#[cfg(unix)]
use crate::advice::Advice;
use std::fs::{File, OpenOptions};
use std::io::{Read, Write};
use std::mem;
#[cfg(unix)]
use std::os::unix::io::AsRawFd;
#[cfg(windows)]
use std::os::windows::fs::OpenOptionsExt;
#[cfg(windows)]
const GENERIC_ALL: u32 = 0x10000000;
use super::{Mmap, MmapMut, MmapOptions};
#[test]
fn map_file() {
let expected_len = 128;
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmap");
let file = OpenOptions::new()
.read(true)
.write(true)
.create(true)
.open(path)
.unwrap();
file.set_len(expected_len as u64).unwrap();
let mut mmap = unsafe { MmapMut::map_mut(&file).unwrap() };
let len = mmap.len();
assert_eq!(expected_len, len);
let zeros = vec![0; len];
let incr: Vec<u8> = (0..len as u8).collect();
// check that the mmap is empty
assert_eq!(&zeros[..], &mmap[..]);
// write values into the mmap
(&mut mmap[..]).write_all(&incr[..]).unwrap();
// read values back
assert_eq!(&incr[..], &mmap[..]);
}
#[test]
#[cfg(unix)]
fn map_fd() {
let expected_len = 128;
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmap");
let file = OpenOptions::new()
.read(true)
.write(true)
.create(true)
.open(path)
.unwrap();
file.set_len(expected_len as u64).unwrap();
let mut mmap = unsafe { MmapMut::map_mut(file.as_raw_fd()).unwrap() };
let len = mmap.len();
assert_eq!(expected_len, len);
let zeros = vec![0; len];
let incr: Vec<u8> = (0..len as u8).collect();
// check that the mmap is empty
assert_eq!(&zeros[..], &mmap[..]);
// write values into the mmap
(&mut mmap[..]).write_all(&incr[..]).unwrap();
// read values back
assert_eq!(&incr[..], &mmap[..]);
}
/// Checks that "mapping" a 0-length file derefs to an empty slice.
#[test]
fn map_empty_file() {
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmap");
let file = OpenOptions::new()
.read(true)
.write(true)
.create(true)
.open(path)
.unwrap();
let mmap = unsafe { Mmap::map(&file).unwrap() };
assert!(mmap.is_empty());
assert_eq!(mmap.as_ptr().align_offset(mem::size_of::<usize>()), 0);
let mmap = unsafe { MmapMut::map_mut(&file).unwrap() };
assert!(mmap.is_empty());
assert_eq!(mmap.as_ptr().align_offset(mem::size_of::<usize>()), 0);
}
#[test]
fn map_anon() {
let expected_len = 128;
let mut mmap = MmapMut::map_anon(expected_len).unwrap();
let len = mmap.len();
assert_eq!(expected_len, len);
let zeros = vec![0; len];
let incr: Vec<u8> = (0..len as u8).collect();
// check that the mmap is empty
assert_eq!(&zeros[..], &mmap[..]);
// write values into the mmap
(&mut mmap[..]).write_all(&incr[..]).unwrap();
// read values back
assert_eq!(&incr[..], &mmap[..]);
}
#[test]
fn map_anon_zero_len() {
assert!(MmapOptions::new().map_anon().unwrap().is_empty())
}
#[test]
#[cfg(target_pointer_width = "32")]
fn map_anon_len_overflow() {
let res = MmapMut::map_anon(0x80000000);
assert_eq!(
res.unwrap_err().to_string(),
"memory map length overflows isize"
);
}
#[test]
fn file_write() {
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmap");
let mut file = OpenOptions::new()
.read(true)
.write(true)
.create(true)
.open(path)
.unwrap();
file.set_len(128).unwrap();
let write = b"abc123";
let mut read = [0u8; 6];
let mut mmap = unsafe { MmapMut::map_mut(&file).unwrap() };
(&mut mmap[..]).write_all(write).unwrap();
mmap.flush().unwrap();
file.read_exact(&mut read).unwrap();
assert_eq!(write, &read);
}
#[test]
fn flush_range() {
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmap");
let file = OpenOptions::new()
.read(true)
.write(true)
.create(true)
.open(path)
.unwrap();
file.set_len(128).unwrap();
let write = b"abc123";
let mut mmap = unsafe {
MmapOptions::new()
.offset(2)
.len(write.len())
.map_mut(&file)
.unwrap()
};
(&mut mmap[..]).write_all(write).unwrap();
mmap.flush_async_range(0, write.len()).unwrap();
mmap.flush_range(0, write.len()).unwrap();
}
#[test]
fn map_copy() {
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmap");
let mut file = OpenOptions::new()
.read(true)
.write(true)
.create(true)
.open(path)
.unwrap();
file.set_len(128).unwrap();
let nulls = b"\0\0\0\0\0\0";
let write = b"abc123";
let mut read = [0u8; 6];
let mut mmap = unsafe { MmapOptions::new().map_copy(&file).unwrap() };
(&mut mmap[..]).write_all(write).unwrap();
mmap.flush().unwrap();
// The mmap contains the write
(&mmap[..]).read_exact(&mut read).unwrap();
assert_eq!(write, &read);
// The file does not contain the write
file.read_exact(&mut read).unwrap();
assert_eq!(nulls, &read);
// another mmap does not contain the write
let mmap2 = unsafe { MmapOptions::new().map(&file).unwrap() };
(&mmap2[..]).read_exact(&mut read).unwrap();
assert_eq!(nulls, &read);
}
#[test]
fn map_copy_read_only() {
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmap");
let file = OpenOptions::new()
.read(true)
.write(true)
.create(true)
.open(path)
.unwrap();
file.set_len(128).unwrap();
let nulls = b"\0\0\0\0\0\0";
let mut read = [0u8; 6];
let mmap = unsafe { MmapOptions::new().map_copy_read_only(&file).unwrap() };
(&mmap[..]).read_exact(&mut read).unwrap();
assert_eq!(nulls, &read);
let mmap2 = unsafe { MmapOptions::new().map(&file).unwrap() };
(&mmap2[..]).read_exact(&mut read).unwrap();
assert_eq!(nulls, &read);
}
#[test]
fn map_offset() {
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmap");
let file = OpenOptions::new()
.read(true)
.write(true)
.create(true)
.open(path)
.unwrap();
let offset = u32::MAX as u64 + 2;
let len = 5432;
file.set_len(offset + len as u64).unwrap();
// Check inferred length mmap.
let mmap = unsafe { MmapOptions::new().offset(offset).map_mut(&file).unwrap() };
assert_eq!(len, mmap.len());
// Check explicit length mmap.
let mut mmap = unsafe {
MmapOptions::new()
.offset(offset)
.len(len)
.map_mut(&file)
.unwrap()
};
assert_eq!(len, mmap.len());
let zeros = vec![0; len];
let incr: Vec<_> = (0..len).map(|i| i as u8).collect();
// check that the mmap is empty
assert_eq!(&zeros[..], &mmap[..]);
// write values into the mmap
(&mut mmap[..]).write_all(&incr[..]).unwrap();
// read values back
assert_eq!(&incr[..], &mmap[..]);
}
#[test]
fn index() {
let mut mmap = MmapMut::map_anon(128).unwrap();
mmap[0] = 42;
assert_eq!(42, mmap[0]);
}
#[test]
fn sync_send() {
let mmap = MmapMut::map_anon(129).unwrap();
fn is_sync_send<T>(_val: T)
where
T: Sync + Send,
{
}
is_sync_send(mmap);
}
#[cfg(any(target_arch = "x86", target_arch = "x86_64"))]
fn jit_x86(mut mmap: MmapMut) {
mmap[0] = 0xB8; // mov eax, 0xAB
mmap[1] = 0xAB;
mmap[2] = 0x00;
mmap[3] = 0x00;
mmap[4] = 0x00;
mmap[5] = 0xC3; // ret
let mmap = mmap.make_exec().expect("make_exec");
let jitfn: extern "C" fn() -> u8 = unsafe { mem::transmute(mmap.as_ptr()) };
assert_eq!(jitfn(), 0xab);
}
#[test]
#[cfg(any(target_arch = "x86", target_arch = "x86_64"))]
fn jit_x86_anon() {
jit_x86(MmapMut::map_anon(4096).unwrap());
}
#[test]
#[cfg(any(target_arch = "x86", target_arch = "x86_64"))]
fn jit_x86_file() {
let tempdir = tempfile::tempdir().unwrap();
let mut options = OpenOptions::new();
#[cfg(windows)]
options.access_mode(GENERIC_ALL);
let file = options
.read(true)
.write(true)
.create(true)
.open(tempdir.path().join("jit_x86"))
.expect("open");
file.set_len(4096).expect("set_len");
jit_x86(unsafe { MmapMut::map_mut(&file).expect("map_mut") });
}
#[test]
fn mprotect_file() {
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmap");
let mut options = OpenOptions::new();
#[cfg(windows)]
options.access_mode(GENERIC_ALL);
let mut file = options
.read(true)
.write(true)
.create(true)
.open(path)
.expect("open");
file.set_len(256_u64).expect("set_len");
let mmap = unsafe { MmapMut::map_mut(&file).expect("map_mut") };
let mmap = mmap.make_read_only().expect("make_read_only");
let mut mmap = mmap.make_mut().expect("make_mut");
let write = b"abc123";
let mut read = [0u8; 6];
(&mut mmap[..]).write_all(write).unwrap();
mmap.flush().unwrap();
// The mmap contains the write
(&mmap[..]).read_exact(&mut read).unwrap();
assert_eq!(write, &read);
// The file should contain the write
file.read_exact(&mut read).unwrap();
assert_eq!(write, &read);
// another mmap should contain the write
let mmap2 = unsafe { MmapOptions::new().map(&file).unwrap() };
(&mmap2[..]).read_exact(&mut read).unwrap();
assert_eq!(write, &read);
let mmap = mmap.make_exec().expect("make_exec");
drop(mmap);
}
#[test]
fn mprotect_copy() {
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmap");
let mut options = OpenOptions::new();
#[cfg(windows)]
options.access_mode(GENERIC_ALL);
let mut file = options
.read(true)
.write(true)
.create(true)
.open(path)
.expect("open");
file.set_len(256_u64).expect("set_len");
let mmap = unsafe { MmapOptions::new().map_copy(&file).expect("map_mut") };
let mmap = mmap.make_read_only().expect("make_read_only");
let mut mmap = mmap.make_mut().expect("make_mut");
let nulls = b"\0\0\0\0\0\0";
let write = b"abc123";
let mut read = [0u8; 6];
(&mut mmap[..]).write_all(write).unwrap();
mmap.flush().unwrap();
// The mmap contains the write
(&mmap[..]).read_exact(&mut read).unwrap();
assert_eq!(write, &read);
// The file does not contain the write
file.read_exact(&mut read).unwrap();
assert_eq!(nulls, &read);
// another mmap does not contain the write
let mmap2 = unsafe { MmapOptions::new().map(&file).unwrap() };
(&mmap2[..]).read_exact(&mut read).unwrap();
assert_eq!(nulls, &read);
let mmap = mmap.make_exec().expect("make_exec");
drop(mmap);
}
#[test]
fn mprotect_anon() {
let mmap = MmapMut::map_anon(256).expect("map_mut");
let mmap = mmap.make_read_only().expect("make_read_only");
let mmap = mmap.make_mut().expect("make_mut");
let mmap = mmap.make_exec().expect("make_exec");
drop(mmap);
}
#[test]
fn raw() {
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmapraw");
let mut options = OpenOptions::new();
let mut file = options
.read(true)
.write(true)
.create(true)
.open(path)
.expect("open");
file.write_all(b"abc123").unwrap();
let mmap = MmapOptions::new().map_raw(&file).unwrap();
assert_eq!(mmap.len(), 6);
assert!(!mmap.as_ptr().is_null());
assert_eq!(unsafe { std::ptr::read(mmap.as_ptr()) }, b'a');
}
#[test]
fn raw_read_only() {
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmaprawro");
File::create(&path).unwrap().write_all(b"abc123").unwrap();
let mmap = MmapOptions::new()
.map_raw_read_only(&File::open(&path).unwrap())
.unwrap();
assert_eq!(mmap.len(), 6);
assert!(!mmap.as_ptr().is_null());
assert_eq!(unsafe { std::ptr::read(mmap.as_ptr()) }, b'a');
}
/// Something that relies on StableDeref
#[test]
#[cfg(feature = "stable_deref_trait")]
fn owning_ref() {
extern crate owning_ref;
let mut map = MmapMut::map_anon(128).unwrap();
map[10] = 42;
let owning = owning_ref::OwningRef::new(map);
let sliced = owning.map(|map| &map[10..20]);
assert_eq!(42, sliced[0]);
let map = sliced.into_owner().make_read_only().unwrap();
let owning = owning_ref::OwningRef::new(map);
let sliced = owning.map(|map| &map[10..20]);
assert_eq!(42, sliced[0]);
}
#[test]
#[cfg(unix)]
fn advise() {
let expected_len = 128;
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmap_advise");
let file = OpenOptions::new()
.read(true)
.write(true)
.create(true)
.open(path)
.unwrap();
file.set_len(expected_len as u64).unwrap();
// Test MmapMut::advise
let mut mmap = unsafe { MmapMut::map_mut(&file).unwrap() };
mmap.advise(Advice::Random)
.expect("mmap advising should be supported on unix");
let len = mmap.len();
assert_eq!(expected_len, len);
let zeros = vec![0; len];
let incr: Vec<u8> = (0..len as u8).collect();
// check that the mmap is empty
assert_eq!(&zeros[..], &mmap[..]);
mmap.advise_range(Advice::Sequential, 0, mmap.len())
.expect("mmap advising should be supported on unix");
// write values into the mmap
(&mut mmap[..]).write_all(&incr[..]).unwrap();
// read values back
assert_eq!(&incr[..], &mmap[..]);
// Set advice and Read from the read-only map
let mmap = unsafe { Mmap::map(&file).unwrap() };
mmap.advise(Advice::Random)
.expect("mmap advising should be supported on unix");
// read values back
assert_eq!(&incr[..], &mmap[..]);
}
#[test]
#[cfg(target_os = "linux")]
fn advise_writes_unsafely() {
let page_size = unsafe { libc::sysconf(libc::_SC_PAGESIZE) as usize };
let mut mmap = MmapMut::map_anon(page_size).unwrap();
mmap.as_mut().fill(255);
let mmap = mmap.make_read_only().unwrap();
let a = mmap.as_ref()[0];
unsafe {
mmap.unchecked_advise(crate::UncheckedAdvice::DontNeed)
.unwrap();
}
let b = mmap.as_ref()[0];
assert_eq!(a, 255);
assert_eq!(b, 0);
}
#[test]
#[cfg(target_os = "linux")]
fn advise_writes_unsafely_to_part_of_map() {
let page_size = unsafe { libc::sysconf(libc::_SC_PAGESIZE) as usize };
let mut mmap = MmapMut::map_anon(2 * page_size).unwrap();
mmap.as_mut().fill(255);
let mmap = mmap.make_read_only().unwrap();
let a = mmap.as_ref()[0];
let b = mmap.as_ref()[page_size];
unsafe {
mmap.unchecked_advise_range(crate::UncheckedAdvice::DontNeed, page_size, page_size)
.unwrap();
}
let c = mmap.as_ref()[0];
let d = mmap.as_ref()[page_size];
assert_eq!(a, 255);
assert_eq!(b, 255);
assert_eq!(c, 255);
assert_eq!(d, 0);
}
/// Returns true if a non-zero amount of memory is locked.
#[cfg(target_os = "linux")]
fn is_locked() -> bool {
let status = &std::fs::read_to_string("/proc/self/status")
.expect("/proc/self/status should be available");
for line in status.lines() {
if line.starts_with("VmLck:") {
let numbers = line.replace(|c: char| !c.is_ascii_digit(), "");
return numbers != "0";
}
}
panic!("cannot get VmLck information")
}
#[test]
#[cfg(unix)]
fn lock() {
let tempdir = tempfile::tempdir().unwrap();
let path = tempdir.path().join("mmap_lock");
let file = OpenOptions::new()
.read(true)
.write(true)
.create(true)
.open(path)
.unwrap();
file.set_len(128).unwrap();
let mmap = unsafe { Mmap::map(&file).unwrap() };
#[cfg(target_os = "linux")]
assert!(!is_locked());
mmap.lock().expect("mmap lock should be supported on unix");
#[cfg(target_os = "linux")]
assert!(is_locked());
mmap.lock()
.expect("mmap lock again should not cause problems");
#[cfg(target_os = "linux")]
assert!(is_locked());
mmap.unlock()
.expect("mmap unlock should be supported on unix");
#[cfg(target_os = "linux")]
assert!(!is_locked());
mmap.unlock()
.expect("mmap unlock again should not cause problems");
#[cfg(target_os = "linux")]
assert!(!is_locked());
}
#[test]
#[cfg(target_os = "linux")]
fn remap_grow() {
use crate::RemapOptions;
let initial_len = 128;
let final_len = 2000;
let zeros = vec![0u8; final_len];
let incr: Vec<u8> = (0..final_len).map(|v| v as u8).collect();
let file = tempfile::tempfile().unwrap();
file.set_len(final_len as u64).unwrap();
let mut mmap = unsafe { MmapOptions::new().len(initial_len).map_mut(&file).unwrap() };
assert_eq!(mmap.len(), initial_len);
assert_eq!(&mmap[..], &zeros[..initial_len]);
unsafe {
mmap.remap(final_len, RemapOptions::new().may_move(true))
.unwrap()
};
// The size should have been updated
assert_eq!(mmap.len(), final_len);
// Should still be all zeros
assert_eq!(&mmap[..], &zeros);
// Write out to the whole expanded slice.
mmap.copy_from_slice(&incr);
}
#[test]
#[cfg(target_os = "linux")]
fn remap_shrink() {
use crate::RemapOptions;
let initial_len = 20000;
let final_len = 400;
let incr: Vec<u8> = (0..final_len).map(|v| v as u8).collect();
let file = tempfile::tempfile().unwrap();
file.set_len(initial_len as u64).unwrap();
let mut mmap = unsafe { MmapMut::map_mut(&file).unwrap() };
assert_eq!(mmap.len(), initial_len);
unsafe { mmap.remap(final_len, RemapOptions::new()).unwrap() };
assert_eq!(mmap.len(), final_len);
// Check that the mmap is still writable along the slice length
mmap.copy_from_slice(&incr);
}
#[test]
#[cfg(target_os = "linux")]
#[cfg(target_pointer_width = "32")]
fn remap_len_overflow() {
use crate::RemapOptions;
let file = tempfile::tempfile().unwrap();
file.set_len(1024).unwrap();
let mut mmap = unsafe { MmapOptions::new().len(1024).map(&file).unwrap() };
let res = unsafe { mmap.remap(0x80000000, RemapOptions::new().may_move(true)) };
assert_eq!(
res.unwrap_err().to_string(),
"memory map length overflows isize"
);
assert_eq!(mmap.len(), 1024);
}
#[test]
#[cfg(target_os = "linux")]
fn remap_with_offset() {
use crate::RemapOptions;
let offset = 77;
let initial_len = 128;
let final_len = 2000;
let zeros = vec![0u8; final_len];
let incr: Vec<u8> = (0..final_len).map(|v| v as u8).collect();
let file = tempfile::tempfile().unwrap();
file.set_len(final_len as u64 + offset).unwrap();
let mut mmap = unsafe {
MmapOptions::new()
.len(initial_len)
.offset(offset)
.map_mut(&file)
.unwrap()
};
assert_eq!(mmap.len(), initial_len);
assert_eq!(&mmap[..], &zeros[..initial_len]);
unsafe {
mmap.remap(final_len, RemapOptions::new().may_move(true))
.unwrap()
};
// The size should have been updated
assert_eq!(mmap.len(), final_len);
// Should still be all zeros
assert_eq!(&mmap[..], &zeros);
// Write out to the whole expanded slice.
mmap.copy_from_slice(&incr);
}
}