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|
#![cfg(feature = "mman")]
#![allow(clippy::redundant_slicing)]
use nix::sys::mman::{mmap_anonymous, MapFlags, ProtFlags};
use std::num::NonZeroUsize;
#[test]
fn test_mmap_anonymous() {
unsafe {
let mut ptr = mmap_anonymous(
None,
NonZeroUsize::new(1).unwrap(),
ProtFlags::PROT_READ | ProtFlags::PROT_WRITE,
MapFlags::MAP_PRIVATE,
)
.unwrap()
.cast::<u8>();
assert_eq!(*ptr.as_ref(), 0x00u8);
*ptr.as_mut() = 0xffu8;
assert_eq!(*ptr.as_ref(), 0xffu8);
}
}
#[test]
#[cfg(any(target_os = "linux", target_os = "netbsd"))]
fn test_mremap_grow() {
use nix::libc::size_t;
use nix::sys::mman::{mremap, MRemapFlags};
use std::ptr::NonNull;
const ONE_K: size_t = 1024;
let one_k_non_zero = NonZeroUsize::new(ONE_K).unwrap();
let slice: &mut [u8] = unsafe {
let mem = mmap_anonymous(
None,
one_k_non_zero,
ProtFlags::PROT_READ | ProtFlags::PROT_WRITE,
MapFlags::MAP_PRIVATE,
)
.unwrap();
std::slice::from_raw_parts_mut(mem.as_ptr().cast(), ONE_K)
};
assert_eq!(slice[ONE_K - 1], 0x00);
slice[ONE_K - 1] = 0xFF;
assert_eq!(slice[ONE_K - 1], 0xFF);
let slice: &mut [u8] = unsafe {
#[cfg(target_os = "linux")]
let mem = mremap(
NonNull::from(&mut slice[..]).cast(),
ONE_K,
10 * ONE_K,
MRemapFlags::MREMAP_MAYMOVE,
None,
)
.unwrap();
#[cfg(target_os = "netbsd")]
let mem = mremap(
NonNull::from(&mut slice[..]).cast(),
ONE_K,
10 * ONE_K,
MRemapFlags::MAP_REMAPDUP,
None,
)
.unwrap();
std::slice::from_raw_parts_mut(mem.cast().as_ptr(), 10 * ONE_K)
};
// The first KB should still have the old data in it.
assert_eq!(slice[ONE_K - 1], 0xFF);
// The additional range should be zero-init'd and accessible.
assert_eq!(slice[10 * ONE_K - 1], 0x00);
slice[10 * ONE_K - 1] = 0xFF;
assert_eq!(slice[10 * ONE_K - 1], 0xFF);
}
#[test]
#[cfg(any(target_os = "linux", target_os = "netbsd"))]
// Segfaults for unknown reasons under QEMU for 32-bit targets
#[cfg_attr(all(target_pointer_width = "32", qemu), ignore)]
fn test_mremap_shrink() {
use nix::libc::size_t;
use nix::sys::mman::{mremap, MRemapFlags};
use std::num::NonZeroUsize;
use std::ptr::NonNull;
const ONE_K: size_t = 1024;
let ten_one_k = NonZeroUsize::new(10 * ONE_K).unwrap();
let slice: &mut [u8] = unsafe {
let mem = mmap_anonymous(
None,
ten_one_k,
ProtFlags::PROT_READ | ProtFlags::PROT_WRITE,
MapFlags::MAP_PRIVATE,
)
.unwrap();
std::slice::from_raw_parts_mut(mem.as_ptr().cast(), ONE_K)
};
assert_eq!(slice[ONE_K - 1], 0x00);
slice[ONE_K - 1] = 0xFF;
assert_eq!(slice[ONE_K - 1], 0xFF);
let slice: &mut [u8] = unsafe {
let mem = mremap(
NonNull::from(&mut slice[..]).cast(),
ten_one_k.into(),
ONE_K,
MRemapFlags::empty(),
None,
)
.unwrap();
// Since we didn't supply MREMAP_MAYMOVE, the address should be the
// same.
assert_eq!(mem.as_ptr(), NonNull::from(&mut slice[..]).cast().as_ptr());
std::slice::from_raw_parts_mut(mem.as_ptr().cast(), ONE_K)
};
// The first KB should still be accessible and have the old data in it.
assert_eq!(slice[ONE_K - 1], 0xFF);
}
#[test]
#[cfg(target_os = "linux")]
fn test_mremap_dontunmap() {
use nix::libc::size_t;
use nix::sys::mman::{mremap, MRemapFlags};
use std::num::NonZeroUsize;
use std::ptr::NonNull;
const ONE_K: size_t = 1024;
let one_k_non_zero = NonZeroUsize::new(ONE_K).unwrap();
let slice: &mut [u8] = unsafe {
let mem = mmap_anonymous(
None,
one_k_non_zero,
ProtFlags::PROT_READ | ProtFlags::PROT_WRITE,
MapFlags::MAP_PRIVATE,
)
.unwrap();
std::slice::from_raw_parts_mut(mem.as_ptr().cast(), ONE_K)
};
// because we do not unmap `slice`, `old_size` and `new_size`
// need to be equal or `EINVAL` is set.
let _new_slice: &mut [u8] = unsafe {
let mem = mremap(
NonNull::from(&mut slice[..]).cast(),
ONE_K,
ONE_K,
MRemapFlags::MREMAP_MAYMOVE | MRemapFlags::MREMAP_DONTUNMAP,
None,
)
.unwrap();
std::slice::from_raw_parts_mut(mem.cast().as_ptr(), 10 * ONE_K)
};
}
#[test]
#[cfg(target_os = "linux")]
#[cfg(feature = "signal")]
fn test_madv_wipeonfork() {
use nix::libc::size_t;
use nix::sys::mman::{madvise, MmapAdvise};
use nix::unistd::{fork, ForkResult};
use std::num::NonZeroUsize;
const ONE_K: size_t = 1024;
let ten_one_k = NonZeroUsize::new(10 * ONE_K).unwrap();
let slice: &mut [u8] = unsafe {
let mem = mmap_anonymous(
None,
ten_one_k,
ProtFlags::PROT_READ | ProtFlags::PROT_WRITE,
MapFlags::MAP_PRIVATE,
)
.unwrap();
madvise(mem, ONE_K, MmapAdvise::MADV_WIPEONFORK)
.expect("madvise failed");
std::slice::from_raw_parts_mut(mem.as_ptr().cast(), ONE_K)
};
slice[ONE_K - 1] = 0xFF;
let _m = crate::FORK_MTX.lock();
unsafe {
let res = fork().expect("fork failed");
match res {
ForkResult::Child => {
// that s the whole point of MADV_WIPEONFORK
assert_eq!(slice[ONE_K - 1], 0x00);
libc::_exit(0);
}
ForkResult::Parent { child } => {
nix::sys::signal::kill(child, nix::sys::signal::SIGTERM)
.unwrap();
let _ = nix::sys::wait::wait().unwrap();
}
}
}
}
|
