pub const unsafe fn write_unaligned<T>(dst: *mut T, src: T)
Expand description
Overwrites a memory location with the given value without reading or dropping the old value.
Unlike write()
, the pointer may be unaligned.
write_unaligned
does not drop the contents of dst
. This is safe, but it
could leak allocations or resources, so care should be taken not to overwrite
an object that should be dropped.
Additionally, it does not drop src
. Semantically, src
is moved into the
location pointed to by dst
.
This is appropriate for initializing uninitialized memory, or overwriting
memory that has previously been read with read_unaligned
.
§Safety
Behavior is undefined if any of the following conditions are violated:
dst
must be valid for writes.
Note that even if T
has size 0
, the pointer must be non-null.
§On packed
structs
Attempting to create a raw pointer to an unaligned
struct field with
an expression such as &packed.unaligned as *const FieldType
creates an
intermediate unaligned reference before converting that to a raw pointer.
That this reference is temporary and immediately cast is inconsequential
as the compiler always expects references to be properly aligned.
As a result, using &packed.unaligned as *const FieldType
causes immediate
undefined behavior in your program.
Instead, you must use the ptr::addr_of_mut!
macro to create the pointer. You may use that returned pointer together with
this function.
An example of how to do it and how this relates to write_unaligned
is:
#[repr(packed, C)]
struct Packed {
_padding: u8,
unaligned: u32,
}
let mut packed: Packed = unsafe { std::mem::zeroed() };
// Take the address of a 32-bit integer which is not aligned.
// In contrast to `&packed.unaligned as *mut _`, this has no undefined behavior.
let unaligned = std::ptr::addr_of_mut!(packed.unaligned);
unsafe { std::ptr::write_unaligned(unaligned, 42) };
assert_eq!({packed.unaligned}, 42); // `{...}` forces copying the field instead of creating a reference.
Accessing unaligned fields directly with e.g. packed.unaligned
is safe however
(as can be seen in the assert_eq!
above).
§Examples
Write a usize
value to a byte buffer:
use std::mem;
fn write_usize(x: &mut [u8], val: usize) {
assert!(x.len() >= mem::size_of::<usize>());
let ptr = x.as_mut_ptr() as *mut usize;
unsafe { ptr.write_unaligned(val) }
}