Function sp_std::ptr::write 1.0.0[−][src]
pub unsafe fn write<T>(dst: *mut T, src: T)
Overwrites a memory location with the given value without reading or dropping the old value.
write
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
from.
Safety
Behavior is undefined if any of the following conditions are violated:
-
dst
must be valid for writes. -
dst
must be properly aligned. Usewrite_unaligned
if this is not the case.
Note that even if T
has size 0
, the pointer must be non-NULL and properly aligned.
Examples
Basic usage:
let mut x = 0; let y = &mut x as *mut i32; let z = 12; unsafe { std::ptr::write(y, z); assert_eq!(std::ptr::read(y), 12); }
Manually implement mem::swap
:
use std::ptr; fn swap<T>(a: &mut T, b: &mut T) { unsafe { // Create a bitwise copy of the value at `a` in `tmp`. let tmp = ptr::read(a); // Exiting at this point (either by explicitly returning or by // calling a function which panics) would cause the value in `tmp` to // be dropped while the same value is still referenced by `a`. This // could trigger undefined behavior if `T` is not `Copy`. // Create a bitwise copy of the value at `b` in `a`. // This is safe because mutable references cannot alias. ptr::copy_nonoverlapping(b, a, 1); // As above, exiting here could trigger undefined behavior because // the same value is referenced by `a` and `b`. // Move `tmp` into `b`. ptr::write(b, tmp); // `tmp` has been moved (`write` takes ownership of its second argument), // so nothing is dropped implicitly here. } } let mut foo = "foo".to_owned(); let mut bar = "bar".to_owned(); swap(&mut foo, &mut bar); assert_eq!(foo, "bar"); assert_eq!(bar, "foo");