Trait sp_std::alloc::GlobalAlloc 1.28.0[−][src]
pub unsafe trait GlobalAlloc { unsafe fn alloc(&self, layout: Layout) -> *mut u8; unsafe fn dealloc(&self, ptr: *mut u8, layout: Layout); unsafe fn alloc_zeroed(&self, layout: Layout) -> *mut u8 { ... } unsafe fn realloc(
&self,
ptr: *mut u8,
layout: Layout,
new_size: usize
) -> *mut u8 { ... } }
Expand description
A memory allocator that can be registered as the standard library’s default
through the #[global_allocator]
attribute.
Some of the methods require that a memory block be currently allocated via an allocator. This means that:
-
the starting address for that memory block was previously returned by a previous call to an allocation method such as
alloc
, and -
the memory block has not been subsequently deallocated, where blocks are deallocated either by being passed to a deallocation method such as
dealloc
or by being passed to a reallocation method that returns a non-null pointer.
Example
use std::alloc::{GlobalAlloc, Layout, alloc}; use std::ptr::null_mut; struct MyAllocator; unsafe impl GlobalAlloc for MyAllocator { unsafe fn alloc(&self, _layout: Layout) -> *mut u8 { null_mut() } unsafe fn dealloc(&self, _ptr: *mut u8, _layout: Layout) {} } #[global_allocator] static A: MyAllocator = MyAllocator; fn main() { unsafe { assert!(alloc(Layout::new::<u32>()).is_null()) } }
Safety
The GlobalAlloc
trait is an unsafe
trait for a number of reasons, and
implementors must ensure that they adhere to these contracts:
-
It’s undefined behavior if global allocators unwind. This restriction may be lifted in the future, but currently a panic from any of these functions may lead to memory unsafety.
-
Layout
queries and calculations in general must be correct. Callers of this trait are allowed to rely on the contracts defined on each method, and implementors must ensure such contracts remain true. -
You may not rely on allocations actually happening, even if there are explicit heap allocations in the source. The optimizer may detect unused allocations that it can either eliminate entirely or move to the stack and thus never invoke the allocator. The optimizer may further assume that allocation is infallible, so code that used to fail due to allocator failures may now suddenly work because the optimizer worked around the need for an allocation. More concretely, the following code example is unsound, irrespective of whether your custom allocator allows counting how many allocations have happened.
ⓘdrop(Box::new(42)); let number_of_heap_allocs = /* call private allocator API */; unsafe { std::intrinsics::assume(number_of_heap_allocs > 0); }
Note that the optimizations mentioned above are not the only optimization that can be applied. You may generally not rely on heap allocations happening if they can be removed without changing program behavior. Whether allocations happen or not is not part of the program behavior, even if it could be detected via an allocator that tracks allocations by printing or otherwise having side effects.
Required methods
Allocate memory as described by the given layout
.
Returns a pointer to newly-allocated memory, or null to indicate allocation failure.
Safety
This function is unsafe because undefined behavior can result
if the caller does not ensure that layout
has non-zero size.
(Extension subtraits might provide more specific bounds on behavior, e.g., guarantee a sentinel address or a null pointer in response to a zero-size allocation request.)
The allocated block of memory may or may not be initialized.
Errors
Returning a null pointer indicates that either memory is exhausted
or layout
does not meet this allocator’s size or alignment constraints.
Implementations are encouraged to return null on memory exhaustion rather than aborting, but this is not a strict requirement. (Specifically: it is legal to implement this trait atop an underlying native allocation library that aborts on memory exhaustion.)
Clients wishing to abort computation in response to an
allocation error are encouraged to call the handle_alloc_error
function,
rather than directly invoking panic!
or similar.
Deallocate the block of memory at the given ptr
pointer with the given layout
.
Safety
This function is unsafe because undefined behavior can result if the caller does not ensure all of the following:
-
ptr
must denote a block of memory currently allocated via this allocator, -
layout
must be the same layout that was used to allocate that block of memory.
Provided methods
unsafe fn alloc_zeroed(&self, layout: Layout) -> *mut u8
unsafe fn alloc_zeroed(&self, layout: Layout) -> *mut u8
Behaves like alloc
, but also ensures that the contents
are set to zero before being returned.
Safety
This function is unsafe for the same reasons that alloc
is.
However the allocated block of memory is guaranteed to be initialized.
Errors
Returning a null pointer indicates that either memory is exhausted
or layout
does not meet allocator’s size or alignment constraints,
just as in alloc
.
Clients wishing to abort computation in response to an
allocation error are encouraged to call the handle_alloc_error
function,
rather than directly invoking panic!
or similar.
Shrink or grow a block of memory to the given new_size
.
The block is described by the given ptr
pointer and layout
.
If this returns a non-null pointer, then ownership of the memory block
referenced by ptr
has been transferred to this allocator.
The memory may or may not have been deallocated,
and should be considered unusable (unless of course it was
transferred back to the caller again via the return value of
this method). The new memory block is allocated with layout
, but
with the size
updated to new_size
. This new layout should be
used when deallocating the new memory block with dealloc
. The range
0..min(layout.size(), new_size)
of the new memory block is
guaranteed to have the same values as the original block.
If this method returns null, then ownership of the memory block has not been transferred to this allocator, and the contents of the memory block are unaltered.
Safety
This function is unsafe because undefined behavior can result if the caller does not ensure all of the following:
-
ptr
must be currently allocated via this allocator, -
layout
must be the same layout that was used to allocate that block of memory, -
new_size
must be greater than zero. -
new_size
, when rounded up to the nearest multiple oflayout.align()
, must not overflow (i.e., the rounded value must be less thanusize::MAX
).
(Extension subtraits might provide more specific bounds on behavior, e.g., guarantee a sentinel address or a null pointer in response to a zero-size allocation request.)
Errors
Returns null if the new layout does not meet the size and alignment constraints of the allocator, or if reallocation otherwise fails.
Implementations are encouraged to return null on memory exhaustion rather than panicking or aborting, but this is not a strict requirement. (Specifically: it is legal to implement this trait atop an underlying native allocation library that aborts on memory exhaustion.)
Clients wishing to abort computation in response to a
reallocation error are encouraged to call the handle_alloc_error
function,
rather than directly invoking panic!
or similar.