Enum BitDomain
pub enum BitDomain<'a, M = Const, T = usize, O = Lsb0>where
M: Mutability,
T: 'a + BitStore,
O: BitOrder,
Address<M, BitSlice<T, O>>: Referential<'a>,
Address<M, BitSlice<<T as BitStore>::Unalias, O>>: Referential<'a>,{
Enclave(<Address<M, BitSlice<T, O>> as Referential<'a>>::Ref),
Region {
head: <Address<M, BitSlice<T, O>> as Referential<'a>>::Ref,
body: <Address<M, BitSlice<<T as BitStore>::Unalias, O>> as Referential<'a>>::Ref,
tail: <Address<M, BitSlice<T, O>> as Referential<'a>>::Ref,
},
}
Expand description
§Bit-Slice Partitioning
This enum partitions a bit-slice into its head- and tail- edge bit-slices, and its interior body bit-slice, according to the definitions laid out in the module documentation.
It fragments a BitSlice
into smaller BitSlice
s, and allows the interior
bit-slice to become ::Unalias
ed. This is useful when you need to retain a
bit-slice view of memory, but wish to remove synchronization costs imposed by a
prior call to .split_at_mut()
for as much of the bit-slice as possible.
§Why Not Option
?
The Enclave
variant always contains as its single field the exact bit-slice
that created the Enclave
. As such, this type is easily replaceäble with an
Option
of the Region
variant, which when None
is understood to be the
original.
This exists as a dedicated enum, even with a technically useless variant, in
order to mirror the shape of the element-domain enum. This type should be
understood as a shortcut to the end result of splitting by element-domain, then
mapping each PartialElement
and slice back into BitSlice
s, rather than
testing whether a bit-slice can be split on alias boundaries.
You can get the alternate behavior, of testing whether or not a bit-slice can be
split into a Region
or is unsplittable, by calling .bit_domain().region()
to produce exactly such an Option
.
Variants§
Enclave(<Address<M, BitSlice<T, O>> as Referential<'a>>::Ref)
Indicates that a bit-slice’s contents are entirely in the interior indices of a single memory element.
The contained value is always the bit-slice that created this view.
Region
Indicates that a bit-slice’s contents touch an element edge.
This splits the bit-slice into three partitions, each of which may be empty: two partially-occupied edge elements, with their original type status, and one interior span, which is known to not have any other aliases derived from the bit-slice that created this view.
Fields
head: <Address<M, BitSlice<T, O>> as Referential<'a>>::Ref
Any bits that partially-fill the first element of the underlying storage region.
This does not modify its aliasing status, as it will already be appropriately marked before this view is constructed.
body: <Address<M, BitSlice<<T as BitStore>::Unalias, O>> as Referential<'a>>::Ref
Any bits that wholly-fill elements in the interior of the bit-slice.
This is marked as unaliased, because it is statically impossible for
any other handle derived from the source bit-slice to have
conflicting access to the region of memory it describes. As such,
even a bit-slice that was marked as ::Alias
can revert this
protection on the known-unaliased interior.
Proofs:
- Rust’s
&
/&mut
exclusion rules universally apply. If a reference exists, no other reference has unsynchronized write capability. BitStore::Unalias
only modifies unsynchronized types.Cell
and atomic types unalias to themselves, and retain their original behavior.
Implementations§
§impl<'a, M, T, O> BitDomain<'a, M, T, O>
impl<'a, M, T, O> BitDomain<'a, M, T, O>
pub fn enclave(
self,
) -> Option<<Address<M, BitSlice<T, O>> as Referential<'a>>::Ref>
pub fn enclave( self, ) -> Option<<Address<M, BitSlice<T, O>> as Referential<'a>>::Ref>
Attempts to unpack the bit-domain as an Enclave
variant. This is
just a shorthand for explicit destructuring.
pub fn region(
self,
) -> Option<(<Address<M, BitSlice<T, O>> as Referential<'a>>::Ref, <Address<M, BitSlice<<T as BitStore>::Unalias, O>> as Referential<'a>>::Ref, <Address<M, BitSlice<T, O>> as Referential<'a>>::Ref)>
pub fn region( self, ) -> Option<(<Address<M, BitSlice<T, O>> as Referential<'a>>::Ref, <Address<M, BitSlice<<T as BitStore>::Unalias, O>> as Referential<'a>>::Ref, <Address<M, BitSlice<T, O>> as Referential<'a>>::Ref)>
Attempts to unpack the bit-domain as a Region
variant. This is just
a shorthand for explicit destructuring.
Trait Implementations§
§impl<'a, M, T, O> Debug for BitDomain<'a, M, T, O>where
M: Mutability,
T: 'a + BitStore,
O: BitOrder,
Address<M, BitSlice<T, O>>: Referential<'a>,
Address<M, BitSlice<<T as BitStore>::Unalias, O>>: Referential<'a>,
<Address<M, BitSlice<T, O>> as Referential<'a>>::Ref: Debug,
<Address<M, BitSlice<<T as BitStore>::Unalias, O>> as Referential<'a>>::Ref: Debug,
impl<'a, M, T, O> Debug for BitDomain<'a, M, T, O>where
M: Mutability,
T: 'a + BitStore,
O: BitOrder,
Address<M, BitSlice<T, O>>: Referential<'a>,
Address<M, BitSlice<<T as BitStore>::Unalias, O>>: Referential<'a>,
<Address<M, BitSlice<T, O>> as Referential<'a>>::Ref: Debug,
<Address<M, BitSlice<<T as BitStore>::Unalias, O>> as Referential<'a>>::Ref: Debug,
§impl<'a, M, T, O> Default for BitDomain<'a, M, T, O>where
M: Mutability,
T: 'a + BitStore,
O: BitOrder,
Address<M, BitSlice<T, O>>: Referential<'a>,
Address<M, BitSlice<<T as BitStore>::Unalias, O>>: Referential<'a>,
<Address<M, BitSlice<T, O>> as Referential<'a>>::Ref: Default,
<Address<M, BitSlice<<T as BitStore>::Unalias, O>> as Referential<'a>>::Ref: Default,
impl<'a, M, T, O> Default for BitDomain<'a, M, T, O>where
M: Mutability,
T: 'a + BitStore,
O: BitOrder,
Address<M, BitSlice<T, O>>: Referential<'a>,
Address<M, BitSlice<<T as BitStore>::Unalias, O>>: Referential<'a>,
<Address<M, BitSlice<T, O>> as Referential<'a>>::Ref: Default,
<Address<M, BitSlice<<T as BitStore>::Unalias, O>> as Referential<'a>>::Ref: Default,
impl<T, O> Copy for BitDomain<'_, Const, T, O>
Auto Trait Implementations§
impl<'a, M = Const, T = usize, O = Lsb0> !Freeze for BitDomain<'a, M, T, O>
impl<'a, M = Const, T = usize, O = Lsb0> !RefUnwindSafe for BitDomain<'a, M, T, O>
impl<'a, M = Const, T = usize, O = Lsb0> !Send for BitDomain<'a, M, T, O>
impl<'a, M = Const, T = usize, O = Lsb0> !Sync for BitDomain<'a, M, T, O>
impl<'a, M = Const, T = usize, O = Lsb0> !Unpin for BitDomain<'a, M, T, O>
impl<'a, M = Const, T = usize, O = Lsb0> !UnwindSafe for BitDomain<'a, M, T, O>
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