fabaccess-bffh/bffhd/resources/state/value.rs

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use std::{any::Any, fmt, hash::Hash, ptr, str::FromStr};
use ptr_meta::{DynMetadata, Pointee};
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use rkyv::{out_field, Archive, ArchivePointee, ArchiveUnsized, Archived, ArchivedMetadata, Deserialize, DeserializeUnsized, Fallible, Serialize, SerializeUnsized, RelPtr};
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use rkyv_dyn::{DynDeserializer, DynError, DynSerializer};
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use crate::utils::oid::ObjectIdentifier;
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// Not using linkme because dynamically loaded modules
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use inventory;
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use rkyv::ser::{ScratchSpace, Serializer};
use serde::de::Error as SerdeError;
use serde::ser::SerializeMap;
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use std::alloc::Layout;
use std::collections::HashMap;
use std::fmt::Formatter;
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use std::mem::MaybeUninit;
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use std::ops::Deref;
use std::sync::atomic::{AtomicUsize, Ordering};
use rkyv::boxed::{ArchivedBox, BoxResolver};
use rkyv::vec::ArchivedVec;
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#[repr(transparent)]
struct MetaBox<T: ?Sized>(Box<T>);
impl<T: ?Sized> From<Box<T>> for MetaBox<T> {
fn from(b: Box<T>) -> Self {
Self(b)
}
}
#[repr(transparent)]
struct ArchivedMetaBox<T: ArchivePointee + ?Sized>(RelPtr<T>);
impl<T: ArchivePointee + ?Sized> ArchivedMetaBox<T> {
#[inline]
pub fn get(&self) -> &T {
unsafe { &*self.0.as_ptr() }
}
}
impl<T: ArchivePointee + ?Sized> AsRef<T> for ArchivedMetaBox<T> {
fn as_ref(&self) -> &T {
self.get()
}
}
impl<T: ArchivePointee + ?Sized> Deref for ArchivedMetaBox<T> {
type Target = T;
#[inline]
fn deref(&self) -> &Self::Target {
self.get()
}
}
// State built as
struct NewStateBuilder {
inner: Vec<MetaBox<dyn SerializeStateValue>>,
}
// turns into
struct NewState {
inner: ArchivedVec<ArchivedMetaBox<dyn ArchivedStateValue>>
}
impl NewState {
pub fn get_value<T: TypeOid>(&self) -> Option<&T> {
/*
let target_oid = T::type_oid();
let values = self.inner.as_slice();
for v in values {
let oid: &Archived<ObjectIdentifier> = &v.metadata().type_oid;
if &target_oid.deref() == &oid.deref() {
let value = unsafe { &*v.as_ptr().cast() };
return Some(value);
}
}
None
*/
unimplemented!()
}
}
// for usage.
// The important part is that both `SerializeValue` and `Value` tell us their OIDs. State will
// usually consist of only a very small number of parts, most of the time just one, so linear
// search will be the best.
// `dyn Value` is Archived using custom sauce Metadata that will store the OID of the state
// value, allowing us to cast the object (reasonably) safely. Thus we can also add a
// method `get_part<T: Value>(&self) -> Option<&T>`
// ArchivedBox is just a RelPtr into the object; so we'd use an `ArchivedValue<NewDesignState>`.
// We can freely modify the memory of the value, so caching vtables is possible & sensible?
// For dumping / loading values using serde we have to be able to serialize a `dyn Value` and to
// deserialize a `dyn SerializeValue`.
// This means, for every type T that's a value we must have:
// - impl SerializeValue for T, which probably implies impl Value for T?
// - impl Value for Archived<T>
// - impl serde::Deserialize for T
// - impl serde::Serialize for Archived<T>
// - impl rkyv::Archive, rkyv::Serialize for T
#[ptr_meta::pointee]
/// Trait that values in the State Builder have to implement
///
/// It requires serde::Deserialize and rkyv::SerializeUnsized to be implemented.
///
/// it is assumed that there is a 1:1 mapping between a SerializeStateValue and a StateValue
/// implementation. Every `T` implementing the former has exactly *one* `Archived<T>` implementing
/// the latter.
///
/// The archived version of any implementation must implement [ArchivedStateValue](trait@ArchivedStateValue).
pub trait SerializeStateValue: SerializeDynOid {}
#[ptr_meta::pointee]
/// Trait that (rkyv'ed) values in the State Object have to implement.
///
/// It requires serde::Serialize to be implemented.
///
/// It must be Sync since the State is sent as a signal to all connected actors by reference.
/// It must be Send since the DB thread and the signal thread may be different.
pub trait ArchivedStateValue: Send + Sync {}
/// Serializing a trait object by storing an OID alongside
///
/// This trait is a dependency for [SerializeStateValue](trait@SerializeStateValue). It is by
/// default implemented for all `T where T: for<'a> Serialize<dyn DynSerializer + 'a>, T::Archived: TypeOid`.
pub trait SerializeDynOid {
/// Return the OID associated with the **Archived** type, i.e. `Archived<Self>`.
///
/// This OID will be serialized alongside the trait object and is used to retrieve the
/// correct vtable when loading the state from DB.
fn archived_type_oid(&self) -> &'static ObjectIdentifier;
/// Serialize this type into a [`DynSerializer`](trait@DynSerializer)
fn serialize_dynoid(&self, serializer: &mut dyn DynSerializer) -> Result<usize, DynError>;
}
/// Types with an associated OID
///
/// This trait is required by the default implementation of [SerializeDynOid](trait@SerializeDynOid),
/// providing the OID that is serialized alongside the state object to be able to correctly cast
/// it when accessing state from the DB.
pub trait TypeOid {
fn type_oid() -> &'static ObjectIdentifier;
fn type_name() -> &'static str;
}
impl<T> SerializeDynOid for T
where
T: for<'a> Serialize<dyn DynSerializer + 'a>,
T::Archived: TypeOid,
{
fn archived_type_oid(&self) -> &'static ObjectIdentifier {
Archived::<T>::type_oid()
}
fn serialize_dynoid(&self, serializer: &mut dyn DynSerializer) -> Result<usize, DynError> {
serializer.serialize_value(self)
}
}
impl ArchivePointee for dyn ArchivedStateValue {
type ArchivedMetadata = ArchivedStateValueMetadata;
fn pointer_metadata(archived: &Self::ArchivedMetadata) -> <Self as Pointee>::Metadata {
archived.pointer_metadata()
}
}
impl ArchiveUnsized for dyn SerializeStateValue {
type Archived = dyn ArchivedStateValue;
type MetadataResolver = <ObjectIdentifier as Archive>::Resolver;
unsafe fn resolve_metadata(
&self,
pos: usize,
resolver: Self::MetadataResolver,
out: *mut ArchivedMetadata<Self>, // => ArchivedStateValueMetadata
) {
let (oid_pos, oid) = out_field!(out.type_oid);
let type_oid = self.archived_type_oid();
type_oid.resolve(pos + oid_pos, resolver, oid);
let (_vtable_cache_pos, vtable_cache) = out_field!(out.vtable_cache);
*vtable_cache = AtomicUsize::default();
}
}
impl<S: ScratchSpace + Serializer + ?Sized> SerializeUnsized<S> for dyn SerializeStateValue {
fn serialize_unsized(&self, mut serializer: &mut S) -> Result<usize, S::Error> {
self.serialize_dynoid(&mut serializer)
.map_err(|e| *e.downcast::<S::Error>().unwrap())
}
fn serialize_metadata(&self, serializer: &mut S) -> Result<Self::MetadataResolver, S::Error> {
let oid = self.archived_type_oid();
oid.serialize(serializer)
}
}
#[derive(Debug)]
pub struct ArchivedStateValueMetadata {
pub type_oid: Archived<ObjectIdentifier>,
vtable_cache: AtomicUsize,
}
impl ArchivedStateValueMetadata {
// TODO: `usize as *const VTable` is not sane.
pub fn vtable(&self) -> usize {
let val = self.vtable_cache.load(Ordering::Relaxed);
if val != 0 {
return val;
}
let val = IMPL_REGISTRY
.get(ImplId::from_type_oid(&self.type_oid))
.expect(&format!("Unregistered type oid {:?}", self.type_oid))
.vtable;
self.vtable_cache.store(val, Ordering::Relaxed);
return val;
}
pub fn pointer_metadata(&self) -> DynMetadata<dyn ArchivedStateValue> {
unsafe { core::mem::transmute(self.vtable()) }
}
}
#[derive(Copy, Clone, Debug, Hash, Eq, PartialEq)]
/// OID of an [ArchivedStateValue](trait@ArchivedStateValue) implementation.
///
/// Used by the global type registry of all implementations to look up the vtables of state values
/// when accessing it from DB and when (de-)serializing it using serde.
struct ImplId<'a> {
type_oid: &'a [u8],
}
impl<'a> ImplId<'a> {
fn from_type_oid(type_oid: &'a [u8]) -> Self {
Self { type_oid }
}
}
impl ImplId<'static> {
fn new<T: TypeOid>() -> Self {
Self {
type_oid: &T::type_oid(),
}
}
}
#[derive(Copy, Clone, Debug)]
struct ImplData<'a> {
pub vtable: usize,
pub name: &'a str,
pub info: ImplDebugInfo,
}
#[derive(Copy, Clone, Debug)]
pub struct ImplDebugInfo {
pub file: &'static str,
pub line: u32,
pub column: u32,
}
#[derive(Debug)]
/// State Value Implementation Entry
///
/// To register a state implementation you must call [inventory::collect](macro@inventory::collect)
/// macro for an Entry constructed for your type on top level. Your type will have to have
/// implementations of [TypeOid](trait@TypeOid) and [RegisteredImpl](trait@RegisteredImpl)
/// Alternatively you can use the
/// [statevalue_register](macro@crate::statevalue_register) macro with your OID as first and type
/// as second parameter like so:
///
/// ```no_run
/// struct MyStruct;
/// statevalue_register!(ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.1.14").unwrap(), MyStruct)
/// ```
pub struct ImplEntry<'a> {
id: ImplId<'a>,
data: ImplData<'a>,
}
inventory::collect!(ImplEntry<'static>);
impl ImplEntry<'_> {
pub fn new<T: TypeOid + RegisteredImpl>() -> Self {
Self {
id: ImplId::new::<T>(),
data: ImplData {
vtable: <T as RegisteredImpl>::vtable(),
name: <T as TypeOid>::type_name(),
info: <T as RegisteredImpl>::debug_info(),
},
}
}
}
#[derive(Debug)]
struct ImplRegistry {
oid_to_data: HashMap<ImplId<'static>, ImplData<'static>>,
}
impl ImplRegistry {
fn new() -> Self {
Self {
oid_to_data: HashMap::new(),
}
}
fn add_entry(&mut self, entry: &'static ImplEntry) {
let old_val = self.oid_to_data.insert(entry.id, entry.data);
if let Some(old) = old_val {
eprintln!("Value impl oid conflict for {:?}", entry.id.type_oid);
eprintln!(
"Existing impl registered at {}:{}:{}",
old.info.file, old.info.line, old.info.column
);
eprintln!(
"New impl registered at {}:{}:{}",
entry.data.info.file, entry.data.info.line, entry.data.info.column
);
}
}
fn get(&self, type_oid: ImplId) -> Option<ImplData> {
self.oid_to_data.get(&type_oid).map(|d| *d)
}
}
lazy_static::lazy_static! {
// FIXME: Dynamic modules *will* break this.
static ref IMPL_REGISTRY: ImplRegistry = {
let mut reg = ImplRegistry::new();
for entry in inventory::iter::<ImplEntry> {
reg.add_entry(entry);
}
reg
};
}
pub unsafe trait RegisteredImpl {
fn vtable() -> usize;
fn debug_info() -> ImplDebugInfo;
}
#[doc(hidden)]
#[macro_use]
pub mod macros {
#[macro_export]
macro_rules! debug_info {
() => {
$crate::resources::state::value::ImplDebugInfo {
file: ::core::file!(),
line: ::core::line!(),
column: ::core::column!(),
}
};
}
#[macro_export]
macro_rules! statevalue_typeoid {
( $x:ident, $y:ty, $z:ty ) => {
impl $crate::resources::state::value::TypeOid for $z {
fn type_oid() -> &'static $crate::utils::oid::ObjectIdentifier {
&$x
}
fn type_name() -> &'static str {
stringify!($y)
}
}
}
}
#[macro_export]
macro_rules! statevalue_registeredimpl {
( $z:ty ) => {
unsafe impl $crate::resources::state::value::RegisteredImpl for $z {
fn vtable() -> usize {
unsafe {
::core::mem::transmute(ptr_meta::metadata(
::core::ptr::null::<$z>() as *const dyn $crate::resources::state::value::ArchivedStateValue
))
}
}
fn debug_info() -> $crate::resources::state::value::ImplDebugInfo {
$crate::debug_info!()
}
}
}
}
#[macro_export]
macro_rules! statevalue_register {
( $x:ident, $y:ty ) => {
$crate::oidvalue! {$x, $y, $y}
};
( $x:ident, $y:ty, $z:ty ) => {
$crate::statevalue_typeoid! { $x, $y, $z }
$crate::statevalue_registeredimpl! { $z }
::inventory::submit! {$crate::resources::state::value::ImplEntry::new::<$z>()}
};
}
}
/*
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/// Adding a custom type to BFFH state management:
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///
/// 1. Implement `serde`'s [`Serialize`](serde::Serialize) and [`Deserialize`](serde::Deserialize)
/// - `derive()`d instances work just fine, but keep stability over releases in mind.
/// 2. Implement rkyv's [`Serialize`](rkyv::Serialize).
/// 3. Implement TypeOid on your Archived type (i.e. `<T as Archive>::Archived`)
/// 4. Implement this
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pub trait Value: Any + fmt::Debug + erased_serde::Serialize + Sync {
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/// Initialize `&mut self` from `deserializer`
///
/// At the point this is called &mut self is of undefined value but guaranteed to be well
/// aligned and non-null. Any read access into &mut self before all of &self is brought into
/// a valid state is however undefined behaviour.
/// To this end you *must* initialize `self` **completely**. Serde will do the right thing if
/// you directly deserialize the type you're implementing `Value` for, but for manual
/// implementations this is important to keep in mind.
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fn deserialize_init<'de>(
&mut self,
deserializer: &mut dyn erased_serde::Deserializer<'de>,
) -> Result<(), erased_serde::Error>;
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/// Implement `PartialEq` dynamically.
///
/// This should return `true` iff the Value is of the same type and `self` == `other` for
/// non-dynamic types would return `true`.
/// It is safe to always return `false`.
fn dyn_eq(&self, other: &dyn Value) -> bool;
fn as_value(&self) -> &dyn Value;
fn as_any(&self) -> &dyn Any;
}
erased_serde::serialize_trait_object!(Value);
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erased_serde::serialize_trait_object!(SerializeValue);
erased_serde::serialize_trait_object!(DeserializeValue);
impl<T> Value for T
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where
T: Any
+ fmt::Debug
+ PartialEq
+ Sync
+ erased_serde::Serialize
+ for<'de> serde::Deserialize<'de>,
{
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fn deserialize_init<'de>(
&mut self,
deserializer: &mut dyn erased_serde::Deserializer<'de>,
) -> Result<(), erased_serde::Error> {
*self = erased_serde::deserialize(deserializer)?;
Ok(())
}
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fn dyn_eq(&self, other: &dyn Value) -> bool {
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other
.as_any()
.downcast_ref()
.map_or(false, |other: &T| other == self)
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}
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fn as_value(&self) -> &dyn Value {
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self
}
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fn as_any(&self) -> &dyn Any {
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self
}
}
impl PartialEq for dyn Value {
fn eq(&self, other: &Self) -> bool {
self.dyn_eq(other)
}
}
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#[repr(transparent)]
pub(super) struct DynVal<'a>(pub &'a dyn SerializeValue);
impl<'a> serde::Serialize for DynVal<'a> {
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
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where
S: serde::Serializer,
{
let mut ser = serializer.serialize_map(Some(1))?;
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let oid = self.0.archived_type_oid();
ser.serialize_entry(oid, self.0)?;
ser.end()
}
}
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#[repr(transparent)]
pub(super) struct DynOwnedVal(pub Box<dyn SerializeValue>);
impl<'de> serde::Deserialize<'de> for DynOwnedVal {
fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
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where
D: serde::Deserializer<'de>,
{
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deserializer.deserialize_map(DynValVisitor)
}
}
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struct DynValVisitor;
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impl<'de> serde::de::Visitor<'de> for DynValVisitor {
type Value = DynOwnedVal;
fn expecting(&self, formatter: &mut Formatter) -> fmt::Result {
write!(formatter, "an one entry map from OID to some value object")
}
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fn visit_map<A: serde::de::MapAccess<'de>>(self, mut map: A) -> Result<Self::Value, A::Error> {
// Bad magic code. Problem we have to solve: We only know how to parse whatever comes
// after the OID after having looked at the OID. We have zero static type info available
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// during deserialization. So:
// Get OID first. That's easy, we know it's the key, we know how to read it.
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let oid: ObjectIdentifier = map.next_key()?.ok_or(A::Error::missing_field("oid"))?;
// Get the Value vtable for that OID. Or fail because we don't know that OID, either works.
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let valimpl = IMPL_REGISTRY.get(ImplId::from_type_oid(&oid)).ok_or(
serde::de::Error::invalid_value(
serde::de::Unexpected::Other("unknown oid"),
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&"oid an implementation was registered for",
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),
)?;
// Casting random usize you find on the side of the road as vtable on unchecked pointers.
// What could possibly go wrong? >:D
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let valbox: MaybeUninit<Box<dyn SerializeValue>> = unsafe {
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// "recreate" vtable as fat ptr metadata (we literally just cast an `usize` but the
// only way to put this usize into that spot is by having a valid vtable cast so it's
// probably almost safe)
let meta = valimpl.pointer_metadata();
// Don't bother checking here. The only way this could be bad is if the vtable above
// is bad an in that case a segfault here would be *much better* than whatever is
// going to happen afterwards.
let layout = Layout::from_size_align_unchecked(meta.size_of(), meta.align_of());
// Hello yes I would like a Box the old fashioned way.
// Oh you're asking why we're allocating stuff here and never ever bother zeroing or
// validate in any other way if this is sane?
// Well...
let ptr: *mut () = std::alloc::alloc(layout).cast::<()>();
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let b = Box::from_raw(ptr_meta::from_raw_parts_mut(ptr, meta));
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// We make this a MaybeUninit so `Drop` is never called on the uninitialized value
MaybeUninit::new(b)
};
// ... The only way we can make Value a trait object by having it deserialize *into
// it's own uninitialized representation*. Yeah don't worry, this isn't the worst part of
// the game yet. >:D
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let seed = InitIntoSelf(valbox);
let val = map.next_value_seed(seed)?;
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Ok(DynOwnedVal(val))
}
}
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struct InitIntoSelf(MaybeUninit<Box<dyn SerializeValue>>);
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impl<'de> serde::de::DeserializeSeed<'de> for InitIntoSelf {
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type Value = Box<dyn SerializeValue>;
fn deserialize<D>(mut self, deserializer: D) -> Result<Self::Value, D::Error>
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where
D: serde::Deserializer<'de>,
{
let mut deser = <dyn erased_serde::Deserializer>::erase(deserializer);
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// Unsafe as hell but if we never read from this reference before initializing it's not
// undefined behaviour.
let selfptr = unsafe { &mut *self.0.as_mut_ptr() };
// Hey, better initialize late than never.
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selfptr
.deserialize_init(&mut deser)
.map_err(|e| D::Error::custom(e))?;
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// Assuming `deserialize_init` didn't error and did its job this is now safe.
unsafe { Ok(self.0.assume_init()) }
}
}
pub trait TypeOid {
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fn type_oid() -> &'static ObjectIdentifier;
fn type_name() -> &'static str;
}
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impl<S: ScratchSpace + Serializer + ?Sized> SerializeUnsized<S> for dyn SerializeValue {
fn serialize_unsized(&self, mut serializer: &mut S) -> Result<usize, S::Error> {
self.serialize_dynoid(&mut serializer)
.map_err(|e| *e.downcast::<S::Error>().unwrap())
}
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fn serialize_metadata(&self, serializer: &mut S) -> Result<Self::MetadataResolver, S::Error> {
let oid = self.archived_type_oid();
oid.serialize(serializer)
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}
}
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impl<T> SerializeDynOid for T
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where
T: for<'a> Serialize<dyn DynSerializer + 'a>,
T::Archived: TypeOid,
{
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fn serialize_dynoid(&self, serializer: &mut dyn DynSerializer) -> Result<usize, DynError> {
serializer.serialize_value(self)
}
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fn archived_type_oid(&self) -> &'static ObjectIdentifier {
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Archived::<T>::type_oid()
}
}
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pub trait DeserializeDynOid {
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unsafe fn deserialize_dynoid(
&self,
deserializer: &mut dyn DynDeserializer,
alloc: &mut dyn FnMut(Layout) -> *mut u8,
) -> Result<*mut (), DynError>;
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fn deserialize_dynoid_metadata(
&self,
deserializer: &mut dyn DynDeserializer,
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) -> Result<<dyn SerializeValue as Pointee>::Metadata, DynError>;
}
#[ptr_meta::pointee]
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pub trait SerializeValue: Value + SerializeDynOid {
}
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impl<T: Archive + Value + SerializeDynOid + Clone> SerializeValue for T
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where
T::Archived: RegisteredImpl,
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{
}
impl PartialEq for dyn SerializeValue {
fn eq(&self, other: &Self) -> bool {
self.dyn_eq(other.as_value())
}
}
impl Clone for Box<dyn SerializeValue> {
fn clone(&self) -> Self {
self.dyn_clone()
}
}
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#[ptr_meta::pointee]
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pub trait DeserializeValue: DeserializeDynOid {}
impl<T: DeserializeDynOid> DeserializeValue for T {}
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impl ArchivePointee for dyn DeserializeValue {
type ArchivedMetadata = ArchivedValueMetadata;
fn pointer_metadata(archived: &Self::ArchivedMetadata) -> <Self as Pointee>::Metadata {
archived.pointer_metadata()
}
}
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impl<D: Fallible + ?Sized> DeserializeUnsized<dyn SerializeValue, D> for dyn DeserializeValue {
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unsafe fn deserialize_unsized(
&self,
mut deserializer: &mut D,
mut alloc: impl FnMut(Layout) -> *mut u8,
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) -> Result<*mut (), D::Error> {
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self.deserialize_dynoid(&mut deserializer, &mut alloc)
.map_err(|e| *e.downcast().unwrap())
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}
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fn deserialize_metadata(
&self,
mut deserializer: &mut D,
) -> Result<<dyn SerializeValue as Pointee>::Metadata, D::Error> {
self.deserialize_dynoid_metadata(&mut deserializer)
.map_err(|e| *e.downcast().unwrap())
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}
}
impl ArchiveUnsized for dyn SerializeValue {
type Archived = dyn DeserializeValue;
type MetadataResolver = <ObjectIdentifier as Archive>::Resolver;
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unsafe fn resolve_metadata(
&self,
pos: usize,
resolver: Self::MetadataResolver,
out: *mut ArchivedMetadata<Self>,
) {
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let (oid_pos, oid) = out_field!(out.type_oid);
let type_oid = self.archived_type_oid();
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type_oid.resolve(pos + oid_pos, resolver, oid);
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}
}
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lazy_static::lazy_static! {
pub static ref OID_BOOL: ObjectIdentifier = {
ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.1.1").unwrap()
};
pub static ref OID_U8: ObjectIdentifier = {
ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.1.2").unwrap()
};
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pub static ref OID_U16: ObjectIdentifier = {
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ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.1.3").unwrap()
};
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pub static ref OID_U32: ObjectIdentifier = {
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ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.1.4").unwrap()
};
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pub static ref OID_U64: ObjectIdentifier = {
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ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.1.5").unwrap()
};
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pub static ref OID_U128: ObjectIdentifier = {
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ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.1.6").unwrap()
};
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pub static ref OID_I8: ObjectIdentifier = {
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ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.1.7").unwrap()
};
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pub static ref OID_I16: ObjectIdentifier = {
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ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.1.8").unwrap()
};
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pub static ref OID_I32: ObjectIdentifier = {
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ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.1.9").unwrap()
};
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pub static ref OID_I64: ObjectIdentifier = {
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ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.1.10").unwrap()
};
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pub static ref OID_I128: ObjectIdentifier = {
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ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.1.11").unwrap()
};
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pub static ref OID_VEC3U8: ObjectIdentifier = {
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ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.1.13").unwrap()
};
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pub static ref OID_POWERED: ObjectIdentifier = {
ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.2.1").unwrap()
};
pub static ref OID_INTENSITY: ObjectIdentifier = {
ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.2.2").unwrap()
};
pub static ref OID_COLOUR: ObjectIdentifier = {
ObjectIdentifier::from_str("1.3.6.1.4.1.48398.612.2.3").unwrap()
};
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}
oidvalue!(OID_BOOL, bool);
oidvalue!(OID_U8, u8);
oidvalue!(OID_U16, u16);
oidvalue!(OID_U32, u32);
oidvalue!(OID_U64, u64);
oidvalue!(OID_U128, u128);
oidvalue!(OID_I8, i8);
oidvalue!(OID_I16, i16);
oidvalue!(OID_I32, i32);
oidvalue!(OID_I64, i64);
oidvalue!(OID_I128, i128);
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#[derive(
serde::Serialize,
serde::Deserialize,
Debug,
Copy,
Clone,
PartialEq,
Eq,
Hash,
rkyv::Archive,
rkyv::Serialize,
rkyv::Deserialize,
)]
#[archive_attr(derive(Debug, PartialEq, serde::Serialize, serde::Deserialize))]
pub struct Vec3u8 {
pub a: u8,
pub b: u8,
pub c: u8,
}
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oidvalue!(OID_VEC3U8, Vec3u8, ArchivedVec3u8);
#[cfg(test)]
mod tests {
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use super::*;
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use rand::distributions::Standard;
use rand::prelude::Distribution;
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use rand::Rng;
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impl Distribution<Vec3u8> for Standard {
fn sample<R: Rng + ?Sized>(&self, rng: &mut R) -> Vec3u8 {
let a = self.sample(rng);
let b = self.sample(rng);
let c = self.sample(rng);
Vec3u8 { a, b, c }
}
}
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}
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*/