A rust library to derive optioned structs/enums versions of existing types where all fields have been recursively
replaced with versions that support setting just a subset of the relevant fields (or none at all).
One motivation for this concept is the common problem when expressing patches that for a given rust struct T
a corresponding struct T::Optioned would be required where all fields are recursively optional to specify.
While trivial to write for plain structures this quickly becomes tedious for nested structs/enums.
The library allows to use server-side-apply with built-in Kubernetes types by providing optioned variants for all types
from k8s-openapi. It also provides tooling to derive optioned variants for
kube::CustomResource implementations.
For detailed documentation, see the documentation in kube module for the CRD use case and the examples.
The core utility of this library is to provide an
Optionable derive macro that derives such an
optioned type
and implements the corresponding Optionable
trait (see below for details).
It supports nested structures, enums as well as various container types.
The general logic is the same as for other rust derives. If you want to use the
Optionable derive macro for a struct/enum
every type used for a field needs to also have implemented the corresponding
Optionable trait:
#[derive(Optionable)]
#[optionable(derive(Default, Serialize, Deserialize))]
struct Address {
street_name: String,
number: u8,
}
fn example() {
let _ = AddressOpt {
street_name: Some("a".to_owned()),
// fill the other fields with `None`
..Default::default()
};
}The generated optioned type is (shown here with resolved associated types) as follows:
#[derive(Default, Serialize, Deserialize)]
struct AddressOpt {
street_name: Option<String>,
number: Option<u8>,
}Deriving optioned versions also works with enums:
#[derive(Optionable)]
enum AddressEnum {
Plain(String),
AddressExplicit { street: String, number: u32 },
AddressNested(Address)
}
fn example() {
let _ = AddressEnumOpt::AddressExplicit {
street: Some("a".to_owned()),
number: None
};
}The main Optionable trait is quite simple:
pub trait Optionable {
type Optioned;
}It is a marker trait that allows to express for a given type T which type should be considered its T::Optioned type
such that Option<T::Optioned> would represent all variants of partial completeness.
For types without inner structure this means that the Optioned type will just resolve to the type itself, e.g.
impl Optionable for String {
type Optioned = String;
}For many primitive types as well as common wrapper or collection types the
Optionable trait is already implemented.
Per default also conversion traits for struct/enums with sized fields will be derived.
The relevant traits are (shown here without comments and with some where clauses omitted):
pub trait OptionableConvert: Sized + Optionable {
fn into_optioned(self) -> Self::Optioned;
fn try_from_optioned(value: Self::Optioned) -> Result<Self, Error>;
fn merge(&mut self, other: Self::Optioned) -> Result<(), Error>;
}
pub trait OptionedConvert<T>: Sized
{
fn from_optionable(value: T) -> Self;
fn try_into_optionable(self) -> Result<T, Error>;
}derive: Default-feature, re-exports theOptionablederive macro.std: Default-feature. AddsOptionable-implementations for many std-lib types.alloc: AddsOptionable-implementations for alloc types (only useful when not enabling thestdfeature).serde_json: Derive [trait@Optionable] for serde_json::Value.chrono04: Derive [trait@Optionable] for types from chrono v0.4.jiff02: DeriveOptionablefor types from jiff v0.2.k8s_openapi026_v1_(30..=34): AddsOptionable-implementations for all k8s-openapi v0.26 types. Only one feature version, e.g.k8s_openapi026_v1_34may be enabled at once.k8s_openapi_convert: AddsOptionableConvert-implementations for all optioned k8s-openapi types specified by thek8s_openapi026_v1_(30..=34)feature.kube: Tooling to derive optioned types for kubeCustomResource. Also includesextract-functionality for server-side apply. Will replaced with a versionedkube3after kube v3 has been released.
Due to the orphan rule the usage of the library becomes cumbersome if one has a use case which heavily relies on crate-external types.
If just have a few types from external crates don't have an Optionable impl
the example/orphanrule
illustrates how to circumvent this limitation.
For well-established libraries adding corresponding impl to this crate (feature-gated) would be a worthwhile approach.
Due to the use of associated types some IDE-hints do not fully resolve the associated types leaving you with
<i32 as Optionable>::Optioned instead of i32. Luckily, for checking type correctness and also for error messages
when using wrong types the associated types are resolved.
For the derived Optioned-structs/enums a related issue is that other derive macros for those derived types won't see
the resolved
associated types. Therefore, corresponding type bounds have to be added(done by the
Optionable derive macro) to the Optioned
-structs/enums:
#[derive(Optionable)]
#[optionable(derive(Serialize))]
struct DeriveExample<T> {
name: T,
}
// The generated code for the struct is shown below (simplified)
#[derive(Serialize)]
struct DeriveExampleOpt<T>
where
T: Optionable,
// extra `Serialize` bound on the struct level
<T as Optionable>::Optioned: Sized + Serialize,
{
#[serde(skip_serializing_if = "Option::is_none")]
name: Option<<T as Optionable>::Optioned>
}One crate with similar scope is optional_struct. It focuses specifically on structs (not enums) and offers a more manual approach, especially in respect to nested sub-struct, providing many fine-grained configuration options.
Another crate is struct-patch. It focuses on patching structs (not enums), especially from serde inputs. Nesting is supported with manual helper annotations.
You can use this under the conditions of the MIT license or the Apache License, Version 2.0 at your option.
Any contributor has to agree to have their contribution also dual-licensed under the MIT as well as Apache-2.0 license
as
specified above in the License subsection.