Crate scale_info
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Efficient and space-efficient serialization of Rust types.
This library provides structures to easily retrieve compile-time type
information at runtime and also to serialize this information in a
space-efficient form, aka PortableForm
.
§Registry
At the heart of its functionality is the Registry
that acts as a cache for known types in order to efficiently deduplicate
types and ensure a space-efficient serialization.
§Type Information
Information about types is provided via the TypeInfo
trait.
This trait should be implemented for all types that are serializable.
scale-info
provides implementations for all commonly used Rust standard
types and a derive macro for implementing of custom types.
§Deriving TypeInfo
Enable the derive
feature of this crate:
scale-info = { version = "2.0.0", features = ["derive"] }
use scale_info::TypeInfo;
#[derive(TypeInfo)]
struct MyStruct {
a: u32,
b: MyEnum,
}
#[derive(TypeInfo)]
enum MyEnum {
A(bool),
B { f: Vec<u8> },
C,
}
§Attributes
§#[scale_info(bounds(..))]
Replace the auto-generated where
clause bounds for the derived TypeInfo
implementation.
#[derive(TypeInfo)]
#[scale_info(bounds(T: TypeInfo + 'static))]
struct MyStruct<T> {
a: Vec<T>,
}
The derive macro automatically adds TypeInfo
bounds for all type parameters, and all field
types containing type parameters or associated types.
This is naive and sometimes adds unnecessary bounds, since on a syntactical level there is no way to differentiate between a generic type constructor and a type alias with a generic argument e.g.
trait MyTrait {
type A;
}
type MyAlias<T> = <T as MyTrait>::A;
#[derive(TypeInfo)]
struct MyStruct<T> {
a: MyAlias<T>,
b: Vec<T>,
}
So for the above, since a MyAlias<T>: TypeInfo
bound is required, and we can’t distinguish
between MyAlias<T>
and Vec<T>
, then the TypeInfo
bound is simply added for all
fields which contain any type param. In this case the redundant Vec<T>: TypeInfo
would be added.
This is usually okay, but in some circumstances can cause problems, for example with the
[overflow evaluating the requirement
] error here.
The bounds
attribute provides an “escape hatch” to allow
the programmer control of the where
clause on the generated impl
, to solve this and other
issues that can’t be foreseen by the auto-generated bounds heuristic.
§#[scale_info(skip_type_params(..))]
Remove the requirement for the specified type params to implement TypeInfo
.
Consider a simple example of a type parameter which is used for associated types, but the type itself does not carry any type information. Consider this common pattern:
trait Config {
type Balance;
}
struct Runtime; // doesn't implement `TypeInfo`
impl Config for Runtime {
type Balance = u64;
}
#[allow(unused)]
#[derive(TypeInfo)]
#[scale_info(skip_type_params(T))]
struct A<T: Config> {
balance: T::Balance,
marker: core::marker::PhantomData<T>,
}
fn assert_type_info<T: scale_info::TypeInfo + 'static>() {}
fn main() {
// without the `skip_type_params` attribute this will fail.
assert_type_info::<A<Runtime>>();
}
By default, the derived TypeInfo
implementation will add the type of all type parameters to
the TypeParameter
specification e.g.
type_params(vec![TypeParameter::new("T", Some(MetaType::new::<T>()))])
In the example above, this will cause a compiler error because Runtime
is the concrete tyoe
for T
, which does not satisfy the TypeInfo
requirement of MetaType::new::<T>()
.
Simply adding a TypeInfo
derive to Runtime
is one way of solving this, but that could be
misleading (why does it need TypeInfo
if a value of that type is never encoded?), and can
sometimes require adding TypeInfo
bounds in other impl blocks.
The skip_type_params
attribute solves this, providing an additional “escape hatch” which
prevents the given type parameter’s type information being required:
type_params(vec![TypeParameter::new("T", None)])
The generated type params do not now require T
to implement TypeInfo
, so the auto-generated
bound is not added to the generated TypeInfo
where
clause.
§Combining bounds
and skip_type_params
These two attributes can complement one another, particularly in the case where using bounds
would still require manually adding a TypeInfo
bound for the type parameter:
#[derive(TypeInfo)]
#[scale_info(bounds(), skip_type_params(T))]
struct A<T> {
marker: core::marker::PhantomData<T>,
}
Without skip_type_params
in the example above, it would require the TypeInfo
bounds for T
to be added manually e.g. #[scale_info(bounds(T: TypeInfo + 'static))]
. Since the intention of
the empty bounds is to remove all type bounds, then the addition of skip_type_params
allows this to compile successfully.
§Precedence
When used independently, both attributes modify the where
clause of the derived TypeInfo
impl. When used together, the predicates supplied in the bounds
attribute replaces all
auto-generated bounds, and skip_type_params
will have no effect on the resulting where
clause.
Note: When using bounds
without skip_type_params
, it is therefore required to manually
add a TypeInfo
bound for any non skipped type parameters. The compiler will let you know.
§#[scale_info(capture_docs = "default|always|never")]
Docs for types, fields and variants can all be captured by the docs
feature being enabled.
This can be overridden using the capture_docs
attribute:
#[scale_info(capture_docs = "default")]
will capture docs iff the docs
feature is enabled.
This is the default if capture_docs
is not specified.
#[scale_info(capture_docs = "always")]
will capture docs for the annotated type even if the
docs
feature is not enabled.
#[scale_info(capture_docs = "never")]
will not capture docs for the annotated type even if
the docs
is enabled.
This is useful e.g. when compiling metadata into a Wasm blob, and it is desirable to keep the
binary size as small as possible, so the docs
feature would be disabled. In case the docs for
some types is necessary they could be enabled on a per-type basis with the above attribute.
§#[scale_info(crate = path::to::crate)]
Specify a path to the scale-info crate instance to use when referring to the APIs from generated code. This is normally only applicable when invoking re-exported scale-info derives from a public macro in a different crate. For example:
use scale_info_reexport::info::TypeInfo;
#[derive(TypeInfo)]
#[scale_info(crate = scale_info_reexport::info)]
enum TestEnum {
FirstVariant,
SecondVariant,
}
§#[scale_info(replace_segment("search", "replace"))]
Specify to rename a segment in the path
returned by the [TypeInfo::path
] function.
Normally the path is generated by using the module_path!
macro. This path includes
the crate name and all the modules up to the declaration of the type. Sometimes it
is useful to replace one of these segments to ensure that for example a renaming
of the crate isn’t propagated to downstream users. Be aware that if a crate-name
contains an hypen, the actual segment is crate_name
. The replace
name needs
to be a valid Rust identifier. The attribute is allowed to be passed multiple
times to replace multiple segments.
Example:
use scale_info_reexport::info::TypeInfo;
#[derive(TypeInfo)]
#[scale_info(replace_segment("something", "better_name"))]
#[scale_info(replace_segment("TestEnum", "BetterEnumName"))]
enum TestEnum {
FirstVariant,
SecondVariant,
}
§Forms
To bridge between compile-time type information and runtime the
MetaForm
is used to easily retrieve all
information needed to uniquely identify types.
The MetaForm
and its associated Registry
can be transformed into the
space-efficient form by the IntoPortable
trait; it is
used internally by the Registry
in order to convert
the expanded types into their space-efficient form.
§Symbols and Namespaces
To differentiate two types sharing the same name, namespaces are used.
Commonly the namespace is equal to the one where the type has been defined
in. For Rust prelude types such as Option
and
Result
the root namespace (empty namespace) is
used.
To use this library simply use the MetaForm
initially with your own data structures; make them generic over the
Form
trait just as has been done in this crate with
TypeInfo
in order to get a simple implementation of
IntoPortable
. Use a single instance of the
Registry
for compaction and provide this registry
instance upon serialization.
A usage example can be found in ink! here: https://github.com/paritytech/ink/blob/master/abi/src/specs.rs
Modules§
- Builders for defining metadata for variant types (enums), and composite types (structs). They are designed to allow only construction of valid definitions.
- Provides form definitions.
- Interning data structure and associated symbol definitions.
- Exports from
std
,core
andalloc
crates.
Macros§
- Construct a vector of
TypeParameter
s from pairs of the name and the concrete type. - Takes a number of types and returns a vector that contains their respective
MetaType
instances. - Construct a vector of
TypeParameter
instances with the name of the type parameter, together with its concreteMetaType
.
Structs§
- A field of a struct-like data type.
- A metatype abstraction.
- Represents the path of a type definition.
- A read-only registry containing types in their portable form for serialization.
- Construct a
PortableRegistry
. - Represent a type in it’s portable form.
- The registry for space-efficient storage of type identifiers and definitions.
- A
Type
definition with optional metadata. - An array type.
- Type describing a
bitvec::vec::BitVec
. - A type wrapped in [
Compact
]. - A composite type, consisting of either named (struct) or unnamed (tuple struct) fields
- A type to refer to a sequence of elements of the same type.
- A type to refer to tuple types.
- A Enum type (consisting of variants).
- A generic type parameter.
- A struct enum variant with either named (struct) or unnamed (tuple struct) fields.
Enums§
- An error that may be encountered upon constructing namespaces.
- The possible types a SCALE encodable Rust value could have.
- A primitive Rust type.
Traits§
- Convert the type definition into the portable form using a registry.
- Convenience trait for implementors, combining
TypeInfo
and'static
bounds. - Implementors return their meta type information.
Functions§
- Returns the runtime bridge to the types compile-time type information.