Module wasmer_types::lib::std::any
1.0.0 · source · Expand description
Utilities for dynamic typing or type reflection.
Any
and TypeId
Any
itself can be used to get a TypeId
, and has more features when used
as a trait object. As &dyn Any
(a borrowed trait object), it has the is
and downcast_ref
methods, to test if the contained value is of a given type,
and to get a reference to the inner value as a type. As &mut dyn Any
, there
is also the downcast_mut
method, for getting a mutable reference to the
inner value. Box<dyn Any>
adds the downcast
method, which attempts to
convert to a Box<T>
. See the Box
documentation for the full details.
Note that &dyn Any
is limited to testing whether a value is of a specified
concrete type, and cannot be used to test whether a type implements a trait.
Smart pointers and dyn Any
One piece of behavior to keep in mind when using Any
as a trait object,
especially with types like Box<dyn Any>
or Arc<dyn Any>
, is that simply
calling .type_id()
on the value will produce the TypeId
of the
container, not the underlying trait object. This can be avoided by
converting the smart pointer into a &dyn Any
instead, which will return
the object’s TypeId
. For example:
use std::any::{Any, TypeId};
let boxed: Box<dyn Any> = Box::new(3_i32);
// You're more likely to want this:
let actual_id = (&*boxed).type_id();
// ... than this:
let boxed_id = boxed.type_id();
assert_eq!(actual_id, TypeId::of::<i32>());
assert_eq!(boxed_id, TypeId::of::<Box<dyn Any>>());
Examples
Consider a situation where we want to log out a value passed to a function. We know the value we’re working on implements Debug, but we don’t know its concrete type. We want to give special treatment to certain types: in this case printing out the length of String values prior to their value. We don’t know the concrete type of our value at compile time, so we need to use runtime reflection instead.
use std::fmt::Debug;
use std::any::Any;
// Logger function for any type that implements Debug.
fn log<T: Any + Debug>(value: &T) {
let value_any = value as &dyn Any;
// Try to convert our value to a `String`. If successful, we want to
// output the `String`'s length as well as its value. If not, it's a
// different type: just print it out unadorned.
match value_any.downcast_ref::<String>() {
Some(as_string) => {
println!("String ({}): {}", as_string.len(), as_string);
}
None => {
println!("{value:?}");
}
}
}
// This function wants to log its parameter out prior to doing work with it.
fn do_work<T: Any + Debug>(value: &T) {
log(value);
// ...do some other work
}
fn main() {
let my_string = "Hello World".to_string();
do_work(&my_string);
let my_i8: i8 = 100;
do_work(&my_i8);
}
Provider
and Demand
Provider
and the associated APIs support generic, type-driven access to data, and a mechanism
for implementers to provide such data. The key parts of the interface are the Provider
trait for objects which can provide data, and the request_value
and request_ref
functions for requesting data from an object which implements Provider
. Generally, end users
should not call request_*
directly, they are helper functions for intermediate implementers
to use to implement a user-facing interface. This is purely for the sake of ergonomics, there is
no safety concern here; intermediate implementers can typically support methods rather than
free functions and use more specific names.
Typically, a data provider is a trait object of a trait which extends Provider
. A user will
request data from a trait object by specifying the type of the data.
Data flow
- A user requests an object of a specific type, which is delegated to
request_value
orrequest_ref
request_*
creates aDemand
object and passes it toProvider::provide
- The data provider’s implementation of
Provider::provide
tries providing values of different types usingDemand::provide_*
. If the type matches the type requested by the user, the value will be stored in theDemand
object. request_*
unpacks theDemand
object and returns any stored value to the user.
Examples
use std::any::{Provider, Demand, request_ref};
// Definition of MyTrait, a data provider.
trait MyTrait: Provider {
// ...
}
// Methods on `MyTrait` trait objects.
impl dyn MyTrait + '_ {
/// Get a reference to a field of the implementing struct.
pub fn get_context_by_ref<T: ?Sized + 'static>(&self) -> Option<&T> {
request_ref::<T>(self)
}
}
// Downstream implementation of `MyTrait` and `Provider`.
impl MyTrait for SomeConcreteType {
// ...
}
impl Provider for SomeConcreteType {
fn provide<'a>(&'a self, demand: &mut Demand<'a>) {
// Provide a string reference. We could provide multiple values with
// different types here.
demand.provide_ref::<String>(&self.some_string);
}
}
// Downstream usage of `MyTrait`.
fn use_my_trait(obj: &dyn MyTrait) {
// Request a &String from obj.
let _ = obj.get_context_by_ref::<String>().unwrap();
}
In this example, if the concrete type of obj
in use_my_trait
is SomeConcreteType
, then
the get_context_by_ref
call will return a reference to obj.some_string
with type &String
.
Structs
- DemandExperimentalA helper object for providing data by type.
- A
TypeId
represents a globally unique identifier for a type.
Traits
- ProviderExperimentalTrait implemented by a type which can dynamically provide values based on type.
- A trait to emulate dynamic typing.
Functions
- request_refExperimentalRequest a reference from the
Provider
. - request_valueExperimentalRequest a value from the
Provider
. - type_name_of_valExperimentalReturns the name of the type of the pointed-to value as a string slice. This is the same as
type_name::<T>()
, but can be used where the type of a variable is not easily available. - Returns the name of a type as a string slice.