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218b0fd3b6
bevy/crates/bevy_reflect/src/lib.rs
Jakob Hellermann 218b0fd3b6 bevy_reflect: put serialize into external ReflectSerialize type (#4782) 
builds on top of #4780 

# Objective

`Reflect` and `Serialize` are currently very tied together because `Reflect` has a `fn serialize(&self) -> Option<Serializable<'_>>` method. Because of that, we can either implement `Reflect` for types like `Option<T>` with `T: Serialize` and have `fn serialize` be implemented, or without the bound but having `fn serialize` return `None`.

By separating `ReflectSerialize` into a separate type (like how it already is for `ReflectDeserialize`, `ReflectDefault`), we could separately `.register::<Option<T>>()` and `.register_data::<Option<T>, ReflectSerialize>()` only if the type `T: Serialize`.

This PR does not change the registration but allows it to be changed in a future PR.

## Solution

- add the type
```rust
struct ReflectSerialize { .. }
impl<T: Reflect + Serialize> FromType<T> for ReflectSerialize { .. }
```

- remove `#[reflect(Serialize)]` special casing. 

- when serializing reflect value types, look for `ReflectSerialize` in the `TypeRegistry` instead of calling `value.serialize()`
2022-06-20 17:18:58 +00:00

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#![doc = include_str!("../README.md")]
mod array;
mod fields;
mod list;
mod map;
mod path;
mod reflect;
mod struct_trait;
mod tuple;
mod tuple_struct;
mod type_info;
mod type_registry;
mod type_uuid;
mod impls {
#[cfg(feature = "glam")]
mod glam;
#[cfg(feature = "smallvec")]
mod smallvec;
mod std;
#[cfg(feature = "glam")]
pub use self::glam::*;
#[cfg(feature = "smallvec")]
pub use self::smallvec::*;
pub use self::std::*;
}
pub mod serde;
pub mod std_traits;
pub mod utility;
pub mod prelude {
pub use crate::std_traits::*;
#[doc(hidden)]
pub use crate::{
reflect_trait, GetField, GetTupleStructField, Reflect, ReflectDeserialize,
ReflectSerialize, Struct, TupleStruct,
};
}
pub use array::*;
pub use fields::*;
pub use impls::*;
pub use list::*;
pub use map::*;
pub use path::*;
pub use reflect::*;
pub use struct_trait::*;
pub use tuple::*;
pub use tuple_struct::*;
pub use type_info::*;
pub use type_registry::*;
pub use type_uuid::*;
pub use bevy_reflect_derive::*;
pub use erased_serde;
#[doc(hidden)]
pub mod __macro_exports {
use crate::Uuid;
/// Generates a new UUID from the given UUIDs `a` and `b`,
/// where the bytes are generated by a bitwise `a ^ b.rotate_right(1)`.
/// The generated UUID will be a `UUIDv4` (meaning that the bytes should be random, not e.g. derived from the system time).
#[allow(clippy::unusual_byte_groupings)] // unusual byte grouping is meant to signal the relevant bits
pub const fn generate_composite_uuid(a: Uuid, b: Uuid) -> Uuid {
let mut new = [0; 16];
let mut i = 0;
while i < new.len() {
// rotating ensures different uuids for A<B<C>> and B<A<C>> because: A ^ (B ^ C) = B ^ (A ^ C)
// notice that you have to rotate the second parameter: A.rr ^ (B.rr ^ C) = B.rr ^ (A.rr ^ C)
// Solution: A ^ (B ^ C.rr).rr != B ^ (A ^ C.rr).rr
new[i] = a.as_bytes()[i] ^ b.as_bytes()[i].rotate_right(1);
i += 1;
}
// Version: the most significant 4 bits in the 6th byte: 11110000
new[6] = new[6] & 0b0000_1111 | 0b0100_0000; // set version to v4
// Variant: the most significant 3 bits in the 8th byte: 11100000
new[8] = new[8] & 0b000_11111 | 0b100_00000; // set variant to rfc4122
Uuid::from_bytes(new)
}
}
#[cfg(test)]
#[allow(clippy::blacklisted_name, clippy::approx_constant)]
mod tests {
#[cfg(feature = "glam")]
use ::glam::{vec3, Vec3};
use ::serde::de::DeserializeSeed;
use bevy_utils::HashMap;
use ron::{
ser::{to_string_pretty, PrettyConfig},
Deserializer,
};
use std::fmt::{Debug, Formatter};
use super::prelude::*;
use super::*;
use crate as bevy_reflect;
use crate::serde::{ReflectDeserializer, ReflectSerializer};
#[test]
fn reflect_struct() {
#[derive(Reflect)]
struct Foo {
a: u32,
b: f32,
c: Bar,
}
#[derive(Reflect)]
struct Bar {
x: u32,
}
let mut foo = Foo {
a: 42,
b: 3.14,
c: Bar { x: 1 },
};
let a = *foo.get_field::<u32>("a").unwrap();
assert_eq!(a, 42);
*foo.get_field_mut::<u32>("a").unwrap() += 1;
assert_eq!(foo.a, 43);
let bar = foo.get_field::<Bar>("c").unwrap();
assert_eq!(bar.x, 1);
// nested retrieval
let c = foo.field("c").unwrap();
if let ReflectRef::Struct(value) = c.reflect_ref() {
assert_eq!(*value.get_field::<u32>("x").unwrap(), 1);
} else {
panic!("Expected a struct.");
}
// patch Foo with a dynamic struct
let mut dynamic_struct = DynamicStruct::default();
dynamic_struct.insert("a", 123u32);
dynamic_struct.insert("should_be_ignored", 456);
foo.apply(&dynamic_struct);
assert_eq!(foo.a, 123);
}
#[test]
fn reflect_map() {
#[derive(Reflect, Hash)]
#[reflect(Hash)]
struct Foo {
a: u32,
b: String,
}
let key_a = Foo {
a: 1,
b: "k1".to_string(),
};
let key_b = Foo {
a: 1,
b: "k1".to_string(),
};
let key_c = Foo {
a: 3,
b: "k3".to_string(),
};
let mut map = DynamicMap::default();
map.insert(key_a, 10u32);
assert_eq!(10, *map.get(&key_b).unwrap().downcast_ref::<u32>().unwrap());
assert!(map.get(&key_c).is_none());
*map.get_mut(&key_b).unwrap().downcast_mut::<u32>().unwrap() = 20;
assert_eq!(20, *map.get(&key_b).unwrap().downcast_ref::<u32>().unwrap());
}
#[test]
#[allow(clippy::blacklisted_name)]
fn reflect_unit_struct() {
#[derive(Reflect)]
struct Foo(u32, u64);
let mut foo = Foo(1, 2);
assert_eq!(1, *foo.get_field::<u32>(0).unwrap());
assert_eq!(2, *foo.get_field::<u64>(1).unwrap());
let mut patch = DynamicTupleStruct::default();
patch.insert(3u32);
patch.insert(4u64);
assert_eq!(3, *patch.field(0).unwrap().downcast_ref::<u32>().unwrap());
assert_eq!(4, *patch.field(1).unwrap().downcast_ref::<u64>().unwrap());
foo.apply(&patch);
assert_eq!(3, foo.0);
assert_eq!(4, foo.1);
let mut iter = patch.iter_fields();
assert_eq!(3, *iter.next().unwrap().downcast_ref::<u32>().unwrap());
assert_eq!(4, *iter.next().unwrap().downcast_ref::<u64>().unwrap());
}
#[test]
#[should_panic(expected = "the given key does not support hashing")]
fn reflect_map_no_hash() {
#[derive(Reflect)]
struct Foo {
a: u32,
}
let foo = Foo { a: 1 };
let mut map = DynamicMap::default();
map.insert(foo, 10u32);
}
#[test]
fn reflect_ignore() {
#[derive(Reflect)]
struct Foo {
a: u32,
#[reflect(ignore)]
_b: u32,
}
let foo = Foo { a: 1, _b: 2 };
let values: Vec<u32> = foo
.iter_fields()
.map(|value| *value.downcast_ref::<u32>().unwrap())
.collect();
assert_eq!(values, vec![1]);
}
#[test]
fn from_reflect_should_use_default_field_attributes() {
#[derive(Reflect, FromReflect, Eq, PartialEq, Debug)]
struct MyStruct {
// Use `Default::default()`
// Note that this isn't an ignored field
#[reflect(default)]
foo: String,
// Use `get_bar_default()`
#[reflect(default = "get_bar_default")]
#[reflect(ignore)]
bar: usize,
}
fn get_bar_default() -> usize {
123
}
let expected = MyStruct {
foo: String::default(),
bar: 123,
};
let dyn_struct = DynamicStruct::default();
let my_struct = <MyStruct as FromReflect>::from_reflect(&dyn_struct);
assert_eq!(Some(expected), my_struct);
}
#[test]
fn from_reflect_should_use_default_container_attribute() {
#[derive(Reflect, FromReflect, Eq, PartialEq, Debug)]
#[reflect(Default)]
struct MyStruct {
foo: String,
#[reflect(ignore)]
bar: usize,
}
impl Default for MyStruct {
fn default() -> Self {
Self {
foo: String::from("Hello"),
bar: 123,
}
}
}
let expected = MyStruct {
foo: String::from("Hello"),
bar: 123,
};
let dyn_struct = DynamicStruct::default();
let my_struct = <MyStruct as FromReflect>::from_reflect(&dyn_struct);
assert_eq!(Some(expected), my_struct);
}
#[test]
fn reflect_complex_patch() {
#[derive(Reflect, Eq, PartialEq, Debug, FromReflect)]
#[reflect(PartialEq)]
struct Foo {
a: u32,
#[reflect(ignore)]
_b: u32,
c: Vec<isize>,
d: HashMap<usize, i8>,
e: Bar,
f: (i32, Vec<isize>, Bar),
g: Vec<(Baz, HashMap<usize, Bar>)>,
h: [u32; 2],
}
#[derive(Reflect, Eq, PartialEq, Clone, Debug, FromReflect)]
#[reflect(PartialEq)]
struct Bar {
x: u32,
}
#[derive(Reflect, Eq, PartialEq, Debug, FromReflect)]
struct Baz(String);
let mut hash_map = HashMap::default();
hash_map.insert(1, 1);
hash_map.insert(2, 2);
let mut hash_map_baz = HashMap::default();
hash_map_baz.insert(1, Bar { x: 0 });
let mut foo = Foo {
a: 1,
_b: 1,
c: vec![1, 2],
d: hash_map,
e: Bar { x: 1 },
f: (1, vec![1, 2], Bar { x: 1 }),
g: vec![(Baz("string".to_string()), hash_map_baz)],
h: [2; 2],
};
let mut foo_patch = DynamicStruct::default();
foo_patch.insert("a", 2u32);
foo_patch.insert("b", 2u32); // this should be ignored
let mut list = DynamicList::default();
list.push(3isize);
list.push(4isize);
list.push(5isize);
foo_patch.insert("c", List::clone_dynamic(&list));
let mut map = DynamicMap::default();
map.insert(2usize, 3i8);
foo_patch.insert("d", map);
let mut bar_patch = DynamicStruct::default();
bar_patch.insert("x", 2u32);
foo_patch.insert("e", bar_patch.clone_dynamic());
let mut tuple = DynamicTuple::default();
tuple.insert(2i32);
tuple.insert(list);
tuple.insert(bar_patch);
foo_patch.insert("f", tuple);
let mut composite = DynamicList::default();
composite.push({
let mut tuple = DynamicTuple::default();
tuple.insert({
let mut tuple_struct = DynamicTupleStruct::default();
tuple_struct.insert("new_string".to_string());
tuple_struct
});
tuple.insert({
let mut map = DynamicMap::default();
map.insert(1usize, {
let mut struct_ = DynamicStruct::default();
struct_.insert("x", 7u32);
struct_
});
map
});
tuple
});
foo_patch.insert("g", composite);
let array = DynamicArray::from_vec(vec![2u32, 2u32]);
foo_patch.insert("h", array);
foo.apply(&foo_patch);
let mut hash_map = HashMap::default();
hash_map.insert(1, 1);
hash_map.insert(2, 3);
let mut hash_map_baz = HashMap::default();
hash_map_baz.insert(1, Bar { x: 7 });
let expected_foo = Foo {
a: 2,
_b: 1,
c: vec![3, 4, 5],
d: hash_map,
e: Bar { x: 2 },
f: (2, vec![3, 4, 5], Bar { x: 2 }),
g: vec![(Baz("new_string".to_string()), hash_map_baz.clone())],
h: [2; 2],
};
assert_eq!(foo, expected_foo);
let new_foo = Foo::from_reflect(&foo_patch)
.expect("error while creating a concrete type from a dynamic type");
let mut hash_map = HashMap::default();
hash_map.insert(2, 3);
let expected_new_foo = Foo {
a: 2,
_b: 0,
c: vec![3, 4, 5],
d: hash_map,
e: Bar { x: 2 },
f: (2, vec![3, 4, 5], Bar { x: 2 }),
g: vec![(Baz("new_string".to_string()), hash_map_baz)],
h: [2; 2],
};
assert_eq!(new_foo, expected_new_foo);
}
#[test]
fn reflect_serialize() {
#[derive(Reflect)]
struct Foo {
a: u32,
#[reflect(ignore)]
_b: u32,
c: Vec<isize>,
d: HashMap<usize, i8>,
e: Bar,
f: String,
g: (i32, Vec<isize>, Bar),
h: [u32; 2],
}
#[derive(Reflect)]
struct Bar {
x: u32,
}
let mut hash_map = HashMap::default();
hash_map.insert(1, 1);
hash_map.insert(2, 2);
let foo = Foo {
a: 1,
_b: 1,
c: vec![1, 2],
d: hash_map,
e: Bar { x: 1 },
f: "hi".to_string(),
g: (1, vec![1, 2], Bar { x: 1 }),
h: [2; 2],
};
let mut registry = TypeRegistry::default();
registry.register::<u32>();
registry.register::<isize>();
registry.register::<usize>();
registry.register::<Bar>();
registry.register::<String>();
registry.register::<i8>();
registry.register::<i32>();
let serializer = ReflectSerializer::new(&foo, &registry);
let serialized = to_string_pretty(&serializer, PrettyConfig::default()).unwrap();
let mut deserializer = Deserializer::from_str(&serialized).unwrap();
let reflect_deserializer = ReflectDeserializer::new(&registry);
let value = reflect_deserializer.deserialize(&mut deserializer).unwrap();
let dynamic_struct = value.take::<DynamicStruct>().unwrap();
assert!(foo.reflect_partial_eq(&dynamic_struct).unwrap());
}
#[test]
fn reflect_take() {
#[derive(Reflect, Debug, PartialEq)]
#[reflect(PartialEq)]
struct Bar {
x: u32,
}
let x: Box<dyn Reflect> = Box::new(Bar { x: 2 });
let y = x.take::<Bar>().unwrap();
assert_eq!(y, Bar { x: 2 });
}
#[test]
fn dynamic_names() {
let list = Vec::<usize>::new();
let dyn_list = List::clone_dynamic(&list);
assert_eq!(dyn_list.type_name(), std::any::type_name::<Vec<usize>>());
let array = [b'0'; 4];
let dyn_array = Array::clone_dynamic(&array);
assert_eq!(dyn_array.type_name(), std::any::type_name::<[u8; 4]>());
let map = HashMap::<usize, String>::default();
let dyn_map = map.clone_dynamic();
assert_eq!(
dyn_map.type_name(),
std::any::type_name::<HashMap<usize, String>>()
);
let tuple = (0usize, "1".to_string(), 2.0f32);
let mut dyn_tuple = tuple.clone_dynamic();
dyn_tuple.insert::<usize>(3);
assert_eq!(
dyn_tuple.type_name(),
std::any::type_name::<(usize, String, f32, usize)>()
);
#[derive(Reflect)]
struct TestStruct {
a: usize,
}
let struct_ = TestStruct { a: 0 };
let dyn_struct = struct_.clone_dynamic();
assert_eq!(dyn_struct.type_name(), std::any::type_name::<TestStruct>());
#[derive(Reflect)]
struct TestTupleStruct(usize);
let tuple_struct = TestTupleStruct(0);
let dyn_tuple_struct = tuple_struct.clone_dynamic();
assert_eq!(
dyn_tuple_struct.type_name(),
std::any::type_name::<TestTupleStruct>()
);
}
#[test]
fn reflect_type_info() {
// TypeInfo
let info = i32::type_info();
assert_eq!(std::any::type_name::<i32>(), info.type_name());
assert_eq!(std::any::TypeId::of::<i32>(), info.type_id());
// TypeInfo (unsized)
assert_eq!(
std::any::TypeId::of::<dyn Reflect>(),
<dyn Reflect as Typed>::type_info().type_id()
);
// TypeInfo (instance)
let value: &dyn Reflect = &123_i32;
let info = value.get_type_info();
assert!(info.is::<i32>());
// Struct
#[derive(Reflect)]
struct MyStruct {
foo: i32,
bar: usize,
}
let info = MyStruct::type_info();
if let TypeInfo::Struct(info) = info {
assert!(info.is::<MyStruct>());
assert_eq!(std::any::type_name::<MyStruct>(), info.type_name());
assert_eq!(
std::any::type_name::<i32>(),
info.field("foo").unwrap().type_name()
);
assert_eq!(
std::any::TypeId::of::<i32>(),
info.field("foo").unwrap().type_id()
);
assert!(info.field("foo").unwrap().is::<i32>());
assert_eq!("foo", info.field("foo").unwrap().name());
assert_eq!(
std::any::type_name::<usize>(),
info.field_at(1).unwrap().type_name()
);
} else {
panic!("Expected `TypeInfo::Struct`");
}
let value: &dyn Reflect = &MyStruct { foo: 123, bar: 321 };
let info = value.get_type_info();
assert!(info.is::<MyStruct>());
// Struct (generic)
#[derive(Reflect)]
struct MyGenericStruct<T: Reflect> {
foo: T,
bar: usize,
}
let info = <MyGenericStruct<i32>>::type_info();
if let TypeInfo::Struct(info) = info {
assert!(info.is::<MyGenericStruct<i32>>());
assert_eq!(
std::any::type_name::<MyGenericStruct<i32>>(),
info.type_name()
);
assert_eq!(
std::any::type_name::<i32>(),
info.field("foo").unwrap().type_name()
);
assert_eq!("foo", info.field("foo").unwrap().name());
assert_eq!(
std::any::type_name::<usize>(),
info.field_at(1).unwrap().type_name()
);
} else {
panic!("Expected `TypeInfo::Struct`");
}
let value: &dyn Reflect = &MyGenericStruct {
foo: String::from("Hello!"),
bar: 321,
};
let info = value.get_type_info();
assert!(info.is::<MyGenericStruct<String>>());
// Tuple Struct
#[derive(Reflect)]
struct MyTupleStruct(usize, i32, MyStruct);
let info = MyTupleStruct::type_info();
if let TypeInfo::TupleStruct(info) = info {
assert!(info.is::<MyTupleStruct>());
assert_eq!(std::any::type_name::<MyTupleStruct>(), info.type_name());
assert_eq!(
std::any::type_name::<i32>(),
info.field_at(1).unwrap().type_name()
);
assert!(info.field_at(1).unwrap().is::<i32>());
} else {
panic!("Expected `TypeInfo::TupleStruct`");
}
let value: &dyn Reflect = &MyTupleStruct(123, 321, MyStruct { foo: 123, bar: 321 });
let info = value.get_type_info();
assert!(info.is::<MyTupleStruct>());
// Tuple
type MyTuple = (u32, f32, String);
let info = MyTuple::type_info();
if let TypeInfo::Tuple(info) = info {
assert!(info.is::<MyTuple>());
assert_eq!(std::any::type_name::<MyTuple>(), info.type_name());
assert_eq!(
std::any::type_name::<f32>(),
info.field_at(1).unwrap().type_name()
);
} else {
panic!("Expected `TypeInfo::Tuple`");
}
let value: &dyn Reflect = &(123_u32, 1.23_f32, String::from("Hello!"));
let info = value.get_type_info();
assert!(info.is::<MyTuple>());
// List
type MyList = Vec<usize>;
let info = MyList::type_info();
if let TypeInfo::List(info) = info {
assert!(info.is::<MyList>());
assert!(info.item_is::<usize>());
assert_eq!(std::any::type_name::<MyList>(), info.type_name());
assert_eq!(std::any::type_name::<usize>(), info.item_type_name());
} else {
panic!("Expected `TypeInfo::List`");
}
let value: &dyn Reflect = &vec![123_usize];
let info = value.get_type_info();
assert!(info.is::<MyList>());
// List (SmallVec)
#[cfg(feature = "smallvec")]
{
type MySmallVec = smallvec::SmallVec<[String; 2]>;
let info = MySmallVec::type_info();
if let TypeInfo::List(info) = info {
assert!(info.is::<MySmallVec>());
assert!(info.item_is::<String>());
assert_eq!(std::any::type_name::<MySmallVec>(), info.type_name());
assert_eq!(std::any::type_name::<String>(), info.item_type_name());
} else {
panic!("Expected `TypeInfo::List`");
}
let value: MySmallVec = smallvec::smallvec![String::default(); 2];
let value: &dyn Reflect = &value;
let info = value.get_type_info();
assert!(info.is::<MySmallVec>());
}
// Array
type MyArray = [usize; 3];
let info = MyArray::type_info();
if let TypeInfo::Array(info) = info {
assert!(info.is::<MyArray>());
assert!(info.item_is::<usize>());
assert_eq!(std::any::type_name::<MyArray>(), info.type_name());
assert_eq!(std::any::type_name::<usize>(), info.item_type_name());
assert_eq!(3, info.capacity());
} else {
panic!("Expected `TypeInfo::Array`");
}
let value: &dyn Reflect = &[1usize, 2usize, 3usize];
let info = value.get_type_info();
assert!(info.is::<MyArray>());
// Map
type MyMap = HashMap<usize, f32>;
let info = MyMap::type_info();
if let TypeInfo::Map(info) = info {
assert!(info.is::<MyMap>());
assert!(info.key_is::<usize>());
assert!(info.value_is::<f32>());
assert_eq!(std::any::type_name::<MyMap>(), info.type_name());
assert_eq!(std::any::type_name::<usize>(), info.key_type_name());
assert_eq!(std::any::type_name::<f32>(), info.value_type_name());
} else {
panic!("Expected `TypeInfo::Map`");
}
let value: &dyn Reflect = &MyMap::new();
let info = value.get_type_info();
assert!(info.is::<MyMap>());
// Value
type MyValue = String;
let info = MyValue::type_info();
if let TypeInfo::Value(info) = info {
assert!(info.is::<MyValue>());
assert_eq!(std::any::type_name::<MyValue>(), info.type_name());
} else {
panic!("Expected `TypeInfo::Value`");
}
let value: &dyn Reflect = &String::from("Hello!");
let info = value.get_type_info();
assert!(info.is::<MyValue>());
// Dynamic
type MyDynamic = DynamicList;
let info = MyDynamic::type_info();
if let TypeInfo::Dynamic(info) = info {
assert!(info.is::<MyDynamic>());
assert_eq!(std::any::type_name::<MyDynamic>(), info.type_name());
} else {
panic!("Expected `TypeInfo::Dynamic`");
}
let value: &dyn Reflect = &DynamicList::default();
let info = value.get_type_info();
assert!(info.is::<MyDynamic>());
}
#[test]
fn as_reflect() {
trait TestTrait: Reflect {}
#[derive(Reflect)]
struct TestStruct;
impl TestTrait for TestStruct {}
let trait_object: Box<dyn TestTrait> = Box::new(TestStruct);
// Should compile:
let _ = trait_object.as_reflect();
}
#[test]
fn should_reflect_debug() {
#[derive(Reflect)]
struct Test {
value: usize,
list: Vec<String>,
array: [f32; 3],
map: HashMap<i32, f32>,
a_struct: SomeStruct,
a_tuple_struct: SomeTupleStruct,
custom: CustomDebug,
unknown: Option<String>,
#[reflect(ignore)]
#[allow(dead_code)]
ignored: isize,
}
#[derive(Reflect)]
struct SomeStruct {
foo: String,
}
#[derive(Reflect)]
struct SomeTupleStruct(String);
#[derive(Reflect)]
#[reflect(Debug)]
struct CustomDebug;
impl Debug for CustomDebug {
fn fmt(&self, f: &mut Formatter<'_>) -> std::fmt::Result {
f.write_str("Cool debug!")
}
}
let mut map = HashMap::new();
map.insert(123, 1.23);
let test = Test {
value: 123,
list: vec![String::from("A"), String::from("B"), String::from("C")],
array: [1.0, 2.0, 3.0],
map,
a_struct: SomeStruct {
foo: String::from("A Struct!"),
},
a_tuple_struct: SomeTupleStruct(String::from("A Tuple Struct!")),
custom: CustomDebug,
unknown: Some(String::from("Enums aren't supported yet :(")),
ignored: 321,
};
let reflected: &dyn Reflect = &test;
let expected = r#"
bevy_reflect::tests::should_reflect_debug::Test {
value: 123,
list: [
"A",
"B",
"C",
],
array: [
1.0,
2.0,
3.0,
],
map: {
123: 1.23,
},
a_struct: bevy_reflect::tests::should_reflect_debug::SomeStruct {
foo: "A Struct!",
},
a_tuple_struct: bevy_reflect::tests::should_reflect_debug::SomeTupleStruct(
"A Tuple Struct!",
),
custom: Cool debug!,
unknown: Reflect(core::option::Option<alloc::string::String>),
}"#;
assert_eq!(expected, format!("\n{:#?}", reflected));
}
#[cfg(feature = "glam")]
mod glam {
use super::*;
#[test]
fn vec3_serialization() {
let v = vec3(12.0, 3.0, -6.9);
let mut registry = TypeRegistry::default();
registry.register::<f32>();
registry.register::<Vec3>();
let ser = ReflectSerializer::new(&v, &registry);
let result = ron::to_string(&ser).expect("Failed to serialize to string");
assert_eq!(
result,
r#"{"type":"glam::vec3::Vec3","struct":{"x":{"type":"f32","value":12.0},"y":{"type":"f32","value":3.0},"z":{"type":"f32","value":-6.9}}}"#
);
}
#[test]
fn vec3_deserialization() {
let data = r#"{"type":"glam::vec3::Vec3","struct":{"x":{"type":"f32","value":12},"y":{"type":"f32","value":3},"z":{"type":"f32","value":-6.9}}}"#;
let mut registry = TypeRegistry::default();
registry.add_registration(Vec3::get_type_registration());
registry.add_registration(f32::get_type_registration());
let de = ReflectDeserializer::new(&registry);
let mut deserializer =
ron::de::Deserializer::from_str(data).expect("Failed to acquire deserializer");
let dynamic_struct = de
.deserialize(&mut deserializer)
.expect("Failed to deserialize");
let mut result = Vec3::default();
result.apply(&*dynamic_struct);
assert_eq!(result, vec3(12.0, 3.0, -6.9));
}
#[test]
fn vec3_field_access() {
let mut v = vec3(1.0, 2.0, 3.0);
assert_eq!(*v.get_field::<f32>("x").unwrap(), 1.0);
*v.get_field_mut::<f32>("y").unwrap() = 6.0;
assert_eq!(v.y, 6.0);
}
#[test]
fn vec3_path_access() {
let mut v = vec3(1.0, 2.0, 3.0);
assert_eq!(*v.path("x").unwrap().downcast_ref::<f32>().unwrap(), 1.0);
*v.path_mut("y").unwrap().downcast_mut::<f32>().unwrap() = 6.0;
assert_eq!(v.y, 6.0);
}
#[test]
fn vec3_apply_dynamic() {
let mut v = vec3(3.0, 3.0, 3.0);
let mut d = DynamicStruct::default();
d.insert("x", 4.0f32);
d.insert("y", 2.0f32);
d.insert("z", 1.0f32);
v.apply(&d);
assert_eq!(v, vec3(4.0, 2.0, 1.0));
}
}
}
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