Crates.io | serde-reflection-aptos |
lib.rs | serde-reflection-aptos |
version | 0.3.5 |
source | src |
created_at | 2022-05-24 19:39:57.731956 |
updated_at | 2022-05-24 19:39:57.731956 |
description | Extract representations of Serde data formats |
homepage | |
repository | https://github.com/novifinancial/serde-reflection |
max_upload_size | |
id | 593022 |
size | 135,070 |
This crate provides a way to extract format descriptions for Rust containers that implement the Serialize and/or Deserialize trait(s) of Serde.
Format descriptions are useful in several ways:
serde-generate
in order to generate class definitions and provide Serde-compatible binary
serialization in other languages (C++, python, Java, etc).Very often, Serde traits are simply implemented using Serde derive macros. In this case, you may obtain format descriptions as follows:
trace_simple_type
on the desired top-level container definition(s), thentrace_simple_type
for each enum
type. (This will fix any MissingVariants
error.)#[derive(Deserialize)]
struct Foo {
bar: Bar,
choice: Choice,
}
#[derive(Deserialize)]
struct Bar(u64);
#[derive(Deserialize)]
enum Choice { A, B, C }
// Start the tracing session.
let mut tracer = Tracer::new(TracerConfig::default());
// Trace the desired top-level type(s).
tracer.trace_simple_type::<Foo>()?;
// Also trace each enum type separately to fix any `MissingVariants` error.
tracer.trace_simple_type::<Choice>()?;
// Obtain the registry of Serde formats and serialize it in YAML (for instance).
let registry = tracer.registry()?;
let data = serde_yaml::to_string(®istry).unwrap();
assert_eq!(&data, r#"---
Bar:
NEWTYPESTRUCT: U64
Choice:
ENUM:
0:
A: UNIT
1:
B: UNIT
2:
C: UNIT
Foo:
STRUCT:
- bar:
TYPENAME: Bar
- choice:
TYPENAME: Choice
"#);
serde_reflection
is meant to extract formats for Rust containers (i.e. structs and
enums) with "reasonable" implementations of the Serde traits Serialize
and
Deserialize
.
Supported implementations include:
Plain derived implementations obtained with #[derive(Serialize, Deserialize)]
for
Rust containers in the Serde data model
Customized derived implementations using Serde attributes that are compatible with
binary serialization formats, such as #[serde(rename = "Name")]
.
Hand-written implementations of Deserialize
that are more restrictive than the
derived ones, provided that trace_value
is used during tracing to provide sample
values for all such constrained types (see the detailed example below).
Mutually recursive types provided that the first variant of each enum is
recursion-free. (For instance, enum List { None, Some(Box<List>)}
.) Note that each
enum must be traced separately with trace_type
to discover all the variants.
Unsupported idioms include:
Containers sharing the same base name (e.g. Foo
) but from different modules. (Work
around: use #[serde(rename = ..)]
)
Generic types instantiated multiple times in the same tracing session. (Work around:
use the crate serde-name
and its adapters SerializeNameAdapter
and DeserializeNameAdapter
.)
Attributes that are not compatible with binary formats (e.g. #[serde(flatten)]
, #[serde(tag = ..)]
)
Tracing type aliases. (E.g. type Pair = (u32, u64)
will not create an entry "Pair".)
Mutually recursive types for which picking the first variant of each enum does not
terminate. (Work around: re-order the variants. For instance enum List { Some(Box<List>), None}
must be rewritten enum List { None, Some(Box<List>)}
.)
The error type used in this crate provides a method error.explanation()
to help with
troubleshooting during format tracing.
In the following, more complete example, we extract the Serde formats of two containers
Name
and Person
and demonstrate how to handle a custom implementation of serde::Deserialize
for Name
.
use serde_reflection::{ContainerFormat, Error, Format, Samples, Tracer, TracerConfig};
#[derive(Serialize, PartialEq, Eq, Debug, Clone)]
struct Name(String);
// impl<'de> Deserialize<'de> for Name { ... }
#[derive(Serialize, Deserialize, PartialEq, Eq, Debug, Clone)]
enum Person {
NickName(Name),
FullName { first: Name, last: Name },
}
// Start a session to trace formats.
let mut tracer = Tracer::new(TracerConfig::default());
// Create a store to hold samples of Rust values.
let mut samples = Samples::new();
// For every type (here `Name`), if a user-defined implementation of `Deserialize` exists and
// is known to perform custom validation checks, use `trace_value` first so that `samples`
// contains a valid Rust value of this type.
let bob = Name("Bob".into());
tracer.trace_value(&mut samples, &bob)?;
assert!(samples.value("Name").is_some());
// Now, let's trace deserialization for the top-level type `Person`.
// We pass a reference to `samples` so that sampled values are used for custom types.
let (format, values) = tracer.trace_type::<Person>(&samples)?;
assert_eq!(format, Format::TypeName("Person".into()));
// As a byproduct, we have also obtained sample values of type `Person`.
// We can see that the user-provided value `bob` was used consistently to pass
// validation checks for `Name`.
assert_eq!(values[0], Person::NickName(bob.clone()));
assert_eq!(values[1], Person::FullName { first: bob.clone(), last: bob.clone() });
// We have no more top-level types to trace, so let's stop the tracing session and obtain
// a final registry of containers.
let registry = tracer.registry()?;
// We have successfully extracted a format description of all Serde containers under `Person`.
assert_eq!(
registry.get("Name").unwrap(),
&ContainerFormat::NewTypeStruct(Box::new(Format::Str)),
);
match registry.get("Person").unwrap() {
ContainerFormat::Enum(variants) => assert_eq!(variants.len(), 2),
_ => panic!(),
};
// Export the registry in YAML.
let data = serde_yaml::to_string(®istry).unwrap();
assert_eq!(&data, r#"---
Name:
NEWTYPESTRUCT: STR
Person:
ENUM:
0:
NickName:
NEWTYPE:
TYPENAME: Name
1:
FullName:
STRUCT:
- first:
TYPENAME: Name
- last:
TYPENAME: Name
"#);
trace_value
Tracing the serialization of a Rust value v
consists of visiting the structural
components of v
in depth and recording Serde formats for all the visited types.
#[derive(Serialize)]
struct FullName<'a> {
first: &'a str,
middle: Option<&'a str>,
last: &'a str,
}
let mut tracer = Tracer::new(TracerConfig::default());
let mut samples = Samples::new();
tracer.trace_value(&mut samples, &FullName { first: "", middle: Some(""), last: "" })?;
let registry = tracer.registry()?;
match registry.get("FullName").unwrap() {
ContainerFormat::Struct(fields) => assert_eq!(fields.len(), 3),
_ => panic!(),
};
This approach works well but it can only recover the formats of datatypes for which nontrivial samples have been provided:
In enums, only the variants explicitly covered by user samples will be recorded.
Providing a None
value or an empty vector []
within a sample may result in
formats that are partially unknown.
let mut tracer = Tracer::new(TracerConfig::default());
let mut samples = Samples::new();
tracer.trace_value(&mut samples, &FullName { first: "", middle: None, last: "" })?;
assert_eq!(tracer.registry().unwrap_err(), Error::UnknownFormatInContainer("FullName".to_string()));
For this reason, we introduce a complementary set of APIs to trace deserialization of types.
trace_type<T>
Deserialization-tracing APIs take a type T
, the current tracing state, and a
reference to previously recorded samples as input.
The core algorithm trace_type_once<T>
attempts to reconstruct a witness value of type T
by exploring the graph of all the types
occurring in the definition of T
. At the same time, the algorithm records the
formats of all the visited structs and enum variants.
For the exploration to be able to terminate, the core algorithm trace_type_once<T>
explores
each possible recursion point only once (see paragraph below).
In particular, if T
is an enum, trace_type_once<T>
discovers only one variant of T
at a time.
For this reason, the high-level API trace_type<T>
will repeat calls to trace_type_once<T>
until all the variants of T
are known.
Variant cases of T
are explored in sequential order, starting with index 0
.
Under the assumptions listed below, a single call to trace_type<T>
is guaranteed to
record formats for all the types that T
depends on. Besides, if T
is an enum, it
will record all the variants of T
.
(0) Container names must not collide. If this happens, consider using #[serde(rename = "name")]
,
or implementing serde traits manually.
(1) The first variants of mutually recursive enums must be a "base case". That is,
defaulting to the first variant for every enum type (along with None
for option values
and []
for sequences) must guarantee termination of depth-first traversals of the graph of type
declarations.
(2) If a type runs custom validation checks during deserialization, sample values must have been provided
previously by calling trace_value
. Besides, the corresponding registered formats
must not contain unknown parts.
Whenever we traverse the graph of type declarations using deserialization callbacks, the type
system requires us to return valid Rust values of type V::Value
, where V
is the type of
a given visitor
. This contraint limits the way we can stop graph traversal to only a few cases.
The first 4 cases are what we have called possible recursion points above:
Option<T>
for the second time, we choose to return the value None
to stop;Seq<T>
for the second time, we choose to return the empty sequence []
;Map<K, V>
for the second time, we choose to return the empty map {}
;enum T
for the second time, we choose to return the first variant, i.e.
a "base case" by assumption (1) above.In addition to the cases above,
The default configuration TracerConfig:default()
always picks the recorded value for a
NewTypeStruct
and never does in the other cases.
For efficiency reasons, the current algorithm does not attempt to scan the variants of enums
other than the parameter T
of the main call trace_type<T>
. As a consequence, each enum type must be
traced separately.
See the CONTRIBUTING file for how to help out.
This project is available under the terms of either the Apache 2.0 license or the MIT license.