Module rustc_serialize::json

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JSON parsing and serialization

What is JSON?

JSON (JavaScript Object Notation) is a way to write data in Javascript. Like XML, it allows encoding structured data in a text format that can be easily read by humans. Its simple syntax and native compatibility with JavaScript have made it a widely used format.

Data types that can be encoded are JavaScript types (see the Json enum for more details):

  • I64: equivalent to rust’s i64
  • U64: equivalent to rust’s u64
  • F64: equivalent to rust’s f64
  • Boolean: equivalent to rust’s bool
  • String: equivalent to rust’s String
  • Array: equivalent to rust’s Vec<T>, but also allowing objects of different types in the same array
  • Object: equivalent to rust’s BTreeMap<String, json::Json>
  • Null

An object is a series of string keys mapping to values, in "key": value format. Arrays are enclosed in square brackets ([ … ]) and objects in curly brackets ({ … }). A simple JSON document encoding a person, their age, address and phone numbers could look like

{
    "FirstName": "John",
    "LastName": "Doe",
    "Age": 43,
    "Address": {
        "Street": "Downing Street 10",
        "City": "London",
        "Country": "Great Britain"
    },
    "PhoneNumbers": [
        "+44 1234567",
        "+44 2345678"
    ]
}

Rust Type-based Encoding and Decoding

Rust provides a mechanism for low boilerplate encoding & decoding of values to and from JSON via the serialization API. To be able to encode a piece of data, it must implement the rustc_serialize::Encodable trait. To be able to decode a piece of data, it must implement the rustc_serialize::Decodable trait. The Rust compiler provides an annotation to automatically generate the code for these traits: #[derive(RustcDecodable, RustcEncodable)]

The JSON API provides an enum json::Json and a trait ToJson to encode objects. The ToJson trait provides a to_json method to convert an object into a json::Json value. A json::Json value can be encoded as a string or buffer using the functions described above. You can also use the json::Encoder object, which implements the Encoder trait.

When using ToJson, the Encodable trait implementation is not mandatory.

Examples of use

Using Autoserialization

Create a struct called TestStruct and serialize and deserialize it to and from JSON using the serialization API, using the derived serialization code.

extern crate rustc_serialize;
use rustc_serialize::json;

// Automatically generate `RustcDecodable` and `RustcEncodable` trait
// implementations
#[derive(RustcDecodable, RustcEncodable)]
pub struct TestStruct  {
    data_int: u8,
    data_str: String,
    data_vector: Vec<u8>,
}

fn main() {
    let object = TestStruct {
        data_int: 1,
        data_str: "homura".to_string(),
        data_vector: vec![2,3,4,5],
    };

    // Serialize using `json::encode`
    let encoded = json::encode(&object).unwrap();

    // Deserialize using `json::decode`
    let decoded: TestStruct = json::decode(&encoded).unwrap();
}

Using the ToJson trait

The examples below use the ToJson trait to generate the JSON string, which is required for custom mappings.

Simple example of ToJson usage

extern crate rustc_serialize;
use rustc_serialize::json::{self, ToJson, Json};

// A custom data structure
struct ComplexNum {
    a: f64,
    b: f64,
}

// JSON value representation
impl ToJson for ComplexNum {
    fn to_json(&self) -> Json {
        Json::String(format!("{}+{}i", self.a, self.b))
    }
}

// Only generate `RustcEncodable` trait implementation
#[derive(RustcEncodable)]
pub struct ComplexNumRecord {
    uid: u8,
    dsc: String,
    val: Json,
}

fn main() {
    let num = ComplexNum { a: 0.0001, b: 12.539 };
    let data: String = json::encode(&ComplexNumRecord{
        uid: 1,
        dsc: "test".to_string(),
        val: num.to_json(),
    }).unwrap();
    println!("data: {}", data);
    // data: {"uid":1,"dsc":"test","val":"0.0001+12.539i"};
}

Verbose example of ToJson usage

extern crate rustc_serialize;
use std::collections::BTreeMap;
use rustc_serialize::json::{self, Json, ToJson};

// Only generate `Decodable` trait implementation
#[derive(RustcDecodable)]
pub struct TestStruct {
    data_int: u8,
    data_str: String,
    data_vector: Vec<u8>,
}

// Specify encoding method manually
impl ToJson for TestStruct {
    fn to_json(&self) -> Json {
        let mut d = BTreeMap::new();
        // All standard types implement `to_json()`, so use it
        d.insert("data_int".to_string(), self.data_int.to_json());
        d.insert("data_str".to_string(), self.data_str.to_json());
        d.insert("data_vector".to_string(), self.data_vector.to_json());
        Json::Object(d)
    }
}

fn main() {
    // Serialize using `ToJson`
    let input_data = TestStruct {
        data_int: 1,
        data_str: "madoka".to_string(),
        data_vector: vec![2,3,4,5],
    };
    let json_obj: Json = input_data.to_json();
    let json_str: String = json_obj.to_string();

    // Deserialize like before
    let decoded: TestStruct = json::decode(&json_str).unwrap();
}

Parsing a str to Json and reading the result

extern crate rustc_serialize;
use rustc_serialize::json::Json;

fn main() {
    let data = Json::from_str("{\"foo\": 13, \"bar\": \"baz\"}").unwrap();
    println!("data: {}", data);
    // data: {"bar":"baz","foo":13}
    println!("object? {}", data.is_object());
    // object? true

    let obj = data.as_object().unwrap();
    let foo = obj.get("foo").unwrap();

    println!("array? {:?}", foo.as_array());
    // array? None
    println!("u64? {:?}", foo.as_u64());
    // u64? Some(13u64)

    for (key, value) in obj.iter() {
        println!("{}: {}", key, match *value {
            Json::U64(v) => format!("{} (u64)", v),
            Json::String(ref v) => format!("{} (string)", v),
            _ => format!("other")
        });
    }
    // bar: baz (string)
    // foo: 13 (u64)
}

The status of this library

While this library is the standard way of working with JSON in Rust, there is a next-generation library called Serde that’s in the works (it’s faster, overcomes some design limitations of rustc-serialize and has more features). You might consider using it when starting a new project or evaluating Rust JSON performance.

Structs

  • A Builder consumes a json::Parser to create a generic Json structure.
  • A structure to decode JSON to values in rust.
  • A structure for implementing serialization to JSON.
  • A streaming JSON parser implemented as an iterator of JsonEvent, consuming an iterator of char.
  • A Stack represents the current position of the parser in the logical structure of the JSON stream. For example foo.bar[3].x

Enums

  • The errors that can arise while parsing a JSON stream.
  • Represents a json value
  • The output of the streaming parser.
  • StackElements compose a Stack. For example, Key(“foo”), Key(“bar”), Index(3) and Key(“x”) are the StackElements compositing the stack that represents foo.bar[3].x

Traits

  • A trait for converting values to JSON

Functions

  • Create an AsJson wrapper which can be used to print a value as JSON on-the-fly via write!
  • Create an AsPrettyJson wrapper which can be used to print a value as JSON on-the-fly via write!
  • Shortcut function to decode a JSON &str into an object
  • Shortcut function to encode a T into a JSON String
  • Returns a readable error string for a given error code.

Type Aliases