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Scott Hardy
Scott Hardy

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Serialization and you

Serialization is the term that describes a method to represent data so it can be transferred, stored, and accessed by multiple systems or languages.

There are many serialization formats; for our examples, we will talk about JavaScript Object Notation (JSON). JSON is a standard, language-independent file format that represents objects as key and value pairs in human-readable text.

JavaScript (and by extension TypeScript) also have "Objects"; these objects have their own rules for the keys and values. Methods (functions) can be a value for a key, while in JSON a function cannot be a value. Most importantly: JavaScript and TypeScript objects are not JSON.

For example, let's look at a simple User record for an application as a JSON representation and as an object.

Our User will have a first name, last name, and time when it was created.

First, a JSON User document:

{
    "first_name":  "Theodore",
    "last_name": "Esquire",
    "created_date": "2020-09-24T00:00:00.000Z"
}
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When a JavaScript class is used to represent a record being sent between systems or layers, it's referred to as a model class. Here is User as a TypeScript model class, with default values for illustration:

class User {
    firstName: string = "Theodore";
    lastName: string = "Esquire";
    createdDate: Date = new Date("2020-09-24T00:00:00.000Z");
}
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Let's go through the differences between the keys and values. In this example both JSON keys and the object keys are strings; however, the keys themselves are different. In the JSON example, the underscore _ is used to separate words rather than a capital letter. This use of snake_case is a choice made by the API designer; in JavaScript and TypeScript classes it's more traditional to use camelCase instead, and linter frameworks will often warn if you use snake_case variable names in JavaScript. The mapping between API conventions and JavaScript conventions is a key problem when working with JSON data.

The values from or our dataset also have some differences: in JSON they are all strings, but in TypeScript the createdDate value is not a string, it is a JavaScript Date.

Serialization is how we're able to match the different keys together and convert values into their programmable version. We can do this manually for each model class by adding custom functions:

class User {
    firstName: string;
    lastName: string;
    createdDate: Date;

    deserialize(json: Record<string, any>): this {
        this.firstName = json.first_name; // string -> string
        this.lastName = json.last_name; // string -> string
        this.createdDate = new Date(json.created_date); // string -> date
        return this;
    }
}

// ...
const user = new User().deserialize(JSON.parse(`{
    "first_name": "Theodore",
    "last_name": "Esquire",
    "created_date": "2020-09-24T00:00:00.000Z"
}`));
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Passing the JSON as our input we can use JavaScript to read it and convert it to what we need. For our date, we create a new Date from the string value. To serialize we do the same thing but return a JSON value.

class User {
    firstName: string = "Theodore";
    lastName: string = "Esquire";
    createdDate: Date = new Date("2020-09-24T00:00:00.000Z");

    deserialize(json: Record<string, any>): this {
        this.firstName = json.first_name; // string -> string
        this.lastName = json.last_name; // string -> string
        this.createdDate = new Date(json.created_date); // string -> Date
        return this;
    }

    serialize(): string {
        return JSON.stringify({
            first_name: this.firstName, // string -> string
            last_name: this.lastName, // string -> string
            created_date: this.createdDate.toJSON() // date -> string
        });
    }
}
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JSON is a common format and many programming languages have tools to help with conversions; JavaScript is no different. JSON.stringify() helps with making the JSON file format from an object that we can define. This allows us to convert the keys and values. The Date class also has a built-in function "toJSON" that helps turn the date into a string value to be stored in a JSON format.

Why is this a problem?

Defining these functions that convert to and from JSON for every model is a lot of work and can lead to duplicate code. To save on time things can be applied in a global fashion. For example, the key conversions (snake_case to camelCase) are often done a different time from serialization. Let's look at an HTTP request to understand. A user signing up will send us data and we'll send data back to the user:

User's Machine -> HTTP request with JSON data -> A server that creates and saves a user -> HTTP response with JSON data -> User's machine (success)

A web app will use a library like Axios or Angular's HttpClient to make requests to the server. These libraries have the concept of an interceptor: a function that will run right before every HTTP request or right after every HTTP response. Developers can write these functions to apply the key conversions. There are a few problems with this approach:

  1. Serializing the value and keys at different times means there needs to be an underlying knowledge of the interceptor and what it does.
  2. Not all keys should be converted. For example, the server may send a configuration map with uppercase Java enum-style keys, LIKE_THIS. Converting those keys to camelCase LIKETHIS will lead to mismatches when saving them back to the server.
  3. Not all keys are meant to be sent over the wire.
  4. Interceptors need special logic to avoid modifying other, non-JSON content types, such as multipart/form-data.

ts_serialize v1.0.0

ts_serialize is a module that supports Node.js, Deno, and browser environments. It is built to deal with all the problems mentioned while keeping serialization simple. It does this by providing a base class that model classes can extend. The base class adds the functions needed for (de)serialization and provides a decorator to define how properties are (de)serialized. Let's use ts_serialize to redefine our User Model.

import { Serializable, SerializeProperty } from "@gamebridgeai/ts_serialize";

class User extends Serializable {
    @SerializeProperty("first_name") // string -> string
    firstName: string = "Theodore";

    @SerializeProperty("last_name") // string -> string
    lastName: string = "Esquire";

    @SerializeProperty({
        serializedKey: "created_date",
        toJSONStrategy: (input) => input.toJSON(), // date -> string
        fromJSONStrategy: (json) => new Date(json), // string -> date
    })
    createdDate: Date = new Date("2020-09-24T00:00:00.000Z");
}
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Model properties without "@SerializeProperty()" do not get serialized.

Extending Serializable will add three methods: toJSON(), fromJSON(), and tsSerialize().

  • fromJSON - takes one argument, the JSON string or Object to deserialize
  • toJSON - converts the model to a JSON string with any provided key or value transformations
  • tsSerialize - converts the model to "Plain old Javascript object" with any provided key or value transformations

We can save some typing and apply the snake_case/camelCase conversion to all properties in the class. Define an optional method tsTransformKey() that uses a snake-case conversion function, like lodash's snakeCase():

import { Serializable, SerializeProperty, iso8601Date } from "@gamebridgeai/ts_serialize";
import snakeCase from "lodash.snakeCase";

/** Base class with common snake_case configuration for this app */
abstract class BaseModel extends Serializable {
    tsTransformKey(key: string): string {
        return snakeCase(key);
    }
}

/** User record */
class User extends BaseModel {
    @SerializeProperty() // string -> string
    firstName: string = "Theodore";

    @SerializeProperty() // string -> string
    lastName: string = "Esquire";

    @SerializeProperty({
        fromJSONStrategy: iso8601Date, // string -> date
    })
    createdDate: Date = new Date("2020-09-24T00:00:00.000Z");
}
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ts_serialize keeps track of the original and serialized property names, so we don't need to configure anything to do the reverse transformation.

The example also uses the iso8601Date utility function to deserializing timestamps in standard ISO-8601 formats.

There are more details in our documentation at https://gamebridgeai.github.io/ts_serialize. The library is provided under the MIT license on GitHub at https://github.com/GameBridgeAI/ts_serialize and is available in the npm and deno package registries.

Thank you for reading.

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