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How to Use the TypeScript satisfies Operator
9 min read

How to Use the TypeScript satisfies Operator

Introduction

This post is about how to use TypeScript satisfies operator to effectively apply property value conformance in complex object types with nested properties.

TypeScript's satisfies operator comes with a few features that allow developers to check and validate the value of a variable against a given type. It was introduced in version v4.9 specifically to match type of variable values after their assignment, rather than setting an annotation prior to it.

As of the features added to the current iteration (dating November, 2023), satisfies supports property value conformance, property name constraining and property name fulfillment -- largely associated with the Record<> utility type. It also allows optional member conformance with partial types transformed with Partial<>.

In this post, we get into the details of using TypeScript satisfies while validating types of property values in a fairly nested user (joe) object. We first consider how satisfies is focused on type checking and validation of variable values, rather than their annotation. We explore examples that further illustrate type validation of nested properties of objects - which we transform with the Record<> utility. We also understand how satisfies is geared to handle associated property name constraining and fulfillment that come with the Record<> type. In the end, we go through an example of partial member conformance with the Partial<> transformation utility.

Step by step, we'll cover the following:

TypeScript Setup

Your JavaScript engine has to have TypeScript installed. It could be Node.js in your local machine with TypeScript supported or you could use the TypeScript Playground.

Prior Knowledge

The TypeScript concepts covered in this post range from Intermediate to Advanced. We assume you are already familiar with the following:

  1. TypeScript Union Types
  2. Typing a variable in TypeScript. If you are not already familiar with this, please go through the examples here
  3. Typing an object literal in TypeScript. More here
  4. Utility types, particularly how to transform types with the Record<> and Partial<> utilities. Feel free to get a refesher on all TypeScript utility types from the docs here

What is the TypeScript satisfies Operator ?

TypeScript's satisfies operator is a syntax that helps developers validate the type of a variable's value after assignment. It does this by first matching the value to the type and then remembering the internals of the matched type, i.e. the properties and methods. As such, satisfies keeps track of the types of the nested property values, helps catching otherwise uncaught TypeScript errors, and complying deeply with nested property types as well. It is thus a syntax aimed specifically for validating types on nested property values of objects with certain degrees of complexity.

Here's a nested joe user object example:

type TAddress = {
addressLine1: string;
addressLine2?: string;
postCode: number | string;
city: string;
state: string;
country: string;
};

type UserKeys = "username" | "email" | "firstName" | "lastName" | "address";
type TUser = Record<UserKeys, string | TAddress>;

const joe = {
username: "joe_hiyden",
email: "joe@exmaple.com",
firstName: "Joe",
lastName: "Hiyden",
address: {
addressLine1: "1, New Avenue",
addressLine2: "Old Avenue",
postCode: 12345,
city: "California",
state: "California",
country: "USA",
},
} satisfies TUser;

console.log(joe.address.postCode); // 12345

Notice in the example that, we have used TUser on joe for its value validation with satisfies. And TUser is a transformed record with Record<UserKeys, string | TAddress>

TypeScript satisfies Leverages Contextual Typing

It is necessary to understand that type inference before assignment is different from type validation of the assigned value with satisfies. In other words, joe above has a contextual typing: its type is set to itself and then satisfies checks joe's internals against it to validate the types for all properties and their values, including nested ones. You can find joe's type when you hover over joe. You'll see this:

// joe's inferred type is the object itself

const joe: {
username: string;
email: string;
firstName: string;
lastName: string;
address: {
addressLine1: string;
addressLine2: string;
postCode: number;
city: string;
state: string;
country: string;
};
};

TypeScript satisfies - Annotated Type Has Precedence Over satisfies Type

When we explicitly annotate the variable joe, the annotated type gains precedence during type checking over the one passed to satisfies. We get errors indicating the annotated type's loose specificity on its nested properties. Notice the 2339 error when we annotate joe with TUser:

type TAddress = {
addressLine1: string;
addressLine2?: string;
postCode: number | string;
city: string;
state: string;
country: string;
};

type UserKeys = "username" | "email" | "firstName" | "lastName" | "address";
type TUser = Record<UserKeys, string | TAddress>;

const joe: TUser = {
username: "joe_hiyden",
email: "joe@exmaple.com",
firstName: "Joe",
lastName: "Hiyden",
address: {
addressLine1: "1, New Avenue",
addressLine2: "Mission Bay",
postCode: 12345,
city: "California",
state: "California",
country: "USA",
},
} satisfies TUser;

console.log(joe.address.postCode); // Property 'postCode' does not exist on type 'string | TAddress'. Property 'postCode' does not exist on type 'string'.(2339)

In the modification above, we are using the same TUser type for both annotating joe and for validating it with satisfies. Clearly, since annotating with TUser gains precedence, it doesn't keep track of the internal information we are trying to get from inside the address object nested in joe. TypeScript confuses the TAddress type with the other ones typed with string.

The point to be delivered here is that type inference or annotation of the variable declaration, joe, is not the same thing as type validation of its value with satisfies. And satisfies is not intended for annotation, but rather largely for validating conformance.

TypeScript satisfies - Checking for Property Value Conformance

Annotating joe above with TUser prevents access to joe.address on the grounds of TypeScript's typal dissonance between the union members: string and TAddress. Removing it and reinstating validation with satisfies restores clarity and access, because satisfies keeps track of the types of all property names and values at nested levels:

type TAddress = {
addressLine1: string;
addressLine2?: string;
postCode: number | string;
city: string;
state: string;
country: string;
};

type UserKeys = "username" | "email" | "firstName" | "lastName" | "address";
type TUser = Record<UserKeys, string | TAddress>;

const joe = {
username: "joe_hiyden",
email: "joe@exmaple.com",
firstName: "Joe",
lastName: "Hiyden",
address: {
addressLine1: "1, New Avenue",
addressLine2: "Mission Bay",
postCode: 12345,
city: "California",
state: "California",
country: "USA",
},
} satisfies TUser;

console.log(joe.address.postCode); // 12345

Since we are using a number for joe.address.postCode above, satisfies correctly tracks it and no longer leads to the 2339 error.

TypeScript satisfies - Property Name Constraining

Notice that we are using the Record<> utility to derive a record type for the user. TypeScript satisfies is generally used in conjunction with the Record<> type. And as you notice already, we are applying property name constraints to limit TUser's keys with: type UserKeys = "username" | "email" | "firstName" | "lastName" | "address";.

Due to this, property overloading is prevented. In the below version, role is not included in UserKeys, so we get a complain:

type TAddress = {
addressLine1: string;
addressLine2?: string;
postCode: number | string;
city: string;
state: string;
country: string;
};

type UserKeys = "username" | "email" | "firstName" | "lastName" | "address";
type TUser = Record<UserKeys, string | TAddress>;

const joe = {
username: "joe_hiyden",
email: "joe@exmaple.com",
firstName: "Joe",
lastName: "Hiyden",

// Complains about property overloading
role: "Admin", // Object literal may only specify known properties, and 'role' does not exist in type 'TUser'.(1360)
address: {
addressLine1: "1, New Avenue",
addressLine2: "Mission Bay",
postCode: 12345,
city: "California",
state: "California",
country: "USA",
},
} satisfies TUser;

console.log(joe.address.postCode); // 12345

TypeScript satisfies - Property Name Fulfillment

Similarly, if we have a missing property in joe, we get accused till we get all properties included:

type TAddress = {
addressLine1: string;
addressLine2?: string;
postCode: number | string;
city: string;
state: string;
country: string;
};

type UserKeys = "username" | "email" | "firstName" | "lastName" | "address";
type TUser = Record<UserKeys, string | TAddress>;

const joe = {
username: "joe_hiyden",
email: "joe@exmaple.com",
firstName: "Joe",
// lastName missing
address: {
addressLine1: "1, New Avenue",
addressLine2: "Mission Bay",
postCode: 12345,
city: "California",
state: "California",
country: "USA",
},
// Complains about missing property at `satisfies`
} satisfies TUser; // Property 'lastName' is missing in type '{ username: string; email: string; firstName: string; address: { addressLine1: string; addressLine2: string; postCode: number; city: string; state: string; country: string; }; }' but required in type 'TUser'.(1360)

TypeScript satisfies - Optional Member Conformance

Instead of mandatory property name fulfillment, we can force an optional member conformance with a Partial<> transformation. In the following update, there's no complains about any missing property (lastName). We are all good:

type TAddress = {
addressLine1: string;
addressLine2?: string;
postCode: number | string;
city: string;
state: string;
country: string;
};

type UserKeys = "username" | "email" | "firstName" | "lastName" | "address";
type TUser = Record<UserKeys, string | TAddress>;

const joe = {
username: "joe_hiyden",
email: "joe@exmaple.com",
firstName: "Joe",
address: {
addressLine1: "1, New Avenue",
addressLine2: "Mission Bay",
postCode: 12345,
city: "California",
state: "California",
country: "USA",
},
} satisfies Partial<TUser>; // No complains about missing `lastName`

Summary

In this post, we covered the satisfies operator, a v4.9 addition to TypeScript. We discovered that TypeScript satisfies offers a set of features primarily aimed for type validation of assigned variable values and their nested properties and values. We illustrated through examples that the satisfies operator is used in conjunction with the Record<> utility type. In our examples, we found out that property name constraining, fulfillment associated with a Record<> derived type are handled well by TypeScript satisfies. Finally, we also saw how satisfies can be used to enforce partial member conformance with Partial<> transformation of a variable's value.

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