Share via


JavaScript IntelliSense

Applies to: yesVisual Studio noVisual Studio for Mac

Note

This article applies to Visual Studio 2017. If you're looking for the latest Visual Studio documentation, see Visual Studio documentation. We recommend upgrading to the latest version of Visual Studio. Download it here

Visual Studio provides a powerful JavaScript editing experience right out of the box. Powered by a TypeScript based language service, Visual Studio delivers richer IntelliSense, support for modern JavaScript features, and improved productivity features such as Go to Definition, refactoring, and more.

Note

Starting in Visual Studio 2017, the JavaScript language service uses a new engine for the language service (called "Salsa"). Details are included in this article, and you can also read this blog post. The new editing experience also mostly applies to Visual Studio Code. See the VS Code docs for more info.

For more information about the general IntelliSense functionality of Visual Studio, see Using IntelliSense.

What's new in the JavaScript language service in Visual Studio 2017

Starting in Visual Studio 2017, JavaScript IntelliSense displays a lot more information on parameter and member lists. This new information is provided by the TypeScript language service, which uses static analysis behind the scenes to better understand your code.

TypeScript uses several sources to build up this information:

IntelliSense based on type inference

In JavaScript, most of the time there is no explicit type information available. Luckily, it is usually fairly easy to figure out a type given the surrounding code context. This process is called type inference.

For a variable or property, the type is typically the type of the value used to initialize it or the most recent value assignment.

var nextItem = 10;
nextItem; // here we know nextItem is a number

nextItem = "box";
nextItem; // now we know nextItem is a string

For a function, the return type can be inferred from the return statements.

For function parameters, there is currently no inference, but there are ways to work around this using JSDoc or TypeScript .d.ts files (see later sections).

Additionally, there is special inference for the following:

  • "ES3-style" classes, specified using a constructor function and assignments to the prototype property.
  • CommonJS-style module patterns, specified as property assignments on the exports object, or assignments to the module.exports property.
function Foo(param1) {
    this.prop = param1;
}
Foo.prototype.getIt = function () { return this.prop; };
// Foo will appear as a class, and instances will have a 'prop' property and a 'getIt' method.

exports.Foo = Foo;
// This file will appear as an external module with a 'Foo' export.
// Note that assigning a value to "module.exports" is also supported.

IntelliSense based on JSDoc

Where type inference does not provide the desired type information (or to support documentation), type information may be provided explicitly via JSDoc annotations. For example, to give a partially declared object a specific type, you can use the @type tag as shown below:

/**
 * @type {{a: boolean, b: boolean, c: number}}
 */
var x = {a: true};
x.b = false;
x. // <- "x" is shown as having properties a, b, and c of the types specified

As mentioned, function parameters are never inferred. However, using the JSDoc @param tag you can add types to function parameters as well.

/**
 * @param {string} param1 - The first argument to this function
 */
function Foo(param1) {
    this.prop = param1; // "param1" (and thus "this.prop") are now of type "string".
}

See JSDoc support in JavaScript for the JsDoc annotations currently supported.

IntelliSense based on TypeScript declaration files

Because JavaScript and TypeScript are now based on the same language service, they are able to interact in a richer way. For example, JavaScript IntelliSense can be provided for values declared in a .d.ts file (see TypeScript documentation), and types such as interfaces and classes declared in TypeScript are available for use as types in JsDoc comments.

Below, we show a simple example of a TypeScript definition file providing such type information (via an interface) to a JavaScript file in the same project (using a JsDoc tag).

TypeScript definition file

Automatic acquisition of type definitions

In the TypeScript world, most popular JavaScript libraries have their APIs described by .d.ts files, and the most common repository for such definitions is on DefinitelyTyped.

By default, the Salsa language service will try to detect which JavaScript libraries are in use and automatically download and reference the corresponding .d.ts file that describes the library in order to provide richer IntelliSense. The files are downloaded to a cache located under the user folder at %LOCALAPPDATA%\Microsoft\TypeScript.

Note

This feature is disabled by default if using a tsconfig.json configuration file, but may be set to enabled as outlined further below.

Currently auto-detection works for dependencies downloaded from npm (by reading the package.json file), Bower (by reading the bower.json file), and for loose files in your project that match a list of roughly the top 400 most popular JavaScript libraries. For example, if you have jquery-1.10.min.js in your project, the file jquery.d.ts will be fetched and loaded in order to provide a better editing experience. This .d.ts file will have no impact on your project.

See also