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Annotations to create static Dart interfaces for JavaScript APIs.

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Use this package when you want to call JavaScript APIs from Dart code, or vice versa.

This package's main library, js, provides annotations and functions that let you specify how your Dart code interoperates with JavaScript code. The Dart-to-JavaScript compilers — dartdevc and dart2js — recognize these annotations, using them to connect your Dart code with JavaScript.

Important: This library supersedes dart:js, so don't import dart:js. Instead, import package:js/js.dart.

A second library in this package, js_util, provides low-level utilities that you can use when it isn't possible to wrap JavaScript with a static, annotated API.

Example #

See the Chart.js Dart API for an end-to-end example.

Usage #

The following examples show how to handle common interoperability tasks.

Calling JavaScript functions #

@JS()
library stringify;

import 'package:js/js.dart';

// Calls invoke JavaScript `JSON.stringify(obj)`.
@JS('JSON.stringify')
external String stringify(Object obj);

Using JavaScript namespaces and classes #

@JS('google.maps')
library maps;

import 'package:js/js.dart';

// Invokes the JavaScript getter `google.maps.map`.
external Map get map;

// The `Map` constructor invokes JavaScript `new google.maps.Map(location)`
@JS()
class Map {
  external Map(Location location);
  external Location getLocation();
}

// The `Location` constructor invokes JavaScript `new google.maps.LatLng(...)`
//
// We recommend against using custom JavaScript names whenever
// possible. It is easier for users if the JavaScript names and Dart names
// are consistent.
@JS('LatLng')
class Location {
  external Location(num lat, num lng);
}

Passing object literals to JavaScript #

Many JavaScript APIs take an object literal as an argument. For example:

// JavaScript
printOptions({responsive: true});

If you want to use printOptions from Dart a Map<String, dynamic> would be "opaque" in JavaScript.

Instead, create a Dart class with both the @JS() and @anonymous annotations.

@JS()
library print_options;

import 'package:js/js.dart';

void main() {
  printOptions(Options(responsive: true));
}

@JS()
external printOptions(Options options);

@JS()
@anonymous
class Options {
  external bool get responsive;

  // Must have an unnamed factory constructor with named arguments.
  external factory Options({bool responsive});
}

Making a Dart function callable from JavaScript #

If you pass a Dart function to a JavaScript API as an argument, wrap the Dart function using allowInterop() or allowInteropCaptureThis().

To make a Dart function callable from JavaScript by name, use a setter annotated with @JS().

@JS()
library callable_function;

import 'package:js/js.dart';

/// Allows assigning a function to be callable from `window.functionName()`
@JS('functionName')
external set _functionName(void Function() f);

/// Allows calling the assigned function from Dart as well.
@JS()
external void functionName();

void _someDartFunction() {
  print('Hello from Dart!');
}

void main() {
  _functionName = allowInterop(_someDartFunction);
  // JavaScript code may now call `functionName()` or `window.functionName()`.
}

@staticInterop #

With package:js, we have historically had two different types of classes: plain @JS (those with just the @JS annotation) and @anonymous classes. Now, you can use a new one: @staticInterop.

These classes are different in that they do not allow instance members within the class itself. All such members need to go into an extension (hence “static”). Let’s look at an example:

@JS()
library static_interop;

import 'package:js/js.dart';

// Assumes there is a top-level `StaticInterop` class in a JS module.
@JS()
@staticInterop
class StaticInterop {
  external factory StaticInterop();
}

extension on StaticInterop {
  external int field;
  external int get getSet;
  external set getSet(int val);
  external int method();
}

void main() {
  var jsObj = StaticInterop();
  jsObj.field = 1;
  jsObj.method();
}

The external static extension members get lowered to JS naturally: jsObj.field becomes a property get of field in JS and jsObj.method() becomes a function invocation of method on jsObj.

In many ways, these classes are just like the plain @JS and @anonymous classes. Like with plain @JS classes, you can provide a value in @JS if you want the constructor to use a particular JS class e.g. @JS(‘module.MyJSClass’). You can also add @anonymous to @staticInterop classes if you want the factory constructor with named arguments in order to make an object literal e.g. external factory AnonymousStaticInterop({int? field1, int? field2}). Also like with plain @JS classes, you can’t inherit non-package:js classes. You should only inherit other @staticInterop classes for subtyping and inheriting extension methods. Lastly, you can freely cast JS objects to and from the three types of package:js classes.

What makes @staticInterop unique, however, is that you can use them to represent DOM objects as well as other JS objects, which you can’t with previous package:js classes. Historically, you’ve needed to use dart:html to interact with the DOM e.g. DivElement. Now, you can create your own abstraction for these objects instead of using the ones we provide in dart:html:

@JS()
library static_interop;

import 'dart:html' as html;

import 'package:js/js.dart';

@JS()
@staticInterop
class JSWindow {}

extension JSWindowExtension on JSWindow {
  external String get name;
  String get nameAllCaps => name.toUpperCase();
}

void main() {
  var jsWindow = html.window as JSWindow;
  print(jsWindow.name.toUpperCase() == jsWindow.nameAllCaps);
}

Note that you can have both external and non-external members in the extension.

Compared to non-@staticInterop package:js classes, @staticInterop classes:

  • Are more performant
  • Have better type guarantees
  • Generate less code
  • Allow non-external members
  • Allow external extension members to be renamed using @JS() e.g. @JS('renamedField')

The only catch is that virtual/dynamic dispatch is disallowed. That means methods are resolved using only the static type of the object.

In general, it's advised to use @staticInterop wherever you can, as future JS interop will only target static dispatch.

@JSExport and js_util.createDartExport #

One of the difficulties with JS interop is that most of it is exclusively focused on importing JS code to Dart, not the other way around. We have some functionality like allowInterop, which allows you to call Dart functions in JS, but this becomes cumbersome when you want to use a Dart object. You need to essentially allowInterop all members manually.

createDartExport instead lets you do this automatically. Let’s see how with an example:

import 'dart:js_util';

import 'package:expect/minitest.dart';
import 'package:js/js.dart';

// The Dart class must have `@JSExport` on it or one of its instance members.
@JSExport()
class Counter {
  int value = 0;
  @JSExport('increment')
  void renamedIncrement() {
    value++;
  }
}

@JS()
@staticInterop
class JSCounter {}

extension on JSCounter {
  external int value;
  external void increment();
}

void main() {
  var dartCounter = Counter();
  var counter = createDartExport<Counter>(dartCounter) as JSCounter;
  expect(counter.value, 0);
  counter.increment();
  expect(counter.value, 1);
  expect(dartCounter.value, 1); // Dart object gets modified
  dartCounter.value = 0;
  expect(counter.value, 0); // Changes in Dart object affect the exported object
}

There are a number of things happening here. At a high level, you pass createDartExport an instance of some Dart object that has @JSExport either on it or one of its instance members and the object’s static type if needed. Using the static type, we transform the createDartExport call into a JS object literal that is a mapping from each member’s Dart name (accounting for renames using the @JSExport annotation) to the member. The JS object essentially wraps and acts as a proxy to the exported Dart object.

Now, when we use it as a JS object (in this case, using @staticInterop), we can use the same names to access these members. We can also use the same syntax to access these members e.g. counter.value = 0. This now gives us an easy to do what we wanted before with allowInterop for each member.

There are, of course, limitations.

The only members that are “exported” are concrete instance members i.e. fields, getters, setters, and methods. That means you can’t export static members, constructors, factories, operators (the syntax complicates things), and extension methods. You can still have these members - they just won’t be present in the resulting exported object. Of course, you can use another instance member to call these members as well, and that instance member will be exported.

In order to use createDartExport, you need to have a class that uses @JSExport.If you want to export only some members of a class, omit the annotation on the class, and only use it on the members you want. If you need to rename members, you can provide the @JSExport annotation on that member a string value, similar to renaming done via @JS(). Inheritance respects the individual superclass’ annotations. In other words, if the class of the object you want to export has a superclass, but that superclass has no @JSExport annotation anywhere, none of its superclass’ members are exported.

Lastly, different members can’t have the same export name, unless they are a getter and setter pair. So, for example, if you have a field and a method and one of them is renamed to the other’s name, that’s a conflict:

@JSExport()
class DartClass {
  int member = 0;
  @JSExport('member') // Two incompatible members have the same export name.
  void method() {}
}

This holds true with inheritance as well, unless the member is overridden.

js_util.createStaticInteropMock #

One of the neat things about the above example with Counter is we’ve essentially created a mock for JSCounter. In the past, to mock a plain @JS or @anonymous class, you could create a Dart class that implements that interop class, and due to Dart's virtual dispatch, this would call the Dart class' members instead. Now that we're using external extension members, this no longer works. We now have to mock at the JS level instead. With createDartExport, you’re essentially using a Dart object to replace a JS object. This functionality is equivalent to mocking at the JS level, and you can also use it to mock the old non-@staticInterop package:js classes!

One useful feature of the old style of mocking using implements is it lets you know if you've implemented the needed members. We can't do that with createDartExport. For example:

@JSExport()
class Counter {
  // Where is `value` and `increment`?
}

This would obviously not be a satisfactory mock for JSCounter. createDartExport has no idea what class you're trying to mock, so it can't tell you if you’ve got your mock class right.

This is where createStaticInteropMock comes in. It takes in a separate type argument, e.g. createStaticInteropMock<JSCounter, Counter>(Counter()), to determine whether mocking conformance is satisfied. This type argument must be a @staticInterop class. With this, you’ll see an error saying that you haven’t implemented all the needed members. If the mock class implements all the needed members, the function does the same thing as createDartExport, and returns an object literal that wraps the Dart object.

You can also use package:mockito to do the mocking with this API, by providing a generated mocking object from package:mockito to createStaticInteropMock.

There are some corner cases here that are worth noting.

It is possible, through the expressiveness of extension methods, to have name conflicts like this:

@JS()
@staticInterop
class StaticInterop {}

extension A on StaticInterop {
  external Function member;
}

extension B on StaticInterop {
  external void member();
}

This present an issue as a single Dart class cannot implement member as both a field and a function. So, what to do? We require that you only implement one of these members. So, either a Function field or a function are satisfactory.

It is also sometimes desired that the mocking object is the same underlying type as the JS object you are interfacing. For example, if you want to mock a JS Element, you’d want the type of the mocking object to also be a Element in order to pass instanceof checks. In order to do this, we let users pass the JS prototype of the type they want the mocking object to be as an argument to createStaticInteropMock.

An important note here is that createStaticInteropMock looks for all extensions of the @staticInterop type in the program, even if they are out of scope of the current file. In order to avoid a case where other libraries extending the @staticInterop type break your usage of createStaticInteropMock, you should try to only use this API in tests. createStaticInteropMock is meant to detect issues earlier at compile-time, but if it's too restrictive, you can still use createDartExport to workaround that (and please provide us feedback on why it's restrictive!).

Reporting issues #

Please file bugs and feature requests on the SDK issue tracker.

Known limitations and bugs #

Differences between dart2js and dartdevc #

Dart's production and development JavaScript compilers use different calling conventions and type representation, and therefore have different challenges in JavaScript interop. There are currently some known differences in behavior and bugs in one or both compilers.

Dartdevc and dart2js have different representation for Maps

Passing a Map<String, String> as an argument to a JavaScript function will have different behavior depending on the compiler. Calling something like JSON.stringify() will give different results.

Workaround: Only pass object literals instead of Maps as arguments. For json specifically use jsonEncode in Dart rather than a JS alternative.

Missing validation for anonymous factory constructors in dartdevc

When using an @anonymous class to create JavaScript object literals dart2js will enforce that only named arguments are used, while dartdevc will allow positional arguments but may generate incorrect code.

Workaround: Try builds in both development and release mode to get the full scope of static validation.

Common problems #

Dart and JavaScript have different semantics and common patterns, which makes it easy to make some mistakes and difficult for the tools to provide safety. These common problems are also known as sharp edges.

Lack of runtime type checking

The return types of methods annotated with @JS() are not validated at runtime, so an incorrect type may "leak" into other Dart code and violate type system guarantees. This is not true for @staticInterop classes unless the @trustTypes annotation is used.

Workaround: For any calls into JavaScript code that are not known to be safe in their return values, validate the results manually with is checks.

List instances coming from JavaScript will always be List<dynamic>

A JavaScript array does not have a reified element type, so an array returned from a JavaScript function cannot make guarantees about it's elements without inspecting each one. At runtime a check like result is List may succeed, while result is List<String> will always fail.

Workaround: Use .cast() or construct a new List to get an instance with the expected reified type. For instance if you want a List<String> use .cast<String>() or List<String>.from.

The JsObject type from dart:js can't be used with @JS() annotation

JsObject and related code in dart:js uses a different approach and may not be passed as an argument to a method annotated with @JS().

Workaround: Avoid importing dart:js and only use the package:js provided approach. To handle object literals use @anonymous on an @JS() annotated class.

is checks and as casts between JS interop types will always succeed

For any two @JS() types, with or without @anonymous, a check of whether an object of one type is another type will always return true, regardless of whether those two types are in the same prototype chain. Similarly, an explicit cast using as will also succeed.

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Annotations to create static Dart interfaces for JavaScript APIs.

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