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ember-cli-typescript
Advanced tools
ember-cli-typescript is an addon for Ember.js that enables TypeScript support in Ember applications. It provides a seamless integration of TypeScript into the Ember build pipeline, allowing developers to write their Ember code in TypeScript, which offers static type checking and other benefits.
TypeScript Integration
This feature allows you to write Ember components using TypeScript. The code sample demonstrates a simple Glimmer component written in TypeScript, with type annotations for the component's arguments.
import Component from '@glimmer/component';
interface MyComponentArgs {
name: string;
}
export default class MyComponent extends Component<MyComponentArgs> {
get greeting(): string {
return `Hello, ${this.args.name}!`;
}
}
Type Checking
Type checking ensures that the types of the arguments passed to components are correct. The code sample shows a type error when an incorrect type is passed to the component.
import Component from '@glimmer/component';
interface MyComponentArgs {
name: string;
}
export default class MyComponent extends Component<MyComponentArgs> {
get greeting(): string {
return `Hello, ${this.args.name}!`;
}
}
// This will cause a type error
let component = new MyComponent({ name: 123 });
TypeScript Configuration
This feature allows you to configure TypeScript settings for your Ember project. The code sample shows a typical tsconfig.json file used to configure the TypeScript compiler options and include paths.
{
"compilerOptions": {
"target": "es6",
"module": "esnext",
"strict": true,
"noImplicitAny": true,
"moduleResolution": "node",
"baseUrl": ".",
"paths": {
"*": ["types/*"]
}
},
"include": [
"app/**/*",
"tests/**/*"
]
}
ember-cli-coffeescript is an addon that allows you to write your Ember.js code using CoffeeScript. While it provides a similar integration for a different language, it does not offer the same level of static type checking and tooling support as TypeScript.
ember-cli-babel is an addon that integrates Babel into the Ember build pipeline, allowing you to use the latest JavaScript features in your Ember code. While it does not provide type checking, it is a popular choice for modern JavaScript development in Ember.
ember-cli-flowtype is an addon that integrates Flow, a static type checker for JavaScript, into Ember projects. It offers similar type checking capabilities as TypeScript but is less commonly used in the Ember ecosystem.
Use TypeScript in your Ember 2.x and 3.x apps!
When seeking help, you should first consider what you need, and which aspect of the Ember+TypeScript ecosystem your issue pertains to.
We have a channel (#e-typescript) on the Ember Community Discord server where you can ask about getting started, good resources for self-directed learning and more.
If you've found that some of the Ember type information is missing things, or is incorrect in some way, please first ensure you're using the latest version of the packages this addon installs. Although StackOverflow and Discuss are not the advised places to report problems, you may find an answer there.
If you still see a problem, please create a bug report here or a feature request here.
If you run into a problem with the way TypeScript is compiled in Ember apps (i.e., a broccoli error message, incorrect build output, etc...), please first check StackOverflow and Discuss, as you may find an answer.
If you still need help, please open an bug report here or a feature request here
The TypeScript compiler does some very basic static analysis of your code, and most developers use Palantir's TSLint tool for more thorough checking.
One sure way to tell which tool is generating an error message is that Linters like TSLint and ESLint will always mention their name, and the name of the pertinent rule, when it alerts you to a violation.
[tslint] variable name must be in lowerCamelCase, PascalCase or UPPER_CASE (variable-name)
variable-name
is the name of the rule.
For issues relating to typescript compiler analysis, create an issue in this repository by clicking here. For TSLint-related concerns, please create an issue in the ember-cli-tslint
project by clicking here. If you run into issues with using ESLint with Ember, create an issue here.
To install or upgrade the addon, just run:
ember install ember-cli-typescript@latest
All dependencies will be added to your package.json
, and you're ready to roll! If you're upgrading from a previous release, you should check to merge any tweaks you've made to tsconfig.json
.
In addition to ember-cli-typescript, we make the following changes to your project:
We install the following packages—all at their current "latest" value—or generated:
typescript
@ember/test-helpers
.We add the following files to your project:
tsconfig.json
types/<app name>/index.d.ts
– the location for any global type declarations you need to write for you own application; see Global types for your package for information on its default contents and how to use it effectivelyapp/config/environment.d.ts
– a basic set of types defined for the contents of the config/environment.js
file in your app; see Environment and configuration typings for detailsember-cli-typescript runs its test suite against the 2.12 LTS, the 2.16 LTS, the 2.18 LTS, the current release, the beta branch, and the canary branch. It's also in active use in several large applications. Any breakage for upcoming releases should be detected and fixed ahead of those releases, but you can help us guarantee that by running your own Ember.js+TypeScript app with beta and canary turned on and let us know if you run into issues with upcoming Ember.js releases.
This library supports the current version of TypeScript and at least one previous minor or major release (i.e., if 3.0
is the latest release, we do support 3.0.x
, 2.9.x
, and might support 2.8
as well).
tsconfig.json
We generate a good default tsconfig.json
, which will usually make everything Just Work™. In general, you may customize your TypeScript build process as usual using the tsconfig.json
file.
However, there are a few things worth noting if you're already familiar with TypeScript and looking to make further or more advanced customizations (i.e. most users can just ignore this section!):
The generated tsconfig file does not set "outDir"
and sets "noEmit"
to true
. Under the hood, Ember's own invocation of tsc
does set these, but the default configuration we generate allows you to run editors which use the compiler without creating extraneous .js
files throughout your codebase, leaving the compilation to ember-cli-typescript to manage.
You can still customize those properties in tsconfig.json
if your use case requires it, however. For example, to see the output of the compilation in a separate folder you are welcome to set "outDir"
to some path and set "noEmit"
to false
. Then tools which use the TypeScript compiler (e.g. the watcher tooling in JetBrains IDEs) will generate files at that location, while the Ember.js/Broccoli pipeline will continue to use its own temp folder.
Closely related to the previous point: any changes you do make to outDir
won't have any effect on how Ember builds your application—we have to pipe everything into Ember CLI via broccoli, so we override that. In general, everything else works just as you'd expect, though!
By default, we target the highest stable version of JavaScript available in the TypeScript compiler, so that you may ship anything from that very code without further modification to browsers that support it all the way back to ES3, in line with the Babel configuration in your app's config/targets.js
. You can set this target to whatever is appropriate for your application, but we strongly encourage you to leave it set to the highest stable version of JavaScript if you are developing an addon, so that consumers of your addon have full flexibility in this regard.
If you make changes to the paths included in or excluded from the build via your tsconfig.json
(using the "include"
, "exclude"
, or "files"
keys), you will need to restart the server to take the changes into account: ember-cli-typescript does not currently watch the tsconfig.json
file.
To enable TypeScript sourcemaps, you'll need to add the corresponding configuration for Babel to your ember-cli-build.js
file:
const app = new EmberApp(defaults, {
babel: {
sourceMaps: 'inline',
},
});
(Note that this will noticeably slow down your app rebuilds.)
If you're updating from an older version of the addon, you may also need to update your tsconfig.json
. (Current versions generate the correct config at installation.) Either run
ember generate ember-cli-typescript
or verify you have the same sourcemap settings in your tscsonfig.json
that appear in the blueprint.
In addition to the points made below, you may find the Typing Your Ember blog series (especially the "Update" sequence) particularly helpful in knowing how to do specific things.
If you are porting an existing app to TypeScript, you can install this addon and migrate your files incrementally by changing their extensions from .js
to .ts
. As TypeScript starts to find errors (and it usually does!), make sure to celebrate your wins – even if they're small! – with your team, especially if some people are not convinced yet. We would also love to hear your stories!
Some specific tips for success on the technical front:
Use the strictest strictness settings that our typings allow. While it may be tempting to start with the loosest strictness settings and then to tighten them down as you go, this will actually mean that "getting your app type-checking" will become a repeated process – getting it type-checking with every new strictness setting you enable! – rather than something you do just once. The only strictness setting you should turn off is strictFunctionTypes
, which our current type definitions do not support. The recommended strictness settings in your "compilerOptions"
hash:
"noImplicitAny": true,
"noImplicitThis": true,
"alwaysStrict": true,
"strictNullChecks": true,
"strictPropertyInitialization": true,
"noFallthroughCasesInSwitch": true,
"noUnusedLocals": true,
"noUnusedParameters": true,
"noImplicitReturns": true,
Make liberal use of any
for things you don't have types for as you go, and come back and fill them in later. This will let you do the strictest strictness settings but with an escape hatch that lets you say "We will come back to this when we have more idea how to handle it."
A good approach is to start at your "leaf" files (the ones that don't import anything else from your app, only Ember types) and then work your way back inward toward the most core types that are used everywhere. Often the highest-value modules are your Ember Data models and any core services that are used everywhere else in the app – and those are also the ones that tend to have the most cascading effects (having to update tons of other places in your app) when you type them later in the process.
Set "noEmitOnError": true
in the "compilerOptions"
hash in your tsconfig.json
– it will help a lot if you can be sure that for the parts of your app you have added types to are still correct. And you'll get nice feedback immediately when you have type errors that way!
You may find the blog series "Typing Your Ember" helpful as it walks you through not only how to install but how to most effectively use TypeScript in an Ember app today, and gives some important info on the background and roadmap for the project.
You'll want to use other type definitions as much as possible. The first thing you should do, for example, is install the types for your testing framework of choice: @types/ember-mocha
or @types/ember-qunit
. Beyond that, look for types from other addons: it will mean writing any
a lot less and getting a lot more help both from your editor and from the compiler.
To make this easier, we're maintaining a list of addons with known type definitions either on Definitely Typed or as part of the addon itself. (If you know of typings that aren't in that list, please open a pull request to add them!)
types
directoryDuring installation, we create a types
directory in the root of your application and add a "paths"
mapping that includes that directory in any type lookups TypeScript tries to do. This is convenient for a few things:
vendor
packages which do not have any typesThese are all fallbacks, of course, you should use the types supplied directly with a package
At the root of your application or addon, we include a types/<your app>
directory with an index.d.ts
file in it. Anything which is part of your application but which must be declared globally can go in this file. For example, if you have data attached to the Window
object when the page is loaded (for bootstrapping or whatever other reason), this is a good place to declare it.
In the case of applications (but not for addons), we also automatically include declarations for Ember's prototype extensions in this index.d.ts
file, with the Array
prototype extensions enabled and the Function
prototype extensions commented out. You should configure them to match your own config (which we cannot check during installation). If you are disabling Ember's prototype extensions, you can remove these declarations entirely; we include them because they're enabled in most Ember applications today.
Along with the @types/ files mentioned above, ember-cli-typescript adds a starter interface for config/environment.js
in app/config/environment.d.ts
. This interface will likely require some changes to match your app.
We install this file because the actual config/environment.js
is (a) not actually identical with the types as you inherit them in the content of an application, but rather a superset of what an application has access to, and (b) not in a the same location as the path at which you look it up. The actual config/environment.js
file executes in Node during the build, and Ember CLI writes its result as <my-app>/config/environment
into your build for consumption at runtime.
Ember makes heavy use of string-based APIs to allow for a high degree of dynamicism. With some limitations, you can nonetheless use TypeScript very effectively to get auto-complete/IntelliSense as well as to accurately type-check your applications.
The "Update" sequence in the Typing Your Ember has detailed explanations and guides for getting good type-safety for Ember's string-based APIs, e.g. the use of get
and set
, service and controller injection, Ember Data models and lookups
Ember.Object
world.A few of the most common speed-bumps are listed here to help make this easier:
this
type workaroundOne important note for using class
types effectively with today's Ember typings: you will (at least for now) need to explicitly write out a this
type for methods, computed property callbacks, and actions if you are going to use get
or set
import Component from '@ember/component';
export default class UserProfile extends Component {
changeUsername(this: UserProfile, userName: string) {
// ^---------------^
// `this` tells TS to use `UserProfile` for `get` and `set` lookups
}
}
This is a workaround for how incredibly dynamic Ember.Object
instances are and hopefully will improve over time as we continue to iterate on the type definitions. Again, see the relevant blog post for details.
get
or set
In general, this.get
and this.set
will work as you'd expect if you're doing lookups only a single layer deep. Things like this.get('a.b.c')
don't (and can't ever!) type-check; see the blog posts for a more detailed discussion of why.
The workaround is simply to do one of two things:
The type-safe approach. This will typecheck, but is both ugly and only works *if there are no null
s or undefined
s along the way. If nested
is null
at runtime, this will crash!
import { get } from '@ember/object';
// -- Type-safe but ugly --//
get(get(get(someObject, 'deeply'), 'nested'), 'key');
Using // @ts-ignore
. This will not do any type-checking, but is useful for the cases where you are intentionally checking a path which may be null
or undefined
anywhere long it.
// @ts-ignore
get(someObject, 'deeply.nested.key');
It's usually best to include an explanation of why you're ignoring a lookup!
Ember does service and controller lookups with the inject
functions at runtime, using the name of the service or controller being injected up as the default value—a clever bit of metaprogramming that makes for a nice developer experience. TypeScript cannot do this, because the name of the service or controller to inject isn't available at compile time in the same way.
This means that if you do things the normal Ember way, you will have to specify the type of your service or controller explicitly everywhere you use it. But… where should we put that? If we try to set it up as a class property, we'll get an error as of Ember 3.1 (and it only accidentally works before that): computed properties and injections must be installed on the prototype.
There are two basic approaches we can take. The first uses the .extend
method in conjunction with class definitions to make sure the injections are set up correctly; the second leans on the still-experimental Ember Decorators project to let us do everything in the class body while still getting the niceties of ES6 classes. The decorators approach is much nicer, and likely to eventually become the standard across Ember in general assuming the decorators spec stabilizes. For today, however, it's an opt-in rather than the default because it remains an experimental extension to the JavaScript standard.
.extend
The officially supported method for injections uses a combination of class body and traditional EmberObject.extend
functionality. We generate a service like normal by running ember generate service my-session
. The resulting definition will look like this:
// my-app/services/my-session.ts
import Service from '@ember/service';
import RSVP from 'rsvp';
export default class MySession extends Service {
login(email: string, password: string): RSVP.Promise<string> {
// login and return the confirmation message
}
}
declare module '@ember/service' {
interface Registry {
'my-session': MySession;
}
}
You'll need to add that module and interface declaration to all your existing service and controller declarations for this to work (again, see the blog post for further details), but once you do that, you'll have this much nicer experience throughout! It's not quite vanilla Ember.js, but it's close—and this way, you still get all those type-checking and auto-completion benefits, but with a lot less noise! Moreover, you actually get a significant benefit over "vanilla" Ember: we type-check that you typed the key correctly in the service
invocation.
Then we can use the service as usual:
// my-app/components/user-profile.ts
import Component from '@ember/component';
import { inject as service } from '@ember/service';
export default class UserProfile extends Component.extend({
mySession: service('my-session'),
}) {
login(email: string, password: string) {
this.session.login(email, password);
}
}
Notice that the type of mySession
will be the MySession
type here: TypeScript is using the "registry" set up in the last lines of the my-session
module to look up the type by its name. If we had written just service()
instead, Ember would have resolved the correct type at runtime as usual, but TypeScript would not be able to tell which service we had, only that it was a Service
. In that case, the this.session
would not have a login
property from TS's perspective, and this would fail to type-check. That extra string gives TS the information it needs to resolve the type and give us auto-completion, type-checking, etc.
(In Ember 3.0 or earlier, we would have this.get('session').login(email, password);
instead.)
Although this may look a little strange, everything works correctly. We can use other ES6 class functionality and behaviors (including class properties) as normal; it is just the special Ember pieces which have to be set up on the prototype like this: injections, computed properties, and the actions
hash.
The alternative here is to use Ember Decorators. In that case, we'd have precisely the same definition for our MySession
service, but a much cleaner implementation in the component class:
// my-app/components/user-profile.ts
import Component from '@ember/component';
import { service } from '@ember-decorators/service';
import MySession from 'my-app/services/my-session';
export default class UserProfile extends Component {
@service mySession!: MySession;
login(this: UserProfile, email: string, password: string) {
this.session.login(email, password);
}
}
Note that we need the MySession
type annotation this way, but we don't need the string lookup (unless we're giving the service a different name than the usual on the class, as in Ember injections in general). Without the type annotation, the type of session
would just be any
. This is because decorators (as of TS 2.8 – 3.0) are not allowed to modify the types of whatever they decorate. As a result, we wouldn't get any type-checking on that session.login
call, and we wouldn't get any auto-completion either. Which would be really sad and take away a lot of the reason we're using TypeScript in the first place!
Also use the !
non-null assertion operator to prevent TS2564
, that is caused by enabling strictPropertyInitialization
in tsconfig.json
.
If you're on an Ember version below 3.1, you'll want to wrap your service type in ComputedProperty
, because native ES5 getters are not available there, which means that instead of accessing the service via this.mySession
, you would have to access it as this.get('mySession')
or get(this, 'mySession')
. This means the above code would rather look like:
// my-app/components/user-profile.ts
import Component from '@ember/component';
import { get } from '@ember/object';
import ComputedProperty from '@ember/object/computed';
import { service } from '@ember-decorators/service';
import MySession from 'my-app/services/my-session';
export default class UserProfile extends Component {
@service mySession!: ComputedProperty<MySession>;
login(this: UserProfile, email: string, password: string) {
get(this, 'session').login(email, password);
}
}
This also holds true for all other macros of the ember-decorators addon.
We use the same basic approach for Ember Data type lookups with string keys as we do for service or controller injections. As a result, once you add the module and interface definitions for each model, serializer, and adapter in your app, you will automatically get type-checking and autocompletion and the correct return types for functions like findRecord
, queryRecord
, adapterFor
, serializerFor
, etc. No need to try to write out those (admittedly kind of hairy!) types; just write your Ember Data calls like normal and everything should just work.
The declarations and changes you need to add to your existing files are:
Models
import DS from 'ember-data';
export default class UserMeta extends DS.Model.extend({
// attribute declarations here, as usual
}) {}
declare module 'ember-data' {
interface ModelRegistry {
'user-meta': UserMeta;
}
}
Adapters
import DS from 'ember-data';
export default class UserMeta extends DS.Adapter {
// properties and methods
}
declare module 'ember-data' {
interface AdapterRegistry {
'user-meta': UserMeta;
}
}
Serializers
import DS from 'ember-data';
export default class UserMeta extends DS.Serializer {
// properties and methods
}
declare module 'ember-data' {
interface SerializerRegistry {
'user-meta': UserMeta;
}
}
In addition to the registry, note the oddly defined class for DS.Model
s. This is because we need to set up the attribute bindings on the prototype (for a discussion of how and why this is different from class properties, see Typing Your Ember, Update, Part 2), but we cannot just use a const
here because we need a named type—like a class!—to reference in the type registry and elsewhere in the app.
Also notice that unlike with service and controller injections, there is no unsafe fallback method by default, because there isn't an argument-less variant of the functions to use as there is for Service
and Controller
injection. If for some reason you want to opt out of the full type-safe lookup for the strings you pass into methods like findRecord
, adapterFor
, and serializerFor
, you can add these declarations somewhere in your project:
import DS from 'ember-data';
declare module 'ember-data' {
interface ModelRegistry {
[key: string]: DS.Model;
}
interface AdapterRegistry {
[key: string]: DS.Adapter;
}
interface SerializerRegistry {
[key: string]: DS.Serializer;
}
}
However, we strongly recommend that you simply take the time to add the few lines of declarations to each of your DS.Model
, DS.Adapter
, and DS.Serializer
instances instead. It will save you time in even the short run!
error TS2344
problemIf you're developing an Ember app or addon and not using Ember Data (and accordingly not even have the Ember Data types installed), you may see an error like this and be confused:
node_modules/@types/ember-data/index.d.ts(920,56): error TS2344: Type 'any' does not satisfy the constraint 'never'.
This happens because the types for Ember's test tooling includes the types for Ember Data because the this
value in several of Ember's test types can include a reference to DS.Store
.
The fix: add a declaration like this in a new file named ember-data.d.ts
in your types
directory:
declare module 'ember-data' {
interface ModelRegistry {
[key: string]: any;
}
}
This works because (a) we include things in your types directory automatically and (b) TypeScript will merge this module and interface declaration with the main definitions for Ember Data from DefinitelyTyped behind the scenes.
If you're developing an addon and concerned that this might affect consumers, it won't. Your types directory will never be referenced by consumers at all!
Some common stumbling blocks for people switching to ES6 classes from the traditional EmberObject setup:
Assertion Failed: InjectedProperties should be defined with the inject computed property macros.
– You've written someService = inject()
in an ES6 class body in Ember 3.1+. Replace it with the .extend
approach or by using decorators (@service
or @controller
) as discussed above. Because computed properties of all sorts, including injections, must be set up on a prototype, not on an instance, if you try to use class properties to set up injections, computed properties, the action hash, and so on, you will see this error.
Assertion Failed: Attempting to lookup an injected property on an object without a container, ensure that the object was instantiated via a container.
– You failed to pass ...arguments
when you called super
in e.g. a component class constructor
. Always do super(...arguments)
, not just super()
, in your constructor
.
node_modules/@types
By default, the TypeScript compiler loads all type definitions found in node_modules/@types
. If the type defs you need are not found there and are not supplied in the root of the package you're referencing, you can register a custom value in paths
in the tsconfig.json
file. For example, if you're using ember-browserify, you're used to writing imports like this:
import MyModule from 'npm:my-module';
If my-module
has types, you will not be able to resolve them this way by default. You can add a simple tweak to your tsconfig.json
to resolve the types correctly, however, mapping npm:*
to node_modules/*
.
{
"compilerOptions": {
"paths": {
"my-app-name/*": ["app/*"],
"npm:*": ["node_modules/*"]
}
}
}
Mirage adds files from a nonstandard location to your application tree, so you'll need to tell the TypeScript compiler about how that layout works.
For an app, this should look roughly like:
{
"compilerOptions": {
"paths": {
// ...
"my-app-name/mirage/*": "mirage/*",
}
},
"include": [
"app",
"tests",
"mirage"
]
}
And for an addon:
{
"compilerOptions": {
"paths": {
// ...
"dummy/mirage/*": "tests/dummy/mirage/*",
}
},
"include": [
"addon",
"tests"
]
}
Note that if Mirage was present when you installed ember-cli-typescript (or if you run ember g ember-cli-typescript
), this configuration should be automatically set up for you.
You may sometimes see TypeScript errors indicating that you have duplicate type definitions for Ember, Ember Data, etc. This is usually the result of an annoying quirk of the way both npm and yarn resolve your dependencies in their lockfiles.
There are two options here, neither of them great:
yarn.lock
or package-lock.json
and merge the conflictingpackage.json
with the version you want to install of the types you're installing:{
"resolutions": {
"**/@types/ember": "2.8.15"
}
}
If you're using another package which includes these types, and then you trigger an upgrade for your own copy of the type definitions, npm and yarn will both try to preserve the existing installation and simply add a new one for your updated version. In most cases, this is sane behavior, because it prevents transitive dependency breakage hell. However, in the specific case of type definitions, it causes TypeScript to get confused.
During development, your .ts
files will be watched and rebuilt just like any other sources in your addon when you run ember serve
, ember test
, etc.
However, in order not to force downstream consumers to install the entire TS build toolchain when they want to use an addon written in TypeScript, ember-cli-typescript is designed to allow you to publish vanilla .js
files to the npm registry, alongside .d.ts
declarations so that consumers who are using TypeScript can benefit from it.
This addon provides two commands to help with publishing your addon: ember ts:precompile
and ember ts:clean
. The default ember-cli-typescript
blueprint will configure your package.json
to run these commands in the prepublishOnly
and postpublish
phases respectively, but you can also run them by hand to verify that the output looks as you expect.
The ts:precompile
command will put compiled .js
files in your addon
directory and populate the overall structure of your package with .d.ts
files laid out to match their import paths. For example, addon/index.ts
would produce addon/index.js
as well as index.d.ts
in the root of your package.
The ts:clean
command will remove the generated .js
and .d.ts
files, leaving your working directory back in a pristine state.
Note: While .ts
files from both the app
and addon
directories of your addon will be transpiled by ts:precompile
, only the declaration files from addon
will be published. Since the final import paths for app
files will depend on the name of the consuming application, we can't put those declaration files in a meaningful place.
Often when developing an addon, it can be useful to run that addon in the context of some other host app so you can make sure it will integrate the way you expect, e.g. using yarn link
or npm link
.
When you do this for a TypeScript addon, by default your .ts
files won't be consumed by the host app. In order for a linked addon to work, you need to take a few steps:
ember-cli-typescript
is installed and set up in the host appisDevelopingAddon()
in the linked addon to return true
paths
and include
entries in your tsconfig.json
to instruct the compiler how to resolve imports and include the addon's TypeScript files:compilerOptions: {
// ...other options
paths: {
// ...other paths, e.g. for your tests/ tree
"my-app": [
"app/*",
// add addon app directory that will be merged with the host application
"node_modules/my-addon/app/*"
],
// resolve: import x from 'my-addon';
"my-addon": [
"node_modules/my-addon/addon"
],
// resolve: import y from 'my-addon/utils/y';
"my-addon/*": [
"node_modules/my-addon/addon/*"
]
}
},
include: [
// ...other includes, e.g. app, tests, types
"node_modules/my-addon/app",
"node_modules/my-addon/addon"
]
This will cause ember-cli-typescript
in the host app to take over compiling the TS files in the addon as well, automatically rebuilding any time you make a change.
Note: remember to remove your isDevelopingAddon
override before publishing!
In-repo addons work in much the same way as linked ones: their TypeScript compilation is managed by the host app. They have isDevelopingAddon
return true
by default, so you only have to update the paths
and include
entries in your tsconfig.json
to instruct the compiler how to resolve imports and include the addon's TypeScript files:
compilerOptions: {
// ...other options
paths: {
// ...other paths, e.g. for your tests/ tree
"my-app": [
"app/*",
// add addon app directory that will be merged with the host application
"lib/my-addon/app/*"
],
// resolve: import x from 'my-addon';
"my-addon": [
"lib/my-addon/addon"
],
// resolve: import y from 'my-addon/utils/y';
"my-addon/*": [
"lib/my-addon/addon/*"
]
}
},
include: [
// ...other includes, e.g. app, tests, types
"lib/my-addon"
]
A few things to look out for when working with TypeScript in addons:
true
from their isDevelopingAddon()
hook, which ember-cli-typescript
relies on to determine whether to process the addon's .ts
files. However, if the name field in your package.json
doesn't match the name in your index.js
, this default behavior will fail and you'll need to override the method yourself.ember ts:precompile
yourself as you're getting a feel for these rules to ensure everything will go smoothly when you publish.While TS already works nicely for many things in Ember, there are a number of corners where it won't help you out. Some of them are just a matter of further work on updating the existing typings; others are a matter of further support landing in TypeScript itself, or changes to Ember's object model.
We are hard at work (and would welcome your help!) writing new typings for Ember and the surrounding ecosystem. If you'd like to try those out, please see instructions in that repo!
Here is the short list of things which do not work yet in the version of the typings published on DefinitelyTyped.
import
s don't resolveYou'll frequently see errors for imports which TypeScript doesn't know how to resolve. For example, if you use Ember Concurrency today and try to import its task
helper:
import { task } from 'ember-concurrency';
You'll see an error, because there aren't yet type definitions for it. You may see the same with some addons as well. These won't stop the build from working; they just mean TypeScript doesn't know where to find those.
Writing these missing type definitions is a great way to pitch in! Jump in #e-typescript
on the Ember Community Discord server and we'll be happy to help you.
TypeScript won't detect a mismatch between this action and the corresponding call in the template:
Ember.Component.extend({
actions: {
turnWheel(degrees: number) {
// ...
},
},
});
<button onclick={{action 'turnWheel' 'NOT-A-NUMBER'}}> Click Me </button>
Likewise, it won't notice a problem when you use the send
method:
// TypeScript compiler won't detect this type mismatch
this.send('turnWheel', 'ALSO-NOT-A-NUMBER');
[1.4.3] - 2018-09-24
FAQs
Allow Ember apps to use TypeScript files.
The npm package ember-cli-typescript receives a total of 419,626 weekly downloads. As such, ember-cli-typescript popularity was classified as popular.
We found that ember-cli-typescript demonstrated a healthy version release cadence and project activity because the last version was released less than a year ago. It has 5 open source maintainers collaborating on the project.
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