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The Ahead-of-Time (AOT) compiler

An Angular application consists mainly of components and their HTML templates. Because the components and templates provided by Angular cannot be understood by the browser directly, Angular applications require a compilation process before they can run in a browser.

The Angular Ahead-of-Time (AOT) compiler converts your Angular HTML and TypeScript code into efficient JavaScript code during the build phase before the browser downloads and runs that code. Compiling your application during the build process provides a faster rendering in the browser.

This guide explains how to specify metadata and apply available compiler options to compile your applications efficiently using the AOT compiler.

Angular compilation

Angular offers two ways to compile your application:

  1. Just-in-Time (JIT), which compiles your app in the browser at runtime.
  2. Ahead-of-Time (AOT), which compiles your app at build time.

JIT compilation is the default when you run the ng build (build only) or ng serve (build and serve locally) CLI commands:

ng build ng serve
      
      ng build
ng serve
    

For AOT compilation, include the --aot option with the ng build or ng serve command:

ng build --aot ng serve --aot
      
      ng build --aot
ng serve --aot
    

The ng build command with the --prod meta-flag (ng build --prod) compiles with AOT by default.

See the CLI command reference and Building and serving Angular apps for more information.

Why compile with AOT?

Faster rendering

With AOT, the browser downloads a pre-compiled version of the application. The browser loads executable code so it can render the application immediately, without waiting to compile the app first.

Fewer asynchronous requests

The compiler inlines external HTML templates and CSS style sheets within the application JavaScript, eliminating separate ajax requests for those source files.

Smaller Angular framework download size

There's no need to download the Angular compiler if the app is already compiled. The compiler is roughly half of Angular itself, so omitting it dramatically reduces the application payload.

Detect template errors earlier

The AOT compiler detects and reports template binding errors during the build step before users can see them.

Better security

AOT compiles HTML templates and components into JavaScript files long before they are served to the client. With no templates to read and no risky client-side HTML or JavaScript evaluation, there are fewer opportunities for injection attacks.

Controlling app compilation

When you use the Angular AOT compiler, you can control your app compilation in two ways:

Specifying Angular metadata

Angular metadata tells Angular how to construct instances of your application classes and interact with them at runtime. The Angular AOT compiler extracts metadata to interpret the parts of the application that Angular is supposed to manage.

You can specify the metadata with decorators such as @Component() and @Input() or implicitly in the constructor declarations of these decorated classes.

In the following example, the @Component() metadata object and the class constructor tell Angular how to create and display an instance of TypicalComponent.

@Component({ selector: 'app-typical', template: '<div>A typical component for {{data.name}}</div>' )} export class TypicalComponent { @Input() data: TypicalData; constructor(private someService: SomeService) { ... } }
      
      @Component({
  selector: 'app-typical',
  template: '<div>A typical component for {{data.name}}</div>'
)}
export class TypicalComponent {
  @Input() data: TypicalData;
  constructor(private someService: SomeService) { ... }
}
    

The Angular compiler extracts the metadata once and generates a factory for TypicalComponent. When it needs to create a TypicalComponent instance, Angular calls the factory, which produces a new visual element, bound to a new instance of the component class with its injected dependency.

Metadata restrictions

You write metadata in a subset of TypeScript that must conform to the following general constraints:

  1. Limit expression syntax to the supported subset of JavaScript.
  2. Only reference exported symbols after code folding.
  3. Only call functions supported by the compiler.
  4. Decorated and data-bound class members must be public.

The next sections elaborate on these points.

How AOT works

It helps to think of the AOT compiler as having two phases: a code analysis phase in which it simply records a representation of the source; and a code generation phase in which the compiler's StaticReflector handles the interpretation as well as places restrictions on what it interprets.

Phase 1: analysis

The TypeScript compiler does some of the analytic work of the first phase. It emits the .d.ts type definition files with type information that the AOT compiler needs to generate application code.

At the same time, the AOT collector analyzes the metadata recorded in the Angular decorators and outputs metadata information in .metadata.json files, one per .d.ts file.

You can think of .metadata.json as a diagram of the overall structure of a decorator's metadata, represented as an abstract syntax tree (AST).

Angular's schema.ts describes the JSON format as a collection of TypeScript interfaces.

Expression syntax

The collector only understands a subset of JavaScript. Define metadata objects with the following limited syntax:

Syntax Example
Literal object {cherry: true, apple: true, mincemeat: false}
Literal array ['cherries', 'flour', 'sugar']
Spread in literal array ['apples', 'flour', ...the_rest]
Calls bake(ingredients)
New new Oven()
Property access pie.slice
Array index ingredients[0]
Identity reference Component
A template string `pie is ${multiplier} times better than cake`
Literal string pi
Literal number 3.14153265
Literal boolean true
Literal null null
Supported prefix operator !cake
Supported binary operator a+b
Conditional operator a ? b : c
Parentheses (a+b)

If an expression uses unsupported syntax, the collector writes an error node to the .metadata.json file. The compiler later reports the error if it needs that piece of metadata to generate the application code.

If you want ngc to report syntax errors immediately rather than produce a .metadata.json file with errors, set the strictMetadataEmit option in tsconfig.

"angularCompilerOptions": { ... "strictMetadataEmit" : true }
      
      "angularCompilerOptions": {
  ...
  "strictMetadataEmit" : true
}
    

Angular libraries have this option to ensure that all Angular .metadata.json files are clean and it is a best practice to do the same when building your own libraries.

No arrow functions

The AOT compiler does not support function expressions and arrow functions, also called lambda functions.

Consider the following component decorator:

@Component({ ... providers: [{provide: server, useFactory: () => new Server()}] })
      
      @Component({
  ...
  providers: [{provide: server, useFactory: () => new Server()}]
})
    

The AOT collector does not support the arrow function, () => new Server(), in a metadata expression. It generates an error node in place of the function.

When the compiler later interprets this node, it reports an error that invites you to turn the arrow function into an exported function.

You can fix the error by converting to this:

export function serverFactory() { return new Server(); } @Component({ ... providers: [{provide: server, useFactory: serverFactory}] })
      
      export function serverFactory() {
  return new Server();
}

@Component({
  ...
  providers: [{provide: server, useFactory: serverFactory}]
})
    

Beginning in version 5, the compiler automatically performs this rewriting while emitting the .js file.

Limited function calls

The collector can represent a function call or object creation with new as long as the syntax is valid. The collector only cares about proper syntax.

But beware. The compiler may later refuse to generate a call to a particular function or creation of a particular object. The compiler only supports calls to a small set of functions and will use new for only a few designated classes. These functions and classes are in a table of below.

Folding

The compiler can only resolve references to exported symbols. Fortunately, the collector enables limited use of non-exported symbols through folding.

The collector may be able to evaluate an expression during collection and record the result in the .metadata.json instead of the original expression.

For example, the collector can evaluate the expression 1 + 2 + 3 + 4 and replace it with the result, 10.

This process is called folding. An expression that can be reduced in this manner is foldable.

The collector can evaluate references to module-local const declarations and initialized var and let declarations, effectively removing them from the .metadata.json file.

Consider the following component definition:

const template = '<div>{{hero.name}}</div>'; @Component({ selector: 'app-hero', template: template }) export class HeroComponent { @Input() hero: Hero; }
      
      const template = '<div>{{hero.name}}</div>';

@Component({
  selector: 'app-hero',
  template: template
})
export class HeroComponent {
  @Input() hero: Hero;
}
    

The compiler could not refer to the template constant because it isn't exported.

But the collector can fold the template constant into the metadata definition by inlining its contents. The effect is the same as if you had written:

@Component({ selector: 'app-hero', template: '<div>{{hero.name}}</div>' }) export class HeroComponent { @Input() hero: Hero; }
      
      @Component({
  selector: 'app-hero',
  template: '<div>{{hero.name}}</div>'
})
export class HeroComponent {
  @Input() hero: Hero;
}
    

There is no longer a reference to template and, therefore, nothing to trouble the compiler when it later interprets the collector's output in .metadata.json.

You can take this example a step further by including the template constant in another expression:

const template = '<div>{{hero.name}}</div>'; @Component({ selector: 'app-hero', template: template + '<div>{{hero.title}}</div>' }) export class HeroComponent { @Input() hero: Hero; }
      
      const template = '<div>{{hero.name}}</div>';

@Component({
  selector: 'app-hero',
  template: template + '<div>{{hero.title}}</div>'
})
export class HeroComponent {
  @Input() hero: Hero;
}
    

The collector reduces this expression to its equivalent folded string:

'<div>{{hero.name}}</div><div>{{hero.title}}</div>'.

Foldable syntax

The following table describes which expressions the collector can and cannot fold:

Syntax Foldable
Literal object Yes
Literal array Yes
Spread in literal array no
Calls no
New no
Property access yes, if target is foldable
Array index yes, if target and index are foldable
Identity reference yes, if it is a reference to a local
A template with no substitutions yes
A template with substitutions yes, if the substitutions are foldable
Literal string yes
Literal number yes
Literal boolean yes
Literal null yes
Supported prefix operator yes, if operand is foldable
Supported binary operator yes, if both left and right are foldable
Conditional operator yes, if condition is foldable
Parentheses yes, if the expression is foldable

If an expression is not foldable, the collector writes it to .metadata.json as an AST for the compiler to resolve.

Phase 2: code generation

The collector makes no attempt to understand the metadata that it collects and outputs to .metadata.json. It represents the metadata as best it can and records errors when it detects a metadata syntax violation.

It's the compiler's job to interpret the .metadata.json in the code generation phase.

The compiler understands all syntax forms that the collector supports, but it may reject syntactically correct metadata if the semantics violate compiler rules.

The compiler can only reference exported symbols.

Decorated component class members must be public. You cannot make an @Input() property private or protected.

Data bound properties must also be public.

// BAD CODE - title is private @Component({ selector: 'app-root', template: '<h1>{{title}}</h1>' }) export class AppComponent { private title = 'My App'; // Bad }
      
      // BAD CODE - title is private
@Component({
  selector: 'app-root',
  template: '<h1>{{title}}</h1>'
})
export class AppComponent {
  private title = 'My App'; // Bad
}
    

Most importantly, the compiler only generates code to create instances of certain classes, support certain decorators, and call certain functions from the following lists.

New instances

The compiler only allows metadata that create instances of the class InjectionToken from @angular/core.

Annotations/Decorators

The compiler only supports metadata for these Angular decorators.

Decorator Module
Attribute @angular/core
Component @angular/core
ContentChild @angular/core
ContentChildren @angular/core
Directive @angular/core
Host @angular/core
HostBinding @angular/core
HostListner @angular/core
Inject @angular/core
Injectable @angular/core
Input @angular/core
NgModule @angular/core
Optional @angular/core
Output @angular/core
Pipe @angular/core
Self @angular/core
SkipSelf @angular/core
ViewChild @angular/core

Macro-functions and macro-static methods

The compiler also supports macros in the form of functions or static methods that return an expression.

For example, consider the following function:

export function wrapInArray<T>(value: T): T[] { return [value]; }
      
      export function wrapInArray<T>(value: T): T[] {
  return [value];
}
    

You can call the wrapInArray in a metadata definition because it returns the value of an expression that conforms to the compiler's restrictive JavaScript subset.

You might use wrapInArray() like this:

@NgModule({ declarations: wrapInArray(TypicalComponent) }) export class TypicalModule {}
      
      @NgModule({
  declarations: wrapInArray(TypicalComponent)
})
export class TypicalModule {}
    

The compiler treats this usage as if you had written:

@NgModule({ declarations: [TypicalComponent] }) export class TypicalModule {}
      
      @NgModule({
  declarations: [TypicalComponent]
})
export class TypicalModule {}
    

The collector is simplistic in its determination of what qualifies as a macro function; it can only contain a single return statement.

The Angular RouterModule exports two macro static methods, forRoot and forChild, to help declare root and child routes. Review the source code for these methods to see how macros can simplify configuration of complex NgModules.

Metadata rewriting

The compiler treats object literals containing the fields useClass, useValue, useFactory, and data specially. The compiler converts the expression initializing one of these fields into an exported variable, which replaces the expression. This process of rewriting these expressions removes all the restrictions on what can be in them because the compiler doesn't need to know the expression's value—it just needs to be able to generate a reference to the value.

You might write something like:

class TypicalServer { } @NgModule({ providers: [{provide: SERVER, useFactory: () => TypicalServer}] }) export class TypicalModule {}
      
      class TypicalServer {

}

@NgModule({
  providers: [{provide: SERVER, useFactory: () => TypicalServer}]
})
export class TypicalModule {}
    

Without rewriting, this would be invalid because lambdas are not supported and TypicalServer is not exported.

To allow this, the compiler automatically rewrites this to something like:

class TypicalServer { } export const ɵ0 = () => new TypicalServer(); @NgModule({ providers: [{provide: SERVER, useFactory: ɵ0}] }) export class TypicalModule {}
      
      class TypicalServer {

}

export const ɵ0 = () => new TypicalServer();

@NgModule({
  providers: [{provide: SERVER, useFactory: ɵ0}]
})
export class TypicalModule {}
    

This allows the compiler to generate a reference to ɵ0 in the factory without having to know what the value of ɵ0 contains.

The compiler does the rewriting during the emit of the .js file. This doesn't rewrite the .d.ts file, however, so TypeScript doesn't recognize it as being an export. Thus, it does not pollute the ES module's exported API.

Metadata errors

The following are metadata errors you may encounter, with explanations and suggested corrections.

Expression form not supported
Reference to a local (non-exported) symbol
Only initialized variables and constants
Reference to a non-exported class
Reference to a non-exported function
Function calls are not supported
Destructured variable or constant not supported
Could not resolve type
Name expected
Unsupported enum member name
Tagged template expressions are not supported
Symbol reference expected


Expression form not supported

The compiler encountered an expression it didn't understand while evaluating Angular metadata.

Language features outside of the compiler's restricted expression syntax can produce this error, as seen in the following example:

// ERROR export class Fooish { ... } ... const prop = typeof Fooish; // typeof is not valid in metadata ... // bracket notation is not valid in metadata { provide: 'token', useValue: { [prop]: 'value' } }; ...
      
      // ERROR
export class Fooish { ... }
...
const prop = typeof Fooish; // typeof is not valid in metadata
  ...
  // bracket notation is not valid in metadata
  { provide: 'token', useValue: { [prop]: 'value' } };
  ...
    

You can use typeof and bracket notation in normal application code. You just can't use those features within expressions that define Angular metadata.

Avoid this error by sticking to the compiler's restricted expression syntax when writing Angular metadata and be wary of new or unusual TypeScript features.


Reference to a local (non-exported) symbol

Reference to a local (non-exported) symbol 'symbol name'. Consider exporting the symbol.

The compiler encountered a referenced to a locally defined symbol that either wasn't exported or wasn't initialized.

Here's a provider example of the problem.

// ERROR let foo: number; // neither exported nor initialized @Component({ selector: 'my-component', template: ... , providers: [ { provide: Foo, useValue: foo } ] }) export class MyComponent {}
      
      // ERROR
let foo: number; // neither exported nor initialized

@Component({
  selector: 'my-component',
  template: ... ,
  providers: [
    { provide: Foo, useValue: foo }
  ]
})
export class MyComponent {}
    

The compiler generates the component factory, which includes the useValue provider code, in a separate module. That factory module can't reach back to this source module to access the local (non-exported) foo variable.

You could fix the problem by initializing foo.

let foo = 42; // initialized
      
      let foo = 42; // initialized
    

The compiler will fold the expression into the provider as if you had written this.

providers: [ { provide: Foo, useValue: 42 } ]
      
      providers: [
  { provide: Foo, useValue: 42 }
]
    

Alternatively, you can fix it by exporting foo with the expectation that foo will be assigned at runtime when you actually know its value.

// CORRECTED export let foo: number; // exported @Component({ selector: 'my-component', template: ... , providers: [ { provide: Foo, useValue: foo } ] }) export class MyComponent {}
      
      // CORRECTED
export let foo: number; // exported

@Component({
  selector: 'my-component',
  template: ... ,
  providers: [
    { provide: Foo, useValue: foo }
  ]
})
export class MyComponent {}
    

Adding export often works for variables referenced in metadata such as providers and animations because the compiler can generate references to the exported variables in these expressions. It doesn't need the values of those variables.

Adding export doesn't work when the compiler needs the actual value in order to generate code. For example, it doesn't work for the template property.

// ERROR export let someTemplate: string; // exported but not initialized @Component({ selector: 'my-component', template: someTemplate }) export class MyComponent {}
      
      // ERROR
export let someTemplate: string; // exported but not initialized

@Component({
  selector: 'my-component',
  template: someTemplate
})
export class MyComponent {}
    

The compiler needs the value of the template property right now to generate the component factory. The variable reference alone is insufficient. Prefixing the declaration with export merely produces a new error, "Only initialized variables and constants can be referenced".


Only initialized variables and constants

Only initialized variables and constants can be referenced because the value of this variable is needed by the template compiler.

The compiler found a reference to an exported variable or static field that wasn't initialized. It needs the value of that variable to generate code.

The following example tries to set the component's template property to the value of the exported someTemplate variable which is declared but unassigned.

// ERROR export let someTemplate: string; @Component({ selector: 'my-component', template: someTemplate }) export class MyComponent {}
      
      // ERROR
export let someTemplate: string;

@Component({
  selector: 'my-component',
  template: someTemplate
})
export class MyComponent {}
    

You'd also get this error if you imported someTemplate from some other module and neglected to initialize it there.

// ERROR - not initialized there either import { someTemplate } from './config'; @Component({ selector: 'my-component', template: someTemplate }) export class MyComponent {}
      
      // ERROR - not initialized there either
import { someTemplate } from './config';

@Component({
  selector: 'my-component',
  template: someTemplate
})
export class MyComponent {}
    

The compiler cannot wait until runtime to get the template information. It must statically derive the value of the someTemplate variable from the source code so that it can generate the component factory, which includes instructions for building the element based on the template.

To correct this error, provide the initial value of the variable in an initializer clause on the same line.

// CORRECTED export let someTemplate = '<h1>Greetings from Angular</h1>'; @Component({ selector: 'my-component', template: someTemplate }) export class MyComponent {}
      
      // CORRECTED
export let someTemplate = '<h1>Greetings from Angular</h1>';

@Component({
  selector: 'my-component',
  template: someTemplate
})
export class MyComponent {}
    

Reference to a non-exported class

Reference to a non-exported class . Consider exporting the class.

Metadata referenced a class that wasn't exported.

For example, you may have defined a class and used it as an injection token in a providers array but neglected to export that class.

// ERROR abstract class MyStrategy { } ... providers: [ { provide: MyStrategy, useValue: ... } ] ...
      
      // ERROR
abstract class MyStrategy { }

  ...
  providers: [
    { provide: MyStrategy, useValue: ... }
  ]
  ...
    

Angular generates a class factory in a separate module and that factory can only access exported classes. To correct this error, export the referenced class.

// CORRECTED export abstract class MyStrategy { } ... providers: [ { provide: MyStrategy, useValue: ... } ] ...
      
      // CORRECTED
export abstract class MyStrategy { }

  ...
  providers: [
    { provide: MyStrategy, useValue: ... }
  ]
  ...
    

Reference to a non-exported function

Metadata referenced a function that wasn't exported.

For example, you may have set a providers useFactory property to a locally defined function that you neglected to export.

// ERROR function myStrategy() { ... } ... providers: [ { provide: MyStrategy, useFactory: myStrategy } ] ...
      
      // ERROR
function myStrategy() { ... }

  ...
  providers: [
    { provide: MyStrategy, useFactory: myStrategy }
  ]
  ...
    

Angular generates a class factory in a separate module and that factory can only access exported functions. To correct this error, export the function.

// CORRECTED export function myStrategy() { ... } ... providers: [ { provide: MyStrategy, useFactory: myStrategy } ] ...
      
      // CORRECTED
export function myStrategy() { ... }

  ...
  providers: [
    { provide: MyStrategy, useFactory: myStrategy }
  ]
  ...
    

Function calls are not supported

Function calls are not supported. Consider replacing the function or lambda with a reference to an exported function.

The compiler does not currently support function expressions or lambda functions. For example, you cannot set a provider's useFactory to an anonymous function or arrow function like this.

// ERROR ... providers: [ { provide: MyStrategy, useFactory: function() { ... } }, { provide: OtherStrategy, useFactory: () => { ... } } ] ...
      
      // ERROR
  ...
  providers: [
    { provide: MyStrategy, useFactory: function() { ... } },
    { provide: OtherStrategy, useFactory: () => { ... } }
  ]
  ...
    

You also get this error if you call a function or method in a provider's useValue.

// ERROR import { calculateValue } from './utilities'; ... providers: [ { provide: SomeValue, useValue: calculateValue() } ] ...
      
      // ERROR
import { calculateValue } from './utilities';

  ...
  providers: [
    { provide: SomeValue, useValue: calculateValue() }
  ]
  ...
    

To correct this error, export a function from the module and refer to the function in a useFactory provider instead.

// CORRECTED import { calculateValue } from './utilities'; export function myStrategy() { ... } export function otherStrategy() { ... } export function someValueFactory() { return calculateValue(); } ... providers: [ { provide: MyStrategy, useFactory: myStrategy }, { provide: OtherStrategy, useFactory: otherStrategy }, { provide: SomeValue, useFactory: someValueFactory } ] ...
      
      // CORRECTED
import { calculateValue } from './utilities';

export function myStrategy() { ... }
export function otherStrategy() { ... }
export function someValueFactory() {
  return calculateValue();
}
  ...
  providers: [
    { provide: MyStrategy, useFactory: myStrategy },
    { provide: OtherStrategy, useFactory: otherStrategy },
    { provide: SomeValue, useFactory: someValueFactory }
  ]
  ...
    

Destructured variable or constant not supported

Referencing an exported destructured variable or constant is not supported by the template compiler. Consider simplifying this to avoid destructuring.

The compiler does not support references to variables assigned by destructuring.

For example, you cannot write something like this:

// ERROR import { configuration } from './configuration'; // destructured assignment to foo and bar const {foo, bar} = configuration; ... providers: [ {provide: Foo, useValue: foo}, {provide: Bar, useValue: bar}, ] ...
      
      // ERROR
import { configuration } from './configuration';

// destructured assignment to foo and bar
const {foo, bar} = configuration;
  ...
  providers: [
    {provide: Foo, useValue: foo},
    {provide: Bar, useValue: bar},
  ]
  ...
    

To correct this error, refer to non-destructured values.

// CORRECTED import { configuration } from './configuration'; ... providers: [ {provide: Foo, useValue: configuration.foo}, {provide: Bar, useValue: configuration.bar}, ] ...
      
      // CORRECTED
import { configuration } from './configuration';
  ...
  providers: [
    {provide: Foo, useValue: configuration.foo},
    {provide: Bar, useValue: configuration.bar},
  ]
  ...
    

Could not resolve type

The compiler encountered a type and can't determine which module exports that type.

This can happen if you refer to an ambient type. For example, the Window type is an ambient type declared in the global .d.ts file.

You'll get an error if you reference it in the component constructor, which the compiler must statically analyze.

// ERROR @Component({ }) export class MyComponent { constructor (private win: Window) { ... } }
      
      // ERROR
@Component({ })
export class MyComponent {
  constructor (private win: Window) { ... }
}
    

TypeScript understands ambient types so you don't import them. The Angular compiler does not understand a type that you neglect to export or import.

In this case, the compiler doesn't understand how to inject something with the Window token.

Do not refer to ambient types in metadata expressions.

If you must inject an instance of an ambient type, you can finesse the problem in four steps:

  1. Create an injection token for an instance of the ambient type.
  2. Create a factory function that returns that instance.
  3. Add a useFactory provider with that factory function.
  4. Use @Inject to inject the instance.

Here's an illustrative example.

// CORRECTED import { Inject } from '@angular/core'; export const WINDOW = new InjectionToken('Window'); export function _window() { return window; } @Component({ ... providers: [ { provide: WINDOW, useFactory: _window } ] }) export class MyComponent { constructor (@Inject(WINDOW) private win: Window) { ... } }
      
      // CORRECTED
import { Inject } from '@angular/core';

export const WINDOW = new InjectionToken('Window');
export function _window() { return window; }

@Component({
  ...
  providers: [
    { provide: WINDOW, useFactory: _window }
  ]
})
export class MyComponent {
  constructor (@Inject(WINDOW) private win: Window) { ... }
}
    

The Window type in the constructor is no longer a problem for the compiler because it uses the @Inject(WINDOW) to generate the injection code.

Angular does something similar with the DOCUMENT token so you can inject the browser's document object (or an abstraction of it, depending upon the platform in which the application runs).

import { Inject } from '@angular/core'; import { DOCUMENT } from '@angular/platform-browser'; @Component({ ... }) export class MyComponent { constructor (@Inject(DOCUMENT) private doc: Document) { ... } }
      
      import { Inject }   from '@angular/core';
import { DOCUMENT } from '@angular/platform-browser';

@Component({ ... })
export class MyComponent {
  constructor (@Inject(DOCUMENT) private doc: Document) { ... }
}
    

Name expected

The compiler expected a name in an expression it was evaluating. This can happen if you use a number as a property name as in the following example.

// ERROR provider: [{ provide: Foo, useValue: { 0: 'test' } }]
      
      // ERROR
provider: [{ provide: Foo, useValue: { 0: 'test' } }]
    

Change the name of the property to something non-numeric.

// CORRECTED provider: [{ provide: Foo, useValue: { '0': 'test' } }]
      
      // CORRECTED
provider: [{ provide: Foo, useValue: { '0': 'test' } }]
    

Unsupported enum member name

Angular couldn't determine the value of the enum member that you referenced in metadata.

The compiler can understand simple enum values but not complex values such as those derived from computed properties.

// ERROR enum Colors { Red = 1, White, Blue = "Blue".length // computed } ... providers: [ { provide: BaseColor, useValue: Colors.White } // ok { provide: DangerColor, useValue: Colors.Red } // ok { provide: StrongColor, useValue: Colors.Blue } // bad ] ...
      
      // ERROR
enum Colors {
  Red = 1,
  White,
  Blue = "Blue".length // computed
}

  ...
  providers: [
    { provide: BaseColor,   useValue: Colors.White } // ok
    { provide: DangerColor, useValue: Colors.Red }   // ok
    { provide: StrongColor, useValue: Colors.Blue }  // bad
  ]
  ...
    

Avoid referring to enums with complicated initializers or computed properties.


Tagged template expressions are not supported

Tagged template expressions are not supported in metadata.

The compiler encountered a JavaScript ES2015 tagged template expression such as,

// ERROR const expression = 'funky'; const raw = String.raw`A tagged template ${expression} string`; ... template: '<div>' + raw + '</div>' ...
      
      // ERROR
const expression = 'funky';
const raw = String.raw`A tagged template ${expression} string`;
 ...
 template: '<div>' + raw + '</div>'
 ...
    

String.raw() is a tag function native to JavaScript ES2015.

The AOT compiler does not support tagged template expressions; avoid them in metadata expressions.


Symbol reference expected

The compiler expected a reference to a symbol at the location specified in the error message.

This error can occur if you use an expression in the extends clause of a class.

Phase 3: binding expression validation

In the validation phase, the Angular template compiler uses the TypeScript compiler to validate the binding expressions in templates. Enable this phase explicitly by adding the compiler option "fullTemplateTypeCheck" in the "angularCompilerOptions" of the project's tsconfig.json (see Angular Compiler Options).

Template validation produces error messages when a type error is detected in a template binding expression, similar to how type errors are reported by the TypeScript compiler against code in a .ts file.

For example, consider the following component:

@Component({ selector: 'my-component', template: '{{person.addresss.street}}' }) class MyComponent { person?: Person; }
      
      @Component({
  selector: 'my-component',
  template: '{{person.addresss.street}}'
})
class MyComponent {
  person?: Person;
}
    

This will produce the following error:

my.component.ts.MyComponent.html(1,1): : Property 'addresss' does not exist on type 'Person'. Did you mean 'address'?
      
      my.component.ts.MyComponent.html(1,1): : Property 'addresss' does not exist on type 'Person'. Did you mean 'address'?
    

The file name reported in the error message, my.component.ts.MyComponent.html, is a synthetic file generated by the template compiler that holds contents of the MyComponent class template. Compiler never writes this file to disk. The line and column numbers are relative to the template string in the @Component annotation of the class, MyComponent in this case. If a component uses templateUrl instead of template, the errors are reported in the HTML file referenced by the templateUrl instead of a synthetic file.

The error location is the beginning of the text node that contains the interpolation expression with the error. If the error is in an attribute binding such as [value]="person.address.street", the error location is the location of the attribute that contains the error.

The validation uses the TypeScript type checker and the options supplied to the TypeScript compiler to control how detailed the type validation is. For example, if the strictTypeChecks is specified, the error my.component.ts.MyComponent.html(1,1): : Object is possibly 'undefined' is reported as well as the above error message.

Type narrowing

The expression used in an ngIf directive is used to narrow type unions in the Angular template compiler, the same way the if expression does in TypeScript. For example, to avoid Object is possibly 'undefined' error in the template above, modify it to only emit the interpolation if the value of person is initialized as shown below:

@Component({ selector: 'my-component', template: '<span *ngIf="person"> {{person.addresss.street}} </span>' }) class MyComponent { person?: Person; }
      
      @Component({
  selector: 'my-component',
  template: '<span *ngIf="person"> {{person.addresss.street}} </span>'
})
class MyComponent {
  person?: Person;
}
    

Using *ngIf allows the TypeScript compiler to infer that the person used in the binding expression will never be undefined.

Custom ngIf like directives

Directives that behave like *ngIf can declare that they want the same treatment by including a static member marker that is a signal to the template compiler to treat them like *ngIf. This static member for *ngIf is:

public static ngIfUseIfTypeGuard: void;
      
      public static ngIfUseIfTypeGuard: void;
    

This declares that the input property ngIf of the NgIf directive should be treated as a guard to the use of its template, implying that the template will only be instantiated if the ngIf input property is true.

Non-null type assertion operator

Use the non-null type assertion operator to suppress the Object is possibly 'undefined' error when it is inconvenient to use *ngIf or when some constraint in the component ensures that the expression is always non-null when the binding expression is interpolated.

In the following example, the person and address properties are always set together, implying that address is always non-null if person is non-null. There is no convenient way to describe this constraint to TypeScript and the template compiler, but the error is suppressed in the example by using address!.street.

@Component({ selector: 'my-component', template: '<span *ngIf="person"> {{person.name}} lives on {{address!.street}} </span>' }) class MyComponent { person?: Person; address?: Address; setData(person: Person, address: Address) { this.person = person; this.address = address; } }
      
      
  1. @Component({
  2. selector: 'my-component',
  3. template: '<span *ngIf="person"> {{person.name}} lives on {{address!.street}} </span>'
  4. })
  5. class MyComponent {
  6. person?: Person;
  7. address?: Address;
  8.  
  9. setData(person: Person, address: Address) {
  10. this.person = person;
  11. this.address = address;
  12. }
  13. }

The non-null assertion operator should be used sparingly as refactoring of the component might break this constraint.

In this example it is recommended to include the checking of address in the *ngIfas shown below:

@Component({ selector: 'my-component', template: '<span *ngIf="person && address"> {{person.name}} lives on {{address.street}} </span>' }) class MyComponent { person?: Person; address?: Address; setData(person: Person, address: Address) { this.person = person; this.address = address; } }
      
      
  1. @Component({
  2. selector: 'my-component',
  3. template: '<span *ngIf="person && address"> {{person.name}} lives on {{address.street}} </span>'
  4. })
  5. class MyComponent {
  6. person?: Person;
  7. address?: Address;
  8.  
  9. setData(person: Person, address: Address) {
  10. this.person = person;
  11. this.address = address;
  12. }
  13. }

Disabling type checking using $any()

Disable checking of a binding expression by surrounding the expression in a call to the $any() cast pseudo-function. The compiler treats it as a cast to the any type just like in TypeScript when a <any> or as any cast is used.

In the following example, the error Property addresss does not exist is suppressed by casting person to the any type.

@Component({ selector: 'my-component', template: '{{$any(person).addresss.street}}' }) class MyComponent { person?: Person; }
      
      @Component({
  selector: 'my-component',
  template: '{{$any(person).addresss.street}}'
})
class MyComponent {
  person?: Person;
}
    

Configuration inheritance with extends

Similar to TypeScript Compiler, Angular Compiler also supports extends in the tsconfig.json on angularCompilerOptions. A tsconfig file can inherit configurations from another file using the extends property. The extends is a top level property parallel to compilerOptions and angularCompilerOptions. The configuration from the base file are loaded first, then overridden by those in the inheriting config file. Example:

{ "extends": "../tsconfig.base.json", "compilerOptions": { "experimentalDecorators": true, ... }, "angularCompilerOptions": { "fullTemplateTypeCheck": true, "preserveWhitespaces": true, ... } }
      
      
  1. {
  2. "extends": "../tsconfig.base.json",
  3. "compilerOptions": {
  4. "experimentalDecorators": true,
  5. ...
  6. },
  7. "angularCompilerOptions": {
  8. "fullTemplateTypeCheck": true,
  9. "preserveWhitespaces": true,
  10. ...
  11. }
  12. }

More information about tsconfig extends can be found in the TypeScript Handbook.

Angular template compiler options

The template compiler options are specified as members of the "angularCompilerOptions" object in the tsconfig.json file. Specify template compiler options along with the options supplied to the TypeScript compiler as shown here:

{ "compilerOptions": { "experimentalDecorators": true, ... }, "angularCompilerOptions": { "fullTemplateTypeCheck": true, "preserveWhitespaces": true, ... } }
      
      {
  "compilerOptions": {
    "experimentalDecorators": true,
              ...
  },
  "angularCompilerOptions": {
    "fullTemplateTypeCheck": true,
    "preserveWhitespaces": true,
              ...
  }
}
    

The following section describes the Angular's template compiler options.

enableResourceInlining

This option instructs the compiler to replace the templateUrl and styleUrls property in all @Component decorators with inlined contents in template and styles properties. When enabled, the .js output of ngc will have no lazy-loaded templateUrl or styleUrls.

skipMetadataEmit

This option tells the compiler not to produce .metadata.json files. The option is false by default.

.metadata.json files contain information needed by the template compiler from a .ts file that is not included in the .d.ts file produced by the TypeScript compiler. This information contains, for example, the content of annotations (such as a component's template), which TypeScript emits to the .js file but not to the .d.ts file.

This option should be set to true if you are using TypeScript's --outFile option, because the metadata files are not valid for this style of TypeScript output. It is not recommended to use --outFile with Angular. Use a bundler, such as webpack, instead.

This option can also be set to true when using factory summaries because the factory summaries include a copy of the information that is in the .metadata.json file.

strictMetadataEmit

This option tells the template compiler to report an error to the .metadata.json file if "skipMetadataEmit" is false. This option is false by default. This should only be used when "skipMetadataEmit" is false and "skipTemplateCodeGen" is true.

This option is intended to validate the .metadata.json files emitted for bundling with an npm package. The validation is strict and can emit errors for metadata that would never produce an error when used by the template compiler. You can choose to suppress the error emitted by this option for an exported symbol by including @dynamic in the comment documenting the symbol.

It is valid for .metadata.json files to contain errors. The template compiler reports these errors if the metadata is used to determine the contents of an annotation. The metadata collector cannot predict the symbols that are designed for use in an annotation, so it will preemptively include error nodes in the metadata for the exported symbols. The template compiler can then use the error nodes to report an error if these symbols are used. If the client of a library intends to use a symbol in an annotation, the template compiler will not normally report this until the client uses the symbol. This option allows detecting these errors during the build phase of the library and is used, for example, in producing Angular libraries themselves.

skipTemplateCodegen

This option tells the compiler to suppress emitting .ngfactory.js and .ngstyle.js files. When set, this turns off most of the template compiler and disables reporting template diagnostics. This option can be used to instruct the template compiler to produce .metadata.json files for distribution with an npm package while avoiding the production of .ngfactory.js and .ngstyle.js files that cannot be distributed to npm.

strictInjectionParameters

When set to true, this options tells the compiler to report an error for a parameter supplied whose injection type cannot be determined. When this option is not provided or is false, constructor parameters of classes marked with @Injectable whose type cannot be resolved will produce a warning.

Note: It is recommended to change this option explicitly to true as this option will default to true in the future.

flatModuleOutFile

When set to true, this option tells the template compiler to generate a flat module index of the given file name and the corresponding flat module metadata. Use this option when creating flat modules that are packaged similarly to @angular/core and @angular/common. When this option is used, the package.json for the library should refer to the generated flat module index instead of the library index file. With this option only one .metadata.json file is produced, which contains all the metadata necessary for symbols exported from the library index. In the generated .ngfactory.js files, the flat module index is used to import symbols that includes both the public API from the library index as well as shrowded internal symbols.

By default the .ts file supplied in the files field is assumed to be the library index. If more than one .ts file is specified, libraryIndex is used to select the file to use. If more than one .ts file is supplied without a libraryIndex, an error is produced. A flat module index .d.ts and .js will be created with the given flatModuleOutFile name in the same location as the library index .d.ts file. For example, if a library uses the public_api.ts file as the library index of the module, the tsconfig.json files field would be ["public_api.ts"]. The flatModuleOutFile options could then be set to, for example "index.js", which produces index.d.ts and index.metadata.json files. The library's package.json's module field would be "index.js" and the typings field would be "index.d.ts".

flatModuleId

This option specifies the preferred module id to use for importing a flat module. References generated by the template compiler will use this module name when importing symbols from the flat module. This is only meaningful when flatModuleOutFile is also supplied. Otherwise the compiler ignores this option.

generateCodeForLibraries

This option tells the template compiler to generate factory files (.ngfactory.js and .ngstyle.js) for .d.ts files with a corresponding .metadata.json file. This option defaults to true. When this option is false, factory files are generated only for .ts files.

This option should be set to false when using factory summaries.

fullTemplateTypeCheck

This option tells the compiler to enable the binding expression validation phase of the template compiler which uses TypeScript to validate binding expressions.

This option is false by default.

Note: It is recommended to set this to true because this option will default to true in the future.

annotateForClosureCompiler

This option tells the compiler to use Tsickle to annotate the emitted JavaScript with JSDoc comments needed by the Closure Compiler. This option defaults to false.

annotationsAs

Use this option to modify how the Angular specific annotations are emitted to improve tree-shaking. Non-Angular annotations and decorators are unaffected. Default is static fields.

Value Description
decorators Leave the decorators in place. This makes compilation faster. TypeScript will emit calls to the __decorate helper. Use --emitDecoratorMetadata for runtime reflection. However, the resulting code will not properly tree-shake.
static fields Replace decorators with a static field in the class. Allows advanced tree-shakers like Closure compiler to remove unused classes.

trace

This tells the compiler to print extra information while compiling templates.

enableLegacyTemplate

Use of the <template> element was deprecated starting in Angular 4.0 in favor of using <ng-template> to avoid colliding with the DOM's element of the same name. Setting this option to true enables the use of the deprecated <template> element. This option is false by default. This option might be required by some third-party Angular libraries.

disableExpressionLowering

The Angular template compiler transforms code that is used, or could be used, in an annotation to allow it to be imported from template factory modules. See metadata rewriting for more information.

Setting this option to false disables this rewriting, requiring the rewriting to be done manually.

disableTypeScriptVersionCheck

When true, this option tells the compiler not to check the TypeScript version. The compiler will skip checking and will not error out when an unsupported version of TypeScript is used. Setting this option to true is not recommended because unsupported versions of TypeScript might have undefined behavior.

This option is false by default.

preserveWhitespaces

This option tells the compiler whether to remove blank text nodes from compiled templates. As of v6, this option is false by default, which results in smaller emitted template factory modules.

allowEmptyCodegenFiles

Tells the compiler to generate all the possible generated files even if they are empty. This option is false by default. This is an option used by the Bazel build rules and is needed to simplify how Bazel rules track file dependencies. It is not recommended to use this option outside of the Bazel rules.