You can improve overall data quality by validating user input for accuracy and completeness. This page shows how to validate user input from the UI and display useful validation messages, in both reactive and template-driven forms.
Prerequisites
Before reading about form validation, you should have a basic understanding of the following.
TypeScript and HTML5 programming.
Fundamental concepts of Angular application design.
Basics of either Template-driven Forms or Reactive Forms.
Get the complete example code for the reactive and template-driven forms used here to illustrate form validation. Run the live example.
To add validation to a template-driven form, you add the same validation attributes as you would with native HTML form validation. Angular uses directives to match these attributes with validator functions in the framework.
Every time the value of a form control changes, Angular runs validation and generates either a list of validation errors that results in an INVALID status, or null, which results in a VALID status.
You can then inspect the control's state by exporting ngModel
to a local template variable. The following example exports NgModel
into a variable called name
:
<input type="text" id="name" name="name" class="form-control" required minlength="4" appForbiddenName="bob" [(ngModel)]="hero.name" #name="ngModel"> <div *ngIf="name.invalid && (name.dirty || name.touched)" class="alert"> <div *ngIf="name.errors?.required"> Name is required. </div> <div *ngIf="name.errors?.minlength"> Name must be at least 4 characters long. </div> <div *ngIf="name.errors?.forbiddenName"> Name cannot be Bob. </div> </div>
Notice the following features illustrated by the example.
The <input>
element carries the HTML validation attributes: required
and minlength
. It also carries a custom validator directive, forbiddenName
. For more information, see the Custom validators section.
#name="ngModel"
exports NgModel
into a local variable called name
. NgModel
mirrors many of the properties of its underlying FormControl
instance, so you can use this in the template to check for control states such as valid
and dirty
. For a full list of control properties, see the AbstractControl API reference.
To prevent the validator from displaying errors before the user has a chance to edit the form, you should check for either the
dirty
ortouched
states in a control.
- When the user changes the value in the watched field, the control is marked as "dirty".
- When the user blurs the form control element, the control is marked as "touched".
In a reactive form, the source of truth is the component class. Instead of adding validators through attributes in the template, you add validator functions directly to the form control model in the component class. Angular then calls these functions whenever the value of the control changes.
Validator functions can be either synchronous or asynchronous.
Sync validators: Synchronous functions that take a control instance and immediately return either a set of validation errors or null
. Pass these in as the second argument when you instantiate a FormControl
.
Async validators: Asynchronous functions that take a control instance and return a Promise or Observable that later emits a set of validation errors or null
. Pass these in as the third argument when you instantiate a FormControl
.
For performance reasons, Angular only runs async validators if all sync validators pass. Each must complete before errors are set.
You can choose to write your own validator functions, or you can use some of Angular's built-in validators.
The same built-in validators that are available as attributes in template-driven forms, such as required
and minlength
, are all available to use as functions from the Validators
class. For a full list of built-in validators, see the Validators API reference.
To update the hero form to be a reactive form, use some of the same built-in validators—this time, in function form, as in the following example.
ngOnInit(): void { this.heroForm = new FormGroup({ name: new FormControl(this.hero.name, [ Validators.required, Validators.minLength(4), forbiddenNameValidator(/bob/i) // <-- Here's how you pass in the custom validator. ]), alterEgo: new FormControl(this.hero.alterEgo), power: new FormControl(this.hero.power, Validators.required) }); } get name() { return this.heroForm.get('name'); } get power() { return this.heroForm.get('power'); }
In this example, the name
control sets up two built-in validators—Validators.required
and Validators.minLength(4)
—and one custom validator, forbiddenNameValidator
. (For more details see custom validators.)
All of these validators are synchronous, so they are passed as the second argument. Notice that you can support multiple validators by passing the functions in as an array.
This example also adds a few getter methods. In a reactive form, you can always access any form control through the get
method on its parent group, but sometimes it's useful to define getters as shorthand for the template.
If you look at the template for the name
input again, it is fairly similar to the template-driven example.
<input type="text" id="name" class="form-control" formControlName="name" required> <div *ngIf="name.invalid && (name.dirty || name.touched)" class="alert alert-danger"> <div *ngIf="name.errors?.required"> Name is required. </div> <div *ngIf="name.errors?.minlength"> Name must be at least 4 characters long. </div> <div *ngIf="name.errors?.forbiddenName"> Name cannot be Bob. </div> </div>
This form differs from the template-driven version in that it no longer exports any directives. Instead, it uses the name
getter defined in the component class.
Notice that the required
attribute is still present in the template. Although it's not necessary for validation, it should be retained to for accessibility purposes.
The built-in validators don't always match the exact use case of your application, so you sometimes need to create a custom validator.
Consider the forbiddenNameValidator
function from previous reactive-form examples. Here's what the definition of that function looks like.
/** A hero's name can't match the given regular expression */ export function forbiddenNameValidator(nameRe: RegExp): ValidatorFn { return (control: AbstractControl): ValidationErrors | null => { const forbidden = nameRe.test(control.value); return forbidden ? {forbiddenName: {value: control.value}} : null; }; }
The function is a factory that takes a regular expression to detect a specific forbidden name and returns a validator function.
In this sample, the forbidden name is "bob", so the validator rejects any hero name containing "bob". Elsewhere it could reject "alice" or any name that the configuring regular expression matches.
The forbiddenNameValidator
factory returns the configured validator function. That function takes an Angular control object and returns either null if the control value is valid or a validation error object. The validation error object typically has a property whose name is the validation key, 'forbiddenName'
, and whose value is an arbitrary dictionary of values that you could insert into an error message, {name}
.
Custom async validators are similar to sync validators, but they must instead return a Promise or observable that later emits null or a validation error object. In the case of an observable, the observable must complete, at which point the form uses the last value emitted for validation.
In reactive forms, add a custom validator by passing the function directly to the FormControl
.
this.heroForm = new FormGroup({ name: new FormControl(this.hero.name, [ Validators.required, Validators.minLength(4), forbiddenNameValidator(/bob/i) // <-- Here's how you pass in the custom validator. ]), alterEgo: new FormControl(this.hero.alterEgo), power: new FormControl(this.hero.power, Validators.required) });
In template-driven forms, add a directive to the template, where the directive wraps the validator function. For example, the corresponding ForbiddenValidatorDirective
serves as a wrapper around the forbiddenNameValidator
.
Angular recognizes the directive's role in the validation process because the directive registers itself with the NG_VALIDATORS
provider, as shown in the following example. NG_VALIDATORS
is a predefined provider with an extensible collection of validators.
providers: [{provide: NG_VALIDATORS, useExisting: ForbiddenValidatorDirective, multi: true}]
The directive class then implements the Validator
interface, so that it can easily integrate with Angular forms. Here is the rest of the directive to help you get an idea of how it all comes together.
@Directive({ selector: '[appForbiddenName]', providers: [{provide: NG_VALIDATORS, useExisting: ForbiddenValidatorDirective, multi: true}] }) export class ForbiddenValidatorDirective implements Validator { @Input('appForbiddenName') forbiddenName = ''; validate(control: AbstractControl): ValidationErrors | null { return this.forbiddenName ? forbiddenNameValidator(new RegExp(this.forbiddenName, 'i'))(control) : null; } }
Once the ForbiddenValidatorDirective
is ready, you can add its selector, appForbiddenName
, to any input element to activate it. For example:
<input type="text" id="name" name="name" class="form-control" required minlength="4" appForbiddenName="bob" [(ngModel)]="hero.name" #name="ngModel">
Notice that the custom validation directive is instantiated with
useExisting
rather thanuseClass
. The registered validator must be this instance of theForbiddenValidatorDirective
—the instance in the form with itsforbiddenName
property bound to “bob".If you were to replace
useExisting
withuseClass
, then you’d be registering a new class instance, one that doesn’t have aforbiddenName
.
Angular automatically mirrors many control properties onto the form control element as CSS classes. Use these classes to style form control elements according to the state of the form. The following classes are currently supported.
.ng-valid
.ng-invalid
.ng-pending
.ng-pristine
.ng-dirty
.ng-untouched
.ng-touched
.ng-submitted
(enclosing form element only)In the following example, the hero form uses the .ng-valid
and .ng-invalid
classes to set the color of each form control's border.
.ng-valid[required], .ng-valid.required { border-left: 5px solid #42A948; /* green */ } .ng-invalid:not(form) { border-left: 5px solid #a94442; /* red */ } .alert div { background-color: #fed3d3; color: #820000; padding: 1rem; margin-bottom: 1rem; } .form-group { margin-bottom: 1rem; } label { display: block; margin-bottom: .5rem; } select { width: 100%; padding: .5rem; }
A cross-field validator is a custom validator that compares the values of different fields in a form and accepts or rejects them in combination. For example, you might have a form that offers mutually incompatible options, so that if the user can choose A or B, but not both. Some field values might also depend on others; a user might be allowed to choose B only if A is also chosen.
The following cross validation examples show how to do the following:
The examples use cross-validation to ensure that heroes do not reveal their true identities by filling out the Hero Form. The validators do this by checking that the hero names and alter egos do not match.
The form has the following structure:
const heroForm = new FormGroup({ 'name': new FormControl(), 'alterEgo': new FormControl(), 'power': new FormControl() });
Notice that the name
and alterEgo
are sibling controls. To evaluate both controls in a single custom validator, you must perform the validation in a common ancestor control: the FormGroup
. You query the FormGroup
for its child controls so that you can compare their values.
To add a validator to the FormGroup
, pass the new validator in as the second argument on creation.
const heroForm = new FormGroup({ 'name': new FormControl(), 'alterEgo': new FormControl(), 'power': new FormControl() }, { validators: identityRevealedValidator });
The validator code is as follows.
/** A hero's name can't match the hero's alter ego */ export const identityRevealedValidator: ValidatorFn = (control: AbstractControl): ValidationErrors | null => { const name = control.get('name'); const alterEgo = control.get('alterEgo'); return name && alterEgo && name.value === alterEgo.value ? { identityRevealed: true } : null; };
The identity
validator implements the ValidatorFn
interface. It takes an Angular control object as an argument and returns either null if the form is valid, or ValidationErrors
otherwise.
The validator retrieves the child controls by calling the FormGroup
's get method, then compares the values of the name
and alterEgo
controls.
If the values do not match, the hero's identity remains secret, both are valid, and the validator returns null. If they do match, the hero's identity is revealed and the validator must mark the form as invalid by returning an error object.
To provide better user experience, the template shows an appropriate error message when the form is invalid.
<div *ngIf="heroForm.errors?.identityRevealed && (heroForm.touched || heroForm.dirty)" class="cross-validation-error-message alert alert-danger"> Name cannot match alter ego. </div>
This *ngIf
displays the error if the FormGroup
has the cross validation error returned by the identityRevealed
validator, but only if the user finished interacting with the form.
For a template-driven form, you must create a directive to wrap the validator function. You provide that directive as the validator using the NG_VALIDATORS
token, as shown in the following example.
@Directive({ selector: '[appIdentityRevealed]', providers: [{ provide: NG_VALIDATORS, useExisting: IdentityRevealedValidatorDirective, multi: true }] }) export class IdentityRevealedValidatorDirective implements Validator { validate(control: AbstractControl): ValidationErrors | null { return identityRevealedValidator(control); } }
You must add the new directive to the HTML template. Because the validator must be registered at the highest level in the form, the following template puts the directive on the form
tag.
<form #heroForm="ngForm" appIdentityRevealed>
To provide better user experience, an appropriate error message appears when the form is invalid.
<div *ngIf="heroForm.errors?.identityRevealed && (heroForm.touched || heroForm.dirty)" class="cross-validation-error-message alert"> Name cannot match alter ego. </div>
This is the same in both template-driven and reactive forms.
Asynchronous validators implement the AsyncValidatorFn
and AsyncValidator
interfaces. These are very similar to their synchronous counterparts, with the following differences.
validate()
functions must return a Promise or an observable,first
, last
, take
, or takeUntil
.Asynchronous validation happens after the synchronous validation, and is performed only if the synchronous validation is successful. This check lets forms avoid potentially expensive async validation processes (such as an HTTP request) if the more basic validation methods have already found invalid input.
After asynchronous validation begins, the form control enters a pending
state. Inspect the control's pending
property and use it to give visual feedback about the ongoing validation operation.
A common UI pattern is to show a spinner while the async validation is being performed. The following example shows how to achieve this in a template-driven form.
<input [(ngModel)]="name" #model="ngModel" appSomeAsyncValidator> <app-spinner *ngIf="model.pending"></app-spinner>
In the following example, an async validator ensures that heroes pick an alter ego that is not already taken. New heroes are constantly enlisting and old heroes are leaving the service, so the list of available alter egos cannot be retrieved ahead of time. To validate the potential alter ego entry, the validator must initiate an asynchronous operation to consult a central database of all currently enlisted heroes.
The following code create the validator class, UniqueAlterEgoValidator
, which implements the AsyncValidator
interface.
@Injectable({ providedIn: 'root' }) export class UniqueAlterEgoValidator implements AsyncValidator { constructor(private heroesService: HeroesService) {} validate( ctrl: AbstractControl ): Promise<ValidationErrors | null> | Observable<ValidationErrors | null> { return this.heroesService.isAlterEgoTaken(ctrl.value).pipe( map(isTaken => (isTaken ? { uniqueAlterEgo: true } : null)), catchError(() => of(null)) ); } }
The constructor injects the HeroesService
, which defines the following interface.
interface HeroesService { isAlterEgoTaken: (alterEgo: string) => Observable<boolean>; }
In a real world application, the HeroesService
would be responsible for making an HTTP request to the hero database to check if the alter ego is available. From the validator's point of view, the actual implementation of the service is not important, so the example can just code against the HeroesService
interface.
As the validation begins, the UniqueAlterEgoValidator
delegates to the HeroesService
isAlterEgoTaken()
method with the current control value. At this point the control is marked as pending
and remains in this state until the observable chain returned from the validate()
method completes.
The isAlterEgoTaken()
method dispatches an HTTP request that checks if the alter ego is available, and returns Observable<boolean>
as the result. The validate()
method pipes the response through the map
operator and transforms it into a validation result.
The method then, like any validator, returns null
if the form is valid, and ValidationErrors
if it is not. This validator handles any potential errors with the catchError
operator. In this case, the validator treats the isAlterEgoTaken()
error as a successful validation, because failure to make a validation request does not necessarily mean that the alter ego is invalid. You could handle the error differently and return the ValidationError
object instead.
After some time passes, the observable chain completes and the asynchronous validation is done. The pending
flag is set to false
, and the form validity is updated.
By default, all validators run after every form value change. With synchronous validators, this does not normally have a noticeable impact on application performance. Async validators, however, commonly perform some kind of HTTP request to validate the control. Dispatching an HTTP request after every keystroke could put a strain on the backend API, and should be avoided if possible.
You can delay updating the form validity by changing the updateOn
property from change
(default) to submit
or blur
.
With template-driven forms, set the property in the template.
<input [(ngModel)]="name" [ngModelOptions]="{updateOn: 'blur'}">
With reactive forms, set the property in the FormControl
instance.
new FormControl('', {updateOn: 'blur'});
By default, Angular disables native HTML form validation by adding the novalidate
attribute on the enclosing <form>
and uses directives to match these attributes with validator functions in the framework. If you want to use native validation in combination with Angular-based validation, you can re-enable it with the ngNativeValidate
directive. See the API docs for details.
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Licensed under the Creative Commons Attribution License 4.0.
https://v12.angular.io/guide/form-validation