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Template Syntax
The Angular application manages what the user sees and can do, achieving this through the interaction of a component class instance (the component) and its user-facing template.
You may be familiar with the component/template duality from your experience with model-view-controller (MVC) or model-view-viewmodel (MVVM). In Angular, the component plays the part of the controller/viewmodel, and the template represents the view.
This page is a comprehensive technical reference to the Angular template language. It explains basic principles of the template language and describes most of the syntax that you'll encounter elsewhere in the documentation.
Many code snippets illustrate the points and concepts, all of them available in the .
{@a html}
HTML in templates
HTML is the language of the Angular template.
Almost all HTML syntax is valid template syntax.
The <script>
element is a notable exception;
it is forbidden, eliminating the risk of script injection attacks.
In practice, <script>
is ignored and a warning appears in the browser console.
See the Security page for details.
Some legal HTML doesn't make much sense in a template.
The <html>
, <body>
, and <base>
elements have no useful role.
Pretty much everything else is fair game.
You can extend the HTML vocabulary of your templates with components and directives that appear as new elements and attributes. In the following sections, you'll learn how to get and set DOM (Document Object Model) values dynamically through data binding.
Begin with the first form of data binding—interpolation—to see how much richer template HTML can be.
{@a interpolation}
Interpolation ( {{...}} )
You met the double-curly braces of interpolation, {{
and }}
, early in your Angular education.
You use interpolation to weave calculated strings into the text between HTML element tags and within attribute assignments.
The text between the braces is often the name of a component property. Angular replaces that name with the
string value of the corresponding component property. In the example above, Angular evaluates the title
and heroImageUrl
properties
and "fills in the blanks", first displaying a bold application title and then a heroic image.
More generally, the text between the braces is a template expression that Angular first evaluates and then converts to a string. The following interpolation illustrates the point by adding the two numbers:
The expression can invoke methods of the host component such as getVal()
, seen here:
Angular evaluates all expressions in double curly braces, converts the expression results to strings, and links them with neighboring literal strings. Finally, it assigns this composite interpolated result to an element or directive property.
You appear to be inserting the result between element tags and assigning it to attributes. It's convenient to think so, and you rarely suffer for this mistake. Though this is not exactly true. Interpolation is a special syntax that Angular converts into a property binding, as is explained below.
But first, let's take a closer look at template expressions and statements.
{@a template-expressions}
Template expressions
A template expression produces a value. Angular executes the expression and assigns it to a property of a binding target; the target might be an HTML element, a component, or a directive.
The interpolation braces in {{1 + 1}}
surround the template expression 1 + 1
.
In the property binding section below,
a template expression appears in quotes to the right of the =
symbol as in [property]="expression"
.
You write these template expressions in a language that looks like JavaScript. Many JavaScript expressions are legal template expressions, but not all.
JavaScript expressions that have or promote side effects are prohibited, including:
- assignments (
=
,+=
,-=
, ...) new
- chaining expressions with
;
or,
- increment and decrement operators (
++
and--
)
Other notable differences from JavaScript syntax include:
- no support for the bitwise operators
|
and&
- new template expression operators, such as
|
,?.
and!
.
{@a expression-context}
Expression context
The expression context is typically the component instance.
In the following snippets, the title
within double-curly braces and the
isUnchanged
in quotes refer to properties of the AppComponent
.
An expression may also refer to properties of the template's context
such as a template input variable (let hero
)
or a template reference variable (#heroInput
).
The context for terms in an expression is a blend of the template variables, the directive's context object (if it has one), and the component's members. If you reference a name that belongs to more than one of these namespaces, the template variable name takes precedence, followed by a name in the directive's context, and, lastly, the component's member names.
The previous example presents such a name collision. The component has a hero
property and the *ngFor
defines a hero
template variable.
The hero
in {{hero.name}}
refers to the template input variable, not the component's property.
Template expressions cannot refer to anything in
the global namespace. They can't refer to window
or document
. They
can't call console.log
or Math.max
. They are restricted to referencing
members of the expression context.
{@a no-side-effects}
{@a expression-guidelines}
Expression guidelines
Template expressions can make or break an application. Please follow these guidelines:
The only exceptions to these guidelines should be in specific circumstances that you thoroughly understand.
No visible side effects
A template expression should not change any application state other than the value of the target property.
This rule is essential to Angular's "unidirectional data flow" policy. You should never worry that reading a component value might change some other displayed value. The view should be stable throughout a single rendering pass.
Quick execution
Angular executes template expressions after every change detection cycle. Change detection cycles are triggered by many asynchronous activities such as promise resolutions, http results, timer events, keypresses and mouse moves.
Expressions should finish quickly or the user experience may drag, especially on slower devices. Consider caching values when their computation is expensive.
Simplicity
Although it's possible to write quite complex template expressions, you should avoid them.
A property name or method call should be the norm.
An occasional Boolean negation (!
) is OK.
Otherwise, confine application and business logic to the component itself,
where it will be easier to develop and test.
Idempotence
An idempotent expression is ideal because it is free of side effects and improves Angular's change detection performance.
In Angular terms, an idempotent expression always returns exactly the same thing until one of its dependent values changes.
Dependent values should not change during a single turn of the event loop.
If an idempotent expression returns a string or a number, it returns the same string or number
when called twice in a row. If the expression returns an object (including an array
),
it returns the same object reference when called twice in a row.
{@a template-statements}
Template statements
A template statement responds to an event raised by a binding target
such as an element, component, or directive.
You'll see template statements in the event binding section,
appearing in quotes to the right of the =
symbol as in (event)="statement"
.
A template statement has a side effect. That's the whole point of an event. It's how you update application state from user action.
Responding to events is the other side of Angular's "unidirectional data flow". You're free to change anything, anywhere, during this turn of the event loop.
Like template expressions, template statements use a language that looks like JavaScript.
The template statement parser differs from the template expression parser and
specifically supports both basic assignment (=
) and chaining expressions
(with ;
or ,
).
However, certain JavaScript syntax is not allowed:
new
- increment and decrement operators,
++
and--
- operator assignment, such as
+=
and-=
- the bitwise operators
|
and&
- the template expression operators
Statement context
As with expressions, statements can refer only to what's in the statement context such as an event handling method of the component instance.
The statement context is typically the component instance.
The deleteHero in (click)="deleteHero()"
is a method of the data-bound component.
The statement context may also refer to properties of the template's own context.
In the following examples, the template $event
object,
a template input variable (let hero
),
and a template reference variable (#heroForm
)
are passed to an event handling method of the component.
Template context names take precedence over component context names.
In deleteHero(hero)
above, the hero
is the template input variable,
not the component's hero
property.
Template statements cannot refer to anything in the global namespace. They
can't refer to window
or document
.
They can't call console.log
or Math.max
.
Statement guidelines
As with expressions, avoid writing complex template statements. A method call or simple property assignment should be the norm.
Now that you have a feel for template expressions and statements, you're ready to learn about the varieties of data binding syntax beyond interpolation.
{@a binding-syntax}
Binding syntax: An overview
Data binding is a mechanism for coordinating what users see, with application data values. While you could push values to and pull values from HTML, the application is easier to write, read, and maintain if you turn these chores over to a binding framework. You simply declare bindings between binding sources and target HTML elements and let the framework do the work.
Angular provides many kinds of data binding. This guide covers most of them, after a high-level view of Angular data binding and its syntax.
Binding types can be grouped into three categories distinguished by the direction of data flow: from the source-to-view, from view-to-source, and in the two-way sequence: view-to-source-to-view:
Data direction | Syntax | Type |
---|---|---|
One-way from data source to view target |
|
Binding types other than interpolation have a target name to the left of the equal sign,
either surrounded by punctuation ([]
, ()
) or preceded by a prefix (bind-
, on-
, bindon-
).
The target name is the name of a property. It may look like the name of an attribute but it never is. To appreciate the difference, you must develop a new way to think about template HTML.
A new mental model
With all the power of data binding and the ability to extend the HTML vocabulary with custom markup, it is tempting to think of template HTML as HTML Plus.
It really is HTML Plus. But it's also significantly different than the HTML you're used to. It requires a new mental model.
In the normal course of HTML development, you create a visual structure with HTML elements, and you modify those elements by setting element attributes with string constants.
You still create a structure and initialize attribute values this way in Angular templates.
Then you learn to create new elements with components that encapsulate HTML and drop them into templates as if they were native HTML elements.
That's HTML Plus.
Then you learn about data binding. The first binding you meet might look like this:
You'll get to that peculiar bracket notation in a moment. Looking beyond it,
your intuition suggests that you're binding to the button's disabled
attribute and setting
it to the current value of the component's isUnchanged
property.
Your intuition is incorrect! Your everyday HTML mental model is misleading. In fact, once you start data binding, you are no longer working with HTML attributes. You aren't setting attributes. You are setting the properties of DOM elements, components, and directives.
HTML attribute vs. DOM property
The distinction between an HTML attribute and a DOM property is crucial to understanding how Angular binding works.
Attributes are defined by HTML. Properties are defined by the DOM (Document Object Model).
-
A few HTML attributes have 1:1 mapping to properties.
id
is one example. -
Some HTML attributes don't have corresponding properties.
colspan
is one example. -
Some DOM properties don't have corresponding attributes.
textContent
is one example. -
Many HTML attributes appear to map to properties ... but not in the way you might think!
That last category is confusing until you grasp this general rule:
Attributes initialize DOM properties and then they are done. Property values can change; attribute values can't.
For example, when the browser renders <input type="text" value="Bob">
, it creates a
corresponding DOM node with a value
property initialized to "Bob".
When the user enters "Sally" into the input box, the DOM element value
property becomes "Sally".
But the HTML value
attribute remains unchanged as you discover if you ask the input element
about that attribute: input.getAttribute('value')
returns "Bob".
The HTML attribute value
specifies the initial value; the DOM value
property is the current value.
The disabled
attribute is another peculiar example. A button's disabled
property is
false
by default so the button is enabled.
When you add the disabled
attribute, its presence alone initializes the button's disabled
property to true
so the button is disabled.
Adding and removing the disabled
attribute disables and enables the button. The value of the attribute is irrelevant,
which is why you cannot enable a button by writing <button disabled="false">Still Disabled</button>
.
Setting the button's disabled
property (say, with an Angular binding) disables or enables the button.
The value of the property matters.
The HTML attribute and the DOM property are not the same thing, even when they have the same name.
This fact bears repeating: Template binding works with properties and events, not attributes.
In the world of Angular, the only role of attributes is to initialize element and directive state. When you write a data binding, you're dealing exclusively with properties and events of the target object. HTML attributes effectively disappear.
With this model firmly in mind, read on to learn about binding targets.
Binding targets
The target of a data binding is something in the DOM. Depending on the binding type, the target can be an (element | component | directive) property, an (element | component | directive) event, or (rarely) an attribute name. The following table summarizes:
Type | Target | Examples |
---|---|---|
Property |
Element property Component property Directive property |
|
Event |
Element event Component event Directive event |
|
Two-way | Event and property | |
Attribute | Attribute (the exception) | |
Class |
class property
|
|
Style |
style property
|
With this broad view in mind, you're ready to look at binding types in detail.
{@a property-binding}
Property binding ( [property] )
Write a template property binding to set a property of a view element. The binding sets the property to the value of a template expression.
The most common property binding sets an element property to a component property value. An example is
binding the src
property of an image element to a component's heroImageUrl
property:
Another example is disabling a button when the component says that it isUnchanged
:
Another is setting a property of a directive:
Yet another is setting the model property of a custom component (a great way for parent and child components to communicate):
One-way in
People often describe property binding as one-way data binding because it flows a value in one direction, from a component's data property into a target element property.
You cannot use property binding to pull values out of the target element. You can't bind to a property of the target element to read it. You can only set it.
Similarly, you cannot use property binding to call a method on the target element.
If the element raises events, you can listen to them with an event binding.
If you must read a target element property or call one of its methods, you'll need a different technique. See the API reference for ViewChild and ContentChild.
Binding target
An element property between enclosing square brackets identifies the target property.
The target property in the following code is the image element's src
property.
Some people prefer the bind-
prefix alternative, known as the canonical form:
The target name is always the name of a property, even when it appears to be the name of something else.
You see src
and may think it's the name of an attribute. No. It's the name of an image element property.
Element properties may be the more common targets, but Angular looks first to see if the name is a property of a known directive, as it is in the following example:
Technically, Angular is matching the name to a directive input,
one of the property names listed in the directive's inputs
array or a property decorated with @Input()
.
Such inputs map to the directive's own properties.
If the name fails to match a property of a known directive or element, Angular reports an “unknown directive” error.
Avoid side effects
As mentioned previously, evaluation of a template expression should have no visible side effects. The expression language itself does its part to keep you safe. You can't assign a value to anything in a property binding expression nor use the increment and decrement operators.
Of course, the expression might invoke a property or method that has side effects. Angular has no way of knowing that or stopping you.
The expression could call something like getFoo()
. Only you know what getFoo()
does.
If getFoo()
changes something and you happen to be binding to that something, you risk an unpleasant experience.
Angular may or may not display the changed value. Angular may detect the change and throw a warning error.
In general, stick to data properties and to methods that return values and do no more.
Return the proper type
The template expression should evaluate to the type of value expected by the target property. Return a string if the target property expects a string. Return a number if the target property expects a number. Return an object if the target property expects an object.
The hero
property of the HeroDetail
component expects a Hero
object, which is exactly what you're sending in the property binding:
Remember the brackets
The brackets tell Angular to evaluate the template expression. If you omit the brackets, Angular treats the string as a constant and initializes the target property with that string. It does not evaluate the string!
Don't make the following mistake:
{@a one-time-initialization}
One-time string initialization
You should omit the brackets when all of the following are true:
- The target property accepts a string value.
- The string is a fixed value that you can bake into the template.
- This initial value never changes.
You routinely initialize attributes this way in standard HTML, and it works
just as well for directive and component property initialization.
The following example initializes the prefix
property of the HeroDetailComponent
to a fixed string,
not a template expression. Angular sets it and forgets about it.
The [hero]
binding, on the other hand, remains a live binding to the component's currentHero
property.
{@a property-binding-or-interpolation}
Property binding or interpolation?
You often have a choice between interpolation and property binding. The following binding pairs do the same thing:
Interpolation is a convenient alternative to property binding in many cases.
When rendering data values as strings, there is no technical reason to prefer one form to the other. You lean toward readability, which tends to favor interpolation. You suggest establishing coding style rules and choosing the form that both conforms to the rules and feels most natural for the task at hand.
When setting an element property to a non-string data value, you must use property binding.
Content security
Imagine the following malicious content.
Fortunately, Angular data binding is on alert for dangerous HTML. It sanitizes the values before displaying them. It will not allow HTML with script tags to leak into the browser, neither with interpolation nor property binding.
Interpolation handles the script tags differently than property binding but both approaches render the content harmlessly.
{@a other-bindings}
Attribute, class, and style bindings
The template syntax provides specialized one-way bindings for scenarios less well suited to property binding.
Attribute binding
You can set the value of an attribute directly with an attribute binding.
This is the only exception to the rule that a binding sets a target property. This is the only binding that creates and sets an attribute.
This guide stresses repeatedly that setting an element property with a property binding is always preferred to setting the attribute with a string. Why does Angular offer attribute binding?
You must use attribute binding when there is no element property to bind.
Consider the ARIA, SVG, and table span attributes. They are pure attributes. They do not correspond to element properties, and they do not set element properties. There are no property targets to bind to.
This fact becomes painfully obvious when you write something like this.
<tr><td colspan="{{1 + 1}}">Three-Four</td></tr>And you get this error:
Template parse errors: Can't bind to 'colspan' since it isn't a known native propertyAs the message says, the <td>
element does not have a colspan
property.
It has the "colspan" attribute, but
interpolation and property binding can set only properties, not attributes.
You need attribute bindings to create and bind to such attributes.
Attribute binding syntax resembles property binding.
Instead of an element property between brackets, start with the prefix attr
,
followed by a dot (.
) and the name of the attribute.
You then set the attribute value, using an expression that resolves to a string.
Bind [attr.colspan]
to a calculated value:
Here's how the table renders:
One-Two | |
Five | Six |
One of the primary use cases for attribute binding is to set ARIA attributes, as in this example:
Class binding
You can add and remove CSS class names from an element's class
attribute with
a class binding.
Class binding syntax resembles property binding.
Instead of an element property between brackets, start with the prefix class
,
optionally followed by a dot (.
) and the name of a CSS class: [class.class-name]
.
The following examples show how to add and remove the application's "special" class with class bindings. Here's how to set the attribute without binding:
You can replace that with a binding to a string of the desired class names; this is an all-or-nothing, replacement binding.
Finally, you can bind to a specific class name. Angular adds the class when the template expression evaluates to truthy. It removes the class when the expression is falsy.
While this is a fine way to toggle a single class name, the NgClass directive is usually preferred when managing multiple class names at the same time.
Style binding
You can set inline styles with a style binding.
Style binding syntax resembles property binding.
Instead of an element property between brackets, start with the prefix style
,
followed by a dot (.
) and the name of a CSS style property: [style.style-property]
.
Some style binding styles have a unit extension. The following example conditionally sets the font size in “em” and “%” units .
While this is a fine way to set a single style, the NgStyle directive is generally preferred when setting several inline styles at the same time.
Note that a style property name can be written in either
dash-case, as shown above, or
camelCase, such as fontSize
.
{@a event-binding}
Event binding ( (event) )
The bindings directives you've met so far flow data in one direction: from a component to an element.
Users don't just stare at the screen. They enter text into input boxes. They pick items from lists. They click buttons. Such user actions may result in a flow of data in the opposite direction: from an element to a component.
The only way to know about a user action is to listen for certain events such as keystrokes, mouse movements, clicks, and touches. You declare your interest in user actions through Angular event binding.
Event binding syntax consists of a target event name
within parentheses on the left of an equal sign, and a quoted
template statement on the right.
The following event binding listens for the button's click events, calling
the component's onSave()
method whenever a click occurs:
Target event
A name between parentheses — for example, (click)
—
identifies the target event. In the following example, the target is the button's click event.
Some people prefer the on-
prefix alternative, known as the canonical form:
Element events may be the more common targets, but Angular looks first to see if the name matches an event property of a known directive, as it does in the following example:
The myClick
directive is further described in the section
on aliasing input/output properties.
If the name fails to match an element event or an output property of a known directive, Angular reports an “unknown directive” error.
$event and event handling statements
In an event binding, Angular sets up an event handler for the target event.
When the event is raised, the handler executes the template statement. The template statement typically involves a receiver, which performs an action in response to the event, such as storing a value from the HTML control into a model.
The binding conveys information about the event, including data values, through
an event object named $event
.
The shape of the event object is determined by the target event.
If the target event is a native DOM element event, then $event
is a
DOM event object,
with properties such as target
and target.value
.
Consider this example:
This code sets the input box value
property by binding to the name
property.
To listen for changes to the value, the code binds to the input box's input
event.
When the user makes changes, the input
event is raised, and the binding executes
the statement within a context that includes the DOM event object, $event
.
To update the name
property, the changed text is retrieved by following the path $event.target.value
.
If the event belongs to a directive (recall that components are directives),
$event
has whatever shape the directive decides to produce.
{@a eventemitter}
{@a custom-event}
Custom events with EventEmitter
Directives typically raise custom events with an Angular EventEmitter.
The directive creates an EventEmitter
and exposes it as a property.
The directive calls EventEmitter.emit(payload)
to fire an event, passing in a message payload, which can be anything.
Parent directives listen for the event by binding to this property and accessing the payload through the $event
object.
Consider a HeroDetailComponent
that presents hero information and responds to user actions.
Although the HeroDetailComponent
has a delete button it doesn't know how to delete the hero itself.
The best it can do is raise an event reporting the user's delete request.
Here are the pertinent excerpts from that HeroDetailComponent
:
The component defines a deleteRequest
property that returns an EventEmitter
.
When the user clicks delete, the component invokes the delete()
method,
telling the EventEmitter
to emit a Hero
object.
Now imagine a hosting parent component that binds to the HeroDetailComponent
's deleteRequest
event.
When the deleteRequest
event fires, Angular calls the parent component's deleteHero
method,
passing the hero-to-delete (emitted by HeroDetail
) in the $event
variable.
Template statements have side effects
The deleteHero
method has a side effect: it deletes a hero.
Template statement side effects are not just OK, but expected.
Deleting the hero updates the model, perhaps triggering other changes including queries and saves to a remote server. These changes percolate through the system and are ultimately displayed in this and other views.
{@a two-way}
Two-way binding ( [(...)] )
You often want to both display a data property and update that property when the user makes changes.
On the element side that takes a combination of setting a specific element property and listening for an element change event.
Angular offers a special two-way data binding syntax for this purpose, [(x)]
.
The [(x)]
syntax combines the brackets
of property binding, [x]
, with the parentheses of event binding, (x)
.
Visualize a banana in a box to remember that the parentheses go inside the brackets.
The [(x)]
syntax is easy to demonstrate when the element has a settable property called x
and a corresponding event named xChange
.
Here's a SizerComponent
that fits the pattern.
It has a size
value property and a companion sizeChange
event:
The initial size
is an input value from a property binding.
Clicking the buttons increases or decreases the size
, within min/max values constraints,
and then raises (emits) the sizeChange
event with the adjusted size.
Here's an example in which the AppComponent.fontSizePx
is two-way bound to the SizerComponent
:
The AppComponent.fontSizePx
establishes the initial SizerComponent.size
value.
Clicking the buttons updates the AppComponent.fontSizePx
via the two-way binding.
The revised AppComponent.fontSizePx
value flows through to the style binding,
making the displayed text bigger or smaller.
The two-way binding syntax is really just syntactic sugar for a property binding and an event binding.
Angular desugars the SizerComponent
binding into this:
The $event
variable contains the payload of the SizerComponent.sizeChange
event.
Angular assigns the $event
value to the AppComponent.fontSizePx
when the user clicks the buttons.
Clearly the two-way binding syntax is a great convenience compared to separate property and event bindings.
It would be convenient to use two-way binding with HTML form elements like <input>
and <select>
.
However, no native HTML element follows the x
value and xChange
event pattern.
Fortunately, the Angular NgModel directive is a bridge that enables two-way binding to form elements.
{@a directives}
Built-in directives
Earlier versions of Angular included over seventy built-in directives. The community contributed many more, and countless private directives have been created for internal applications.
You don't need many of those directives in Angular. You can often achieve the same results with the more capable and expressive Angular binding system. Why create a directive to handle a click when you can write a simple binding such as this?
You still benefit from directives that simplify complex tasks. Angular still ships with built-in directives; just not as many. You'll write your own directives, just not as many.
This segment reviews some of the most frequently used built-in directives, classified as either attribute directives or structural directives.
{@a attribute-directives}
Built-in attribute directives
Attribute directives listen to and modify the behavior of other HTML elements, attributes, properties, and components. They are usually applied to elements as if they were HTML attributes, hence the name.
Many details are covered in the Attribute Directives guide.
Many NgModules such as the RouterModule
and the FormsModule
define their own attribute directives.
This section is an introduction to the most commonly used attribute directives:
NgClass
- add and remove a set of CSS classesNgStyle
- add and remove a set of HTML stylesNgModel
- two-way data binding to an HTML form element
{@a ngClass}
NgClass
You typically control how elements appear
by adding and removing CSS classes dynamically.
You can bind to the ngClass
to add or remove several classes simultaneously.
A class binding is a good way to add or remove a single class.
To add or remove many CSS classes at the same time, the NgClass
directive may be the better choice.
Try binding ngClass
to a key:value control object.
Each key of the object is a CSS class name; its value is true
if the class should be added,
false
if it should be removed.
Consider a setCurrentClasses
component method that sets a component property,
currentClasses
with an object that adds or removes three classes based on the
true
/false
state of three other component properties:
Adding an ngClass
property binding to currentClasses
sets the element's classes accordingly:
It's up to you to call setCurrentClassess()
, both initially and when the dependent properties change.
{@a ngStyle}
NgStyle
You can set inline styles dynamically, based on the state of the component.
With NgStyle
you can set many inline styles simultaneously.
A style binding is an easy way to set a single style value.
To set many inline styles at the same time, the NgStyle
directive may be the better choice.
Try binding ngStyle
to a key:value control object.
Each key of the object is a style name; its value is whatever is appropriate for that style.
Consider a setCurrentStyles
component method that sets a component property, currentStyles
with an object that defines three styles, based on the state of three other component propertes:
Adding an ngStyle
property binding to currentStyles
sets the element's styles accordingly:
It's up to you to call setCurrentStyles()
, both initially and when the dependent properties change.
{@a ngModel}
NgModel - Two-way binding to form elements with [(ngModel)]
When developing data entry forms, you often both display a data property and update that property when the user makes changes.
Two-way data binding with the NgModel
directive makes that easy. Here's an example:
FormsModule is required to use ngModel
Before using the ngModel
directive in a two-way data binding,
you must import the FormsModule
and add it to the NgModule's imports
list.
Learn more about the FormsModule
and ngModel
in the
Forms guide.
Here's how to import the FormsModule
to make [(ngModel)]
available.
Inside [(ngModel)]
Looking back at the name
binding, note that
you could have achieved the same result with separate bindings to
the <input>
element's value
property and input
event.
That's cumbersome. Who can remember which element property to set and which element event emits user changes? How do you extract the currently displayed text from the input box so you can update the data property? Who wants to look that up each time?
That ngModel
directive hides these onerous details behind its own ngModel
input and ngModelChange
output properties.
The ngModel
data property sets the element's value property and the ngModelChange
event property
listens for changes to the element's value.
The details are specific to each kind of element and therefore the NgModel
directive only works for an element
supported by a ControlValueAccessor
that adapts an element to this protocol.
The <input>
box is one of those elements.
Angular provides value accessors for all of the basic HTML form elements and the
Forms guide shows how to bind to them.
You can't apply [(ngModel)]
to a non-form native element or a third-party custom component
until you write a suitable value accessor,
a technique that is beyond the scope of this guide.
You don't need a value accessor for an Angular component that you write because you
can name the value and event properties
to suit Angular's basic two-way binding syntax and skip NgModel
altogether.
The sizer
shown above is an example of this technique.
Separate ngModel
bindings is an improvement over binding to the element's native properties. You can do better.
You shouldn't have to mention the data property twice. Angular should be able to capture
the component's data property and set it
with a single declaration, which it can with the [(ngModel)]
syntax:
Is [(ngModel)]
all you need? Is there ever a reason to fall back to its expanded form?
The [(ngModel)]
syntax can only set a data-bound property.
If you need to do something more or something different, you can write the expanded form.
The following contrived example forces the input value to uppercase:
Here are all variations in action, including the uppercase version:
{@a structural-directives}
Built-in structural directives
Structural directives are responsible for HTML layout. They shape or reshape the DOM's structure, typically by adding, removing, and manipulating the host elements to which they are attached.
The deep details of structural directives are covered in the Structural Directives guide where you'll learn:
- why you prefix the directive name with an asterisk (*).
- to use
<ng-container>
to group elements when there is no suitable host element for the directive. - how to write your own structural directive.
- that you can only apply one structural directive to an element.
This section is an introduction to the common structural directives:
NgIf
- conditionally add or remove an element from the DOMNgSwitch
- a set of directives that switch among alternative views- NgForOf - repeat a template for each item in a list
{@a ngIf}
NgIf
You can add or remove an element from the DOM by applying an NgIf
directive to
that element (called the host element).
Bind the directive to a condition expression like isActive
in this example.
Don't forget the asterisk (*
) in front of ngIf
.
When the isActive
expression returns a truthy value, NgIf
adds the HeroDetailComponent
to the DOM.
When the expression is falsy, NgIf
removes the HeroDetailComponent
from the DOM, destroying that component and all of its sub-components.
Show/hide is not the same thing
You can control the visibility of an element with a class or style binding:
Hiding an element is quite different from removing an element with NgIf
.
When you hide an element, that element and all of its descendents remain in the DOM. All components for those elements stay in memory and Angular may continue to check for changes. You could be holding onto considerable computing resources and degrading performance, for something the user can't see.
When NgIf
is false
, Angular removes the element and its descendents from the DOM.
It destroys their components, potentially freeing up substantial resources,
resulting in a more responsive user experience.
The show/hide technique is fine for a few elements with few children.
You should be wary when hiding large component trees; NgIf
may be the safer choice.
Guard against null
The ngIf
directive is often used to guard against null.
Show/hide is useless as a guard.
Angular will throw an error if a nested expression tries to access a property of null
.
Here we see NgIf
guarding two <div>
s.
The currentHero
name will appear only when there is a currentHero
.
The nullHero
will never be displayed.
See also the safe navigation operator described below.
{@a ngFor}
NgForOf
NgForOf
is a repeater directive — a way to present a list of items.
You define a block of HTML that defines how a single item should be displayed.
You tell Angular to use that block as a template for rendering each item in the list.
Here is an example of NgForOf
applied to a simple <div>
:
You can also apply an NgForOf
to a component element, as in this example:
Don't forget the asterisk (*
) in front of ngFor
.
The text assigned to *ngFor
is the instruction that guides the repeater process.
{@a microsyntax}
*ngFor microsyntax
The string assigned to *ngFor
is not a template expression.
It's a microsyntax — a little language of its own that Angular interprets.
The string "let hero of heroes"
means:
Take each hero in the
heroes
array, store it in the localhero
looping variable, and make it available to the templated HTML for each iteration.
Angular translates this instruction into a <ng-template>
around the host element,
then uses this template repeatedly to create a new set of elements and bindings for each hero
in the list.
Learn about the microsyntax in the Structural Directives guide.
{@a template-input-variable}
{@a template-input-variables}
Template input variables
The let
keyword before hero
creates a template input variable called hero
.
The NgForOf
directive iterates over the heroes
array returned by the parent component's heroes
property
and sets hero
to the current item from the array during each iteration.
You reference the hero
input variable within the NgForOf
host element
(and within its descendents) to access the hero's properties.
Here it is referenced first in an interpolation
and then passed in a binding to the hero
property of the <hero-detail>
component.
Learn more about template input variables in the Structural Directives guide.
*ngFor with index
The index
property of the NgForOf
directive context returns the zero-based index of the item in each iteration.
You can capture the index
in a template input variable and use it in the template.
The next example captures the index
in a variable named i
and displays it with the hero name like this.
NgFor
is implemented by the NgForOf
directive. Read more about the other NgForOf
context values such as last
, even
,
and odd
in the NgForOf API reference.
{@a trackBy}
*ngFor with trackBy
The NgForOf
directive may perform poorly, especially with large lists.
A small change to one item, an item removed, or an item added can trigger a cascade of DOM manipulations.
For example, re-querying the server could reset the list with all new hero objects.
Most, if not all, are previously displayed heroes.
You know this because the id
of each hero hasn't changed.
But Angular sees only a fresh list of new object references.
It has no choice but to tear down the old DOM elements and insert all new DOM elements.
Angular can avoid this churn with trackBy
.
Add a method to the component that returns the value NgForOf
should track.
In this case, that value is the hero's id
.
In the microsyntax expression, set trackBy
to this method.
Here is an illustration of the trackBy effect.
"Reset heroes" creates new heroes with the same hero.id
s.
"Change ids" creates new heroes with new hero.id
s.
- With no
trackBy
, both buttons trigger complete DOM element replacement. - With
trackBy
, only changing theid
triggers element replacement.
{@a ngSwitch}
The NgSwitch directives
NgSwitch is like the JavaScript switch
statement.
It can display one element from among several possible elements, based on a switch condition.
Angular puts only the selected element into the DOM.
NgSwitch is actually a set of three, cooperating directives:
NgSwitch
, NgSwitchCase
, and NgSwitchDefault
as seen in this example.
NgSwitch
is the controller directive. Bind it to an expression that returns the switch value.
The emotion
value in this example is a string, but the switch value can be of any type.
Bind to [ngSwitch]
. You'll get an error if you try to set *ngSwitch
because
NgSwitch
is an attribute directive, not a structural directive.
It changes the behavior of its companion directives.
It doesn't touch the DOM directly.
Bind to *ngSwitchCase
and *ngSwitchDefault
.
The NgSwitchCase
and NgSwitchDefault
directives are structural directives
because they add or remove elements from the DOM.
NgSwitchCase
adds its element to the DOM when its bound value equals the switch value.NgSwitchDefault
adds its element to the DOM when there is no selectedNgSwitchCase
.
The switch directives are particularly useful for adding and removing component elements.
This example switches among four "emotional hero" components defined in the hero-switch.components.ts
file.
Each component has a hero
input property
which is bound to the currentHero
of the parent component.
Switch directives work as well with native elements and web components too.
For example, you could replace the <confused-hero>
switch case with the following.
{@a template-reference-variable}
{@a ref-vars}
{@a ref-var}
Template reference variables ( #var )
A template reference variable is often a reference to a DOM element within a template. It can also be a reference to an Angular component or directive or a web component.
Use the hash symbol (#) to declare a reference variable.
The #phone
declares a phone
variable on an <input>
element.
You can refer to a template reference variable anywhere in the template.
The phone
variable declared on this <input>
is
consumed in a <button>
on the other side of the template
How a reference variable gets its value
In most cases, Angular sets the reference variable's value to the element on which it was declared.
In the previous example, phone
refers to the phone number <input>
box.
The phone button click handler passes the input value to the component's callPhone
method.
But a directive can change that behavior and set the value to something else, such as itself.
The NgForm
directive does that.
The following is a simplified version of the form example in the Forms guide.
A template reference variable, heroForm
, appears three times in this example, separated
by a large amount of HTML.
What is the value of heroForm
?
If Angular hadn't taken it over when you imported the FormsModule
,
it would be the HTMLFormElement.
The heroForm
is actually a reference to an Angular NgForm
directive with the ability to track the value and validity of every control in the form.
The native <form>
element doesn't have a form
property.
But the NgForm
directive does, which explains how you can disable the submit button
if the heroForm.form.valid
is invalid and pass the entire form control tree
to the parent component's onSubmit
method.
Template reference variable warning notes
A template reference variable (#phone
) is not the same as a template input variable (let phone
)
such as you might see in an *ngFor
.
Learn the difference in the Structural Directives guide.
The scope of a reference variable is the entire template. Do not define the same variable name more than once in the same template. The runtime value will be unpredictable.
You can use the ref-
prefix alternative to #
.
This example declares the fax
variable as ref-fax
instead of #fax
.
{@a inputs-outputs}
Input and output properties ( @Input and @Output )
So far, you've focused mainly on binding to component members within template expressions and statements that appear on the right side of the binding declaration. A member in that position is a data binding source.
This section concentrates on binding to targets, which are directive properties on the left side of the binding declaration. These directive properties must be declared as inputs or outputs.
Remember: All components are directives.
Note the important distinction between a data binding target and a data binding source.
The target of a binding is to the left of the =
.
The source is on the right of the =
.
The target of a binding is the property or event inside the binding punctuation: []
, ()
or [()]
.
The source is either inside quotes (" "
) or within an interpolation ({{}}
).
Every member of a source directive is automatically available for binding. You don't have to do anything special to access a directive member in a template expression or statement.
You have limited access to members of a target directive. You can only bind to properties that are explicitly identified as inputs and outputs.
In the following snippet, iconUrl
and onSave
are data-bound members of the AppComponent
and are referenced within quoted syntax to the right of the equals (=
).
They are neither inputs nor outputs of the component. They are sources for their bindings.
The targets are the native <img>
and <button>
elements.
Now look at a another snippet in which the HeroDetailComponent
is the target of a binding on the left of the equals (=
).
Both HeroDetailComponent.hero
and HeroDetailComponent.deleteRequest
are on the left side of binding declarations.
HeroDetailComponent.hero
is inside brackets; it is the target of a property binding.
HeroDetailComponent.deleteRequest
is inside parentheses; it is the target of an event binding.
Declaring input and output properties
Target properties must be explicitly marked as inputs or outputs.
In the HeroDetailComponent
, such properties are marked as input or output properties using decorators.
Alternatively, you can identify members in the inputs
and outputs
arrays
of the directive metadata, as in this example:
You can specify an input/output property either with a decorator or in a metadata array. Don't do both!
Input or output?
Input properties usually receive data values.
Output properties expose event producers, such as EventEmitter
objects.
The terms input and output reflect the perspective of the target directive.
HeroDetailComponent.hero
is an input property from the perspective of HeroDetailComponent
because data flows into that property from a template binding expression.
HeroDetailComponent.deleteRequest
is an output property from the perspective of HeroDetailComponent
because events stream out of that property and toward the handler in a template binding statement.
Aliasing input/output properties
Sometimes the public name of an input/output property should be different from the internal name.
This is frequently the case with attribute directives.
Directive consumers expect to bind to the name of the directive.
For example, when you apply a directive with a myClick
selector to a <div>
tag,
you expect to bind to an event property that is also called myClick
.
However, the directive name is often a poor choice for the name of a property within the directive class.
The directive name rarely describes what the property does.
The myClick
directive name is not a good name for a property that emits click messages.
Fortunately, you can have a public name for the property that meets conventional expectations,
while using a different name internally.
In the example immediately above, you are actually binding through the myClick
alias to
the directive's own clicks
property.
You can specify the alias for the property name by passing it into the input/output decorator like this:
You can also alias property names in the inputs
and outputs
arrays.
You write a colon-delimited (:
) string with
the directive property name on the left and the public alias on the right:
{@a expression-operators}
Template expression operators
The template expression language employs a subset of JavaScript syntax supplemented with a few special operators for specific scenarios. The next sections cover two of these operators: pipe and safe navigation operator.
{@a pipe}
The pipe operator ( | )
The result of an expression might require some transformation before you're ready to use it in a binding. For example, you might display a number as a currency, force text to uppercase, or filter a list and sort it.
Angular pipes are a good choice for small transformations such as these.
Pipes are simple functions that accept an input value and return a transformed value.
They're easy to apply within template expressions, using the pipe operator (|
):
The pipe operator passes the result of an expression on the left to a pipe function on the right.
You can chain expressions through multiple pipes:
And you can also apply parameters to a pipe:
The json
pipe is particularly helpful for debugging bindings:
The generated output would look something like this
{ "id": 0, "name": "Hercules", "emotion": "happy", "birthdate": "1970-02-25T08:00:00.000Z", "url": "http://www.imdb.com/title/tt0065832/", "rate": 325 }{@a safe-navigation-operator}
The safe navigation operator ( ?. ) and null property paths
The Angular safe navigation operator (?.
) is a fluent and convenient way to
guard against null and undefined values in property paths.
Here it is, protecting against a view render failure if the currentHero
is null.
What happens when the following data bound title
property is null?
The view still renders but the displayed value is blank; you see only "The title is" with nothing after it. That is reasonable behavior. At least the app doesn't crash.
Suppose the template expression involves a property path, as in this next example
that displays the name
of a null hero.
JavaScript throws a null reference error, and so does Angular:
TypeError: Cannot read property 'name' of null in [null].Worse, the entire view disappears.
This would be reasonable behavior if the hero
property could never be null.
If it must never be null and yet it is null,
that's a programming error that should be caught and fixed.
Throwing an exception is the right thing to do.
On the other hand, null values in the property path may be OK from time to time, especially when the data are null now and will arrive eventually.
While waiting for data, the view should render without complaint, and
the null property path should display as blank just as the title
property does.
Unfortunately, the app crashes when the currentHero
is null.
You could code around that problem with *ngIf.
You could try to chain parts of the property path with &&
, knowing that the expression bails out
when it encounters the first null.
These approaches have merit but can be cumbersome, especially if the property path is long.
Imagine guarding against a null somewhere in a long property path such as a.b.c.d
.
The Angular safe navigation operator (?.
) is a more fluent and convenient way to guard against nulls in property paths.
The expression bails out when it hits the first null value.
The display is blank, but the app keeps rolling without errors.
It works perfectly with long property paths such as a?.b?.c?.d
.
{@a non-null-assertion-operator}
The non-null assertion operator ( ! )
As of Typescript 2.0, you can enforce strict null checking with the --strictNullChecks
flag. TypeScript then ensures that no variable is unintentionally null or undefined.
In this mode, typed variables disallow null and undefined by default. The type checker throws an error if you leave a variable unassigned or try to assign null or undefined to a variable whose type disallows null and undefined.
The type checker also throws an error if it can't determine whether a variable will be null or undefined at runtime. You may know that can't happen but the type checker doesn't know. You tell the type checker that it can't happen by applying the post-fix non-null assertion operator (!).
The Angular non-null assertion operator (!
) serves the same purpose in an Angular template.
For example, after you use *ngIf to check that hero
is defined, you can assert that
hero
properties are also defined.
When the Angular compiler turns your template into TypeScript code,
it prevents TypeScript from reporting that hero.name
might be null or undefined.
Unlike the safe navigation operator, the non-null assertion operator does not guard against null or undefined. Rather it tells the TypeScript type checker to suspend strict null checks for a specific property expression.
You'll need this template operator when you turn on strict null checks. It's optional otherwise.
Summary
You've completed this survey of template syntax. Now it's time to put that knowledge to work on your own components and directives.