User Interface Component Model (original) (raw)

In addition to the lifecycle description, an overview of JavaServer Faces architecture provides better understanding of the technology.

JavaServer Faces components are the building blocks of a JavaServer Faces view. A component can be a user interface (UI) component or a non-UI component.

JavaServer Faces UI components are configurable, reusable elements that compose the user interfaces of JavaServer Faces applications. A component can be simple, such as a button, or can be compound, such as a table composed of multiple components.

JavaServer Faces technology provides a rich, flexible component architecture that includes the following:

• A set of javax.faces.component.UIComponent classes for specifying the state and behavior of UI components
• A rendering model that defines how to render the components in various ways
• A conversion model that defines how to register data converters onto a component
• An event and listener model that defines how to handle component events
• A validation model that defines how to register validators onto a component

This section briefly describes each of these pieces of the component architecture.

User Interface Component Classes

JavaServer Faces technology provides a set of UI component classes and associated behavioral interfaces that specify all the UI component functionality, such as holding component state, maintaining a reference to objects, and driving event handling and rendering for a set of standard components.

The abstract base class for all components isjavax.faces.component.UIComponent. JavaServer Faces UI component classes extend the UIComponentBase class (a subclass ofUIComponent), which defines the default state and behavior of a component. The following set of component classes is included with JavaServer Faces technology.

• UIColumn: Represents a single column of data in a UIDatacomponent.
• UICommand: Represents a control that fires actions when activated.
• UIData: Represents a data binding to a collection of data represented by a javax.faces.model.DataModel instance.
• UIForm: Represents an input form to be presented to the user. Its child components represent (among other things) the input fields to be included when the form is submitted. This component is analogous to theform tag in HTML.
• UIGraphic: Displays an image.
• UIInput: Takes data input from a user. This class is a subclass ofUIOutput.
• UIMessage: Displays a localized error message.
• UIMessages: Displays a set of localized error messages.
• UIOutcomeTarget: Displays a link in the form of a link or a button.
• UIOutput: Displays data output on a page.
• UIPanel: Manages the layout of its child components.
• UIParameter: Represents substitution parameters.
• UISelectBoolean: Allows a user to set a boolean value on a control by selecting or deselecting it. This class is a subclass of theUIInput class.
• UISelectItem: Represents a single item in a set of items.
• UISelectItems: Represents an entire set of items.
• UISelectMany: Allows a user to select multiple items from a group of items. This class is a subclass of the UIInput class.
• UISelectOne: Allows a user to select one item from a group of items. This class is a subclass of the UIInput class.
• UIViewParameter: Represents the query parameters in a request. This class is a subclass of the UIInput class.
• UIViewRoot: Represents the root of the component tree.

In addition to extending UIComponentBase, the component classes also implement one or more behavioral interfaces, each of which defines certain behavior for a set of components whose classes implement the interface.

These behavioral interfaces, all defined in the javax.faces.componentpackage unless otherwise stated, are as follows.

• ActionSource: Indicates that the component can fire an action event. This interface is intended for use with components based on JavaServer Faces technology 1.1_01 and earlier versions. This interface is deprecated in JavaServer Faces 2.
• ActionSource2: Extends ActionSource and therefore provides the same functionality. However, it allows components to use the Expression Language (EL) when they are referencing methods that handle action events.
• EditableValueHolder: Extends ValueHolder and specifies additional features for editable components, such as validation and emitting value-change events.
• NamingContainer: Mandates that each component rooted at this component have a unique ID.
• StateHolder: Denotes that a component has state that must be saved between requests.
• ValueHolder: Indicates that the component maintains a local value as well as the option of accessing data in the model tier.
• javax.faces.event.SystemEventListenerHolder: Maintains a list ofjavax.faces.event.SystemEventListener instances for each type ofjavax.faces.event.SystemEvent defined by that class.
• javax.faces.component.behavior.ClientBehaviorHolder: Adds the ability to attach javax.faces.component.behavior.ClientBehaviorinstances, such as a reusable script.

UICommand implements ActionSource2 and StateHolder. UIOutput and component classes that extend UIOutput implement StateHolder andValueHolder. UIInput and component classes that extend UIInputimplement EditableValueHolder, StateHolder, and ValueHolder.UIComponentBase implements StateHolder.

Only component writers will need to use the component classes and behavioral interfaces directly. Page authors and application developers will use a standard component by including a tag that represents it on a page. Most of the components can be rendered in different ways on a page. For example, a UICommand component can be rendered as a button or a link.

The next section explains how the rendering model works and how page authors can choose to render the components by selecting the appropriate tags.

Component Rendering Model

The JavaServer Faces component architecture is designed such that the functionality of the components is defined by the component classes, whereas the component rendering can be defined by a separate renderer class. This design has several benefits, including the following.

• Component writers can define the behavior of a component once but create multiple renderers, each of which defines a different way to render the component to the same client or to different clients.
• Page authors and application developers can change the appearance of a component on the page by selecting the tag that represents the appropriate combination of component and renderer.

A render kit defines how component classes map to component tags that are appropriate for a particular client. The JavaServer Faces implementation includes a standard HTML render kit for rendering to an HTML client.

The render kit defines a set of javax.faces.render.Renderer classes for each component that it supports. Each Renderer class defines a different way to render the particular component to the output defined by the render kit. For example, a UISelectOne component has three different renderers. One of them renders the component as a group of options. Another renders the component as a combo box. The third one renders the component as a list box. Similarly, a UICommand component can be rendered as a button or a link, using the h:commandButton orh:commandLink tag. The command part of each tag corresponds to theUICommand class, specifying the functionality, which is to fire an action. The Button or Link part of each tag corresponds to a separate Renderer class that defines how the component appears on the page.

Each custom tag defined in the standard HTML render kit is composed of the component functionality (defined in the UIComponent class) and the rendering attributes (defined by the Renderer class).

The JavaServer Faces implementation provides a custom tag library for rendering components in HTML.

Conversion Model

A JavaServer Faces application can optionally associate a component with server-side object data. This object is a JavaBeans component, such as a managed bean. An application gets and sets the object data for a component by calling the appropriate object properties for that component.

When a component is bound to an object, the application has two views of the component’s data.

• The model view, in which data is represented as data types, such asint or long.
• The presentation view, in which data is represented in a manner that can be read or modified by the user. For example, a java.util.Datemight be represented as a text string in the format mm/dd/yy or as a set of three text strings.

The JavaServer Faces implementation automatically converts component data between these two views when the bean property associated with the component is of one of the types supported by the component’s data. For example, if a UISelectBoolean component is associated with a bean property of type java.lang.Boolean, the JavaServer Faces implementation will automatically convert the component’s data fromString to Boolean. In addition, some component data must be bound to properties of a particular type. For example, a UISelectBooleancomponent must be bound to a property of type boolean orjava.lang.Boolean.

Sometimes you might want to convert a component’s data to a type other than a standard type, or you might want to convert the format of the data. To facilitate this, JavaServer Faces technology allows you to register a javax.faces.convert.Converter implementation on UIOutputcomponents and components whose classes subclass UIOutput. If you register the Converter implementation on a component, the Converterimplementation converts the component’s data between the two views.

Event and Listener Model

The JavaServer Faces event and listener model is similar to the JavaBeans event model in that it has strongly typed event classes and listener interfaces that an application can use to handle events generated by components.

The JavaServer Faces specification defines three types of events: application events, system events, and data-model events.

Application events are tied to a particular application and are generated by a UIComponent. They represent the standard events available in previous versions of JavaServer Faces technology.

An event object identifies the component that generated the event and stores information about the event. To be notified of an event, an application must provide an implementation of the listener class and must register it on the component that generates the event. When the user activates a component, such as by clicking a button, an event is fired. This causes the JavaServer Faces implementation to invoke the listener method that processes the event.

JavaServer Faces supports two kinds of application events: action events and value-change events.

An action event (class javax.faces.event.ActionEvent) occurs when the user activates a component that implements ActionSource. These components include buttons and links.

A value-change event (class javax.faces.event.ValueChangeEvent) occurs when the user changes the value of a component represented by UIInputor one of its subclasses. An example is selecting a check box, an action that results in the component’s value changing to true. The component types that can generate these types of events are the UIInput,UISelectOne, UISelectMany, and UISelectBoolean components. Value-change events are fired only if no validation errors are detected.

Depending on the value of the immediate property (seeThe immediate Attribute) of the component emitting the event, action events can be processed during the Invoke Application phase or the Apply Request Values phase, and value-change events can be processed during the Process Validations phase or the Apply Request Values phase.

System events are generated by an Object rather than a UIComponent. They are generated during the execution of an application at predefined times. They are applicable to the entire application rather than to a specific component.

A data-model event occurs when a new row of a UIData component is selected.

There are two ways to cause your application to react to action events or value-change events that are emitted by a standard component:

• Implement an event listener class to handle the event, and register the listener on the component by nesting either anf:valueChangeListener tag or an f:actionListener tag inside the component tag.
• Implement a method of a managed bean to handle the event, and refer to the method with a method expression from the appropriate attribute of the component’s tag.

When emitting events from custom components, you must implement the appropriate event class and manually queue the event on the component in addition to implementing an event listener class or a managed bean method that handles the event. Handling Events for Custom Components explains how to do this.

Validation Model

JavaServer Faces technology supports a mechanism for validating the local data of editable components (such as text fields). This validation occurs before the corresponding model data is updated to match the local value.

Like the conversion model, the validation model defines a set of standard classes for performing common data validation checks. The JavaServer Faces core tag library also defines a set of tags that correspond to the standard javax.faces.validator.Validatorimplementations. See Using the Standard Validators for a list of all the standard validation classes and corresponding tags.

Most of the tags have a set of attributes for configuring the validator’s properties, such as the minimum and maximum allowable values for the component’s data. The page author registers the validator on a component by nesting the validator’s tag within the component’s tag.

In addition to validators that are registered on the component, you can declare a default validator that is registered on all UIInputcomponents in the application. For more information on default validators, see Using Default Validators.

The validation model also allows you to create your own custom validator and corresponding tag to perform custom validation. The validation model provides two ways to implement custom validation.

• Implement a Validator interface that performs the validation.
• Implement a managed bean method that performs the validation.

If you are implementing a Validator interface, you must also do the following.

• Register the Validator implementation with the application.
• Create a custom tag or use an f:validator tag to register the validator on the component.