Composer"
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=Custom Controller= | =Custom Controller= | ||
− | A custom controller is called a composer in ZK. To implement it, you | + | A custom controller is called a composer in ZK. To implement it, you can simply extend <javadoc>org.zkoss.zk.ui.select.SelectorComposer</javadoc>. Then, specify it in the UI element that it wants to handle in a ZUML document. |
− | + | A composer usually does, but not limited to: | |
− | * | + | *Load data to components, if necessary. |
− | *Handle events and manipulate components if necessary. | + | *Handle events and manipulate components accordingly, if necessary. |
+ | *Provide the data, if necessary. | ||
− | In | + | In addition, a composer can be used to involve the lifecycle of ZK Loader for doing: |
*Exception handling | *Exception handling | ||
− | *Component | + | *Component instantiation monitoring and filtering |
− | A composer be configured as system-level, such that it will be called | + | A composer can be [[ZK Configuration Reference/zk.xml/The listener Element/The org.zkoss.zk.ui.util.Composer interface|configured as a system-level composer]], such that it will be called each time a ZUML document is loaded. |
==Implement Composers== | ==Implement Composers== | ||
− | + | To simplify the implementation of the controller part of UI, ZK provides several skeleton implementations. For example, <javadoc>org.zkoss.zk.ui.select.SelectorComposer</javadoc>, as one of the most popular skeletons, wires components, variables and event listeners automatically based on Java annotations you specify. For example, in the following controller and zul, | |
− | + | Controller: | |
− | + | <source lang="java" line highlight='9-12,14-15,18-19'> | |
− | |||
− | |||
− | <source lang="java"> | ||
package foo; | package foo; | ||
− | import org.zkoss.zk.ui. | + | import org.zkoss.zk.ui.select.SelectorComposer; |
− | import org.zkoss.zk.ui. | + | import org.zkoss.zk.ui.select.annotation.Wire; |
+ | import org.zkoss.zk.ui.select.annotation.Listen; | ||
import org.zkoss.zul.*; | import org.zkoss.zul.*; | ||
− | public class MyComposer extends | + | public class MyComposer extends SelectorComposer<Window> { |
− | |||
− | |||
− | + | @Wire | |
− | + | Textbox input; | |
− | + | @Wire | |
− | + | Label output; | |
− | + | ||
− | + | @Listen("onClick=#ok") | |
+ | public void submit() { | ||
+ | output.setValue(input.getValue()); | ||
+ | } | ||
+ | @Listen("onClick=#cancel") | ||
+ | public void cancel() { | ||
+ | output.setValue(""); | ||
+ | } | ||
+ | |||
} | } | ||
</source> | </source> | ||
+ | * Line: 9-12: The member fields <code>input</code>, <code>output</code> are automatically assigned with components with identifiers of "input" and "output", respectively. | ||
+ | * Line 14-21: The methods <code>submit()</code> and <code>cancel()</code> will be called when user clicks on the corresponding buttons. | ||
+ | |||
+ | ZUL: | ||
+ | <source lang="XML" highlight='1'> | ||
+ | <window apply="foo.MyComposer"> | ||
+ | <div> | ||
+ | Input: <textbox id="input" /> | ||
+ | </div> | ||
+ | <div> | ||
+ | Output: <label id="output" /> | ||
+ | </div> | ||
+ | <button id="ok" label="Submit" /> | ||
+ | <button id="cancel" label="Clear" /> | ||
+ | </window> | ||
+ | </source> | ||
+ | |||
+ | |||
+ | In addition to wiring components via identifiers, you could wire by a CSS3-like selector (<javadoc>org.zkoss.zk.ui.select.Selector</javadoc>), such as | ||
+ | |||
+ | * <code>@Wire("#foo")</code> | ||
+ | * <code>@Wire("textbox, intbox, decimalbox, datebox")</code> | ||
+ | * <code>@Wire("window > div > button")</code> | ||
− | + | * <code>@Listen("onClick = button[label='Clear']")</code> | |
+ | |||
+ | For more information, please refer to the following sections: [[ZK Developer's Reference/MVC/Controller/Wire Components|Wire Components]], [[ZK Developer's Reference/MVC/Controller/Wire Variables|Wire Variables]] and [[ZK Developer's Reference/MVC/Controller/Wire Event Listeners|Wire Event Listeners]]. | ||
==Apply Composers== | ==Apply Composers== | ||
− | Once a composer is implemented, you | + | Once a composer is implemented, you usually associate it with a component, so that the composer can control the associated components and its child components. |
Associating a composer to a component is straightforward: just specify the class to [[ZUML Reference/ZUML/Attributes/apply|the apply attribute]] of the XML element you want to control. For example, | Associating a composer to a component is straightforward: just specify the class to [[ZUML Reference/ZUML/Attributes/apply|the apply attribute]] of the XML element you want to control. For example, | ||
− | <source lang="xml"> | + | <source lang="xml" highlight="1"> |
<grid apply="foo.MyComposer"> | <grid apply="foo.MyComposer"> | ||
<rows> | <rows> | ||
Line 62: | Line 92: | ||
</source> | </source> | ||
− | |||
− | <source lang=" | + | ===Applying Multiple Composers=== |
− | + | ||
− | + | You could specify multiple composers; just separate them with commas. They will be called from left to right. | |
− | + | ||
− | } | + | <source lang="xml"> |
+ | <div apply="foo.Composer1, foo2.Composer2"> | ||
+ | </source> | ||
+ | |||
+ | ===Apply Composer Instances=== | ||
+ | In addition to the class name, you could specify an instance too. For example, suppose you have an instance called <code>fooComposer</code>, then | ||
+ | |||
+ | <source lang="xml"> | ||
+ | <grid apply="${fooComposer}"> | ||
</source> | </source> | ||
− | + | If a class name is specified, each time the component is instantiated, an instance of the specified composer class is instantiated too. Thus, you don't have to worry about the concurrency issue. However, if you specify an instance, it will be used directly. Thus, you have to either create an instance for each request, or make it thread-safe. | |
− | == | + | ==Retrieve Composer in EL Expressions== |
+ | If you have to retrieve the composer back later (such as reference it in an EL expression), you can store the composer into a component's attribute<ref>It can be done by invoking <javadoc method="setAttribute(java.lang.String, java.lang.Object)" type="interface">org.zkoss.zk.ui.Component</javadoc>, because the component's attribute can be referenced directly in EL expressions. Notice that if you want to reference it in EL expressions, you'd set the attribute in <javadoc method="doBeforeComposeChildren(T)" type="interface">org.zkoss.zk.ui.util.ComposerExt</javadoc> because <javadoc method="doAfterCompose(T)" type="interface">org.zkoss.zk.ui.util.Composer</javadoc> was called after all child components were instantiated.</ref>. | ||
− | If you could | + | If the composer extends from one of ZK skeletal implementations (such as <javadoc>org.zkoss.zk.ui.select.SelectorComposer</javadoc> and <javadoc>org.zkoss.zk.ui.util.GenericForwardComposer</javadoc>), it will be stored into an attribute automatically. Thus, for the sake of convenience, you could extend from one of these classes, if you'd like to retrieve the composer back. |
+ | |||
+ | Every ZK skeletal implementation provides several ways to name the composer as described in the following sections. | ||
+ | |||
+ | <blockquote> | ||
+ | ---- | ||
+ | <references/> | ||
+ | </blockquote> | ||
+ | |||
+ | ===Default Names of Composer=== | ||
+ | |||
+ | If a composer extends from one of ZK skeletal implementations (such as <javadoc>org.zkoss.zk.ui.select.SelectorComposer</javadoc> and <javadoc>org.zkoss.zk.ui.util.GenericForwardComposer</javadoc>), the composer is stored in three component attributes called: | ||
+ | * <code>$composer</code> | ||
+ | * <code>''id''$composer</code> | ||
+ | * <code>''id''$''ClassName''</code>, where ''id'' is the component's ID, and ''ClassName'' is the class name of the composer. If ID is not assigned, it defaults to an empty string, so the composer will be stored to two component attributes: <code>$composer</code> and <code>$''ClassName''</code>. | ||
+ | |||
+ | |||
+ | Therefore, you can access the composer with one of the above variables e.g. | ||
<source lang="xml"> | <source lang="xml"> | ||
− | < | + | <window id="mywin" apply="MyComposer"> |
+ | <textbox value="${mywin$composer.title}"/> | ||
+ | <textbox value="${$composer.title}"/> <!- also refer to MyComposer --> | ||
+ | </window> | ||
+ | </source> | ||
+ | |||
+ | Notice that <code>$composer</code> is always assigned no matter what the ID is, so it is more convenient to use. However, if there are several components assigned with composers, you might have to use ID to distinguish them. | ||
+ | |||
+ | The second name (<code>''id''$''ClassName''</code>) is useful, if there are multiple composers applied. | ||
+ | |||
+ | <source lang="xml"> | ||
+ | <window apply="foo.Handle1, foo.Handle2"> | ||
+ | <textbox value="${$Handle1.title}"/> | ||
+ | <textbox value="${$Handle2.name}"/> | ||
+ | </window> | ||
</source> | </source> | ||
− | + | ===Specify Name for Composer=== | |
+ | |||
+ | If you prefer to name the composer by yourself, you could specify the name in a component attribute called <code>composerName</code>. For example, | ||
<source lang="xml"> | <source lang="xml"> | ||
− | < | + | <window apply="MyComposer"> |
+ | <custom-attributes composerName="mc"/> <!-- name the composer as mc --> | ||
+ | |||
+ | <textbox value="${mc.title}"/> | ||
+ | </window> | ||
</source> | </source> | ||
− | + | == Prepare Data for EL Expressions in Composer == | |
+ | It is a common practice to prepare some data in a composer, such that those data are available when rendering the child components. As described above, the composer will be stored as a component attribute that is accessible directly in EL expressions. Thus, you could provide the data easily by declaring a public getter method. For example, | ||
− | = | + | <source lang="java" highlight="2"> |
+ | public class UsersComposer extends org.zkoss.zk.ui.select.SelectorComposer<Window> { | ||
+ | public ListModel<User> getUsers() { | ||
+ | //return a collection of users | ||
+ | } | ||
+ | } | ||
+ | </source> | ||
− | + | Then, you could access it as follows. | |
− | == | + | <source lang="xml" highlight="2"> |
+ | <window title="User List" border="normal" apply="foo.UsersComposer"> | ||
+ | <grid model="${$composer.users}> | ||
+ | ... | ||
+ | </source> | ||
− | + | ===Wire Spring-managed beans=== | |
+ | Here is another example that we wire Spring-managed beans with the <javadoc type="interface">org.zkoss.zk.ui.select.WireVariable</javadoc> annotation. | ||
− | + | <source lang="java" highlight="1,3"> | |
+ | @VariableResolver(org.zkoss.zkplus.spring.DelegatingVariableResolver.class) | ||
+ | public class UsersComposer extends SelectorComposer<Window> { | ||
+ | @WireVariable | ||
+ | private List<User> users; | ||
− | < | + | public ListModel<User> getUsers() { |
− | + | return new ListModelList<User>(users); | |
− | |||
− | return | ||
} | } | ||
} | } | ||
</source> | </source> | ||
− | + | where we register a variable resolver called <javadoc>org.zkoss.zkplus.spring.DelegatingVariableResolver</javadoc> with the <javadoc type="interface">org.zkoss.zk.ui.select.VariableResolver</javadoc> annotation. As its name suggests, <javadoc>org.zkoss.zkplus.spring.DelegatingVariableResolver</javadoc> will be used to retrieve Spring-managed beans when <code>@WireVariable</code> is encountered. For more information, please refer to [[ZK Developer's Reference/MVC/Controller/Wire Variables|the Wire Variables section]]. | |
+ | |||
+ | Notice that the variables will be wired before instantiating the component and its children, so it is OK to access them in the ZUML document, as below. | ||
+ | |||
+ | <source lang="xml"> | ||
+ | <window title="User List" border="normal" apply="foo.UsersComposer"> | ||
+ | <grid model="${$composer.users}> | ||
+ | ... | ||
+ | </source> | ||
<blockquote> | <blockquote> | ||
Line 114: | Line 211: | ||
</blockquote> | </blockquote> | ||
− | == | + | =Composer with More Control= |
+ | |||
+ | A composer could also handle the exceptions, if any, control the life cycle of rendering, and intercept how a child component is instantiated. It can be done by implementing the corresponding interfaces, <javadoc type="interface">org.zkoss.zk.ui.util.ComposerExt</javadoc> and/or <javadoc type="interface">org.zkoss.zk.ui.util.FullComposer</javadoc>. | ||
+ | |||
+ | == Initialize Components == | ||
+ | |||
+ | If you want to initialize a component's properties with some default values, after ZK creates it, you should override <javadoc method="doAfterCompose(T)">org.zkoss.zk.ui.select.SelectorComposer</javadoc>. | ||
+ | |||
+ | <syntaxhighlight lang="java" line highlight='3'> | ||
+ | public class MyComposer extends SelectorComposer<Grid> { | ||
+ | public void doAfterCompose(Grid comp) { | ||
+ | super.doAfterCompose(comp); //wire variables and event listeners | ||
+ | //initialize wired components here e.g. myLabel.setValue("default value") | ||
+ | } | ||
+ | ... | ||
+ | </syntaxhighlight> | ||
+ | * Line 2: The passed argument, <code>comp</code>, is the component that the composer is applied to. In this example, it is the grid. As the name indicates, <code>doAfterCompose</code> is called after the grid and all its descendants are instantiated. | ||
+ | * Line 3: Calling <code>super.doAfterCompose(comp)</code> first is required to make <code>@Wire</code> and <code>@Listen</code> work. | ||
− | + | == Exception and Lifecycle Handling with ComposerExt == | |
− | + | If you want a composer to handle the exception and/or control the life cycle of rendering, you could also implement <javadoc type="interface">org.zkoss.zk.ui.util.ComposerExt</javadoc>. Since <javadoc>org.zkoss.zk.ui.select.SelectorComposer</javadoc> already implements this interface, you only need to override the method you care about if you extend from it. | |
− | For example, | + | For example, we could handle the exception by overriding <javadoc method="doCatch(java.lang.Throwable)">org.zkoss.zk.ui.util.ComposerExt</javadoc> and/or <javadoc method="doFinally()">org.zkoss.zk.ui.util.ComposerExt</javadoc>. |
<source lang="java"> | <source lang="java"> | ||
− | < | + | public class MyComposer<T extends Component> extends SelectorComposer<T> { |
− | + | public boolean doCatch(Throwable ex) { | |
− | + | return ignorable(ex); //return true if ex could be ignored | |
− | + | } | |
− | + | } | |
− | |||
</source> | </source> | ||
− | + | For involving the life cycle, you could override <javadoc method="doBeforeCompose(org.zkoss.zk.ui.Page, org.zkoss.zk.ui.Component, org.zkoss.zk.ui.metainfo.ComponentInfo)" type="interface">org.zkoss.zk.ui.util.ComposerExt</javadoc> and/or <javadoc method="doBeforeComposeChildren(T)" type="interface">org.zkoss.zk.ui.util.ComposerExt</javadoc>. | |
− | + | <blockquote> | |
+ | ---- | ||
+ | <references/> | ||
+ | </blockquote> | ||
− | + | == Fine-grained Full Control with FullComposer == | |
− | + | In addition to controlling the given component, a composer can monitor the instantiation and exceptions for each child and the descendant component. It is done by implementing <javadoc type="interface">org.zkoss.zk.ui.util.FullComposer</javadoc>. <javadoc>org.zkoss.zk.ui.select.SelectorComposer</javadoc> does not implement this interface by default. Thus, you have to implement it explicitly. | |
− | + | There is no implementation method needed for this interface. It is like a decorative interface to indicate that it requires the fine-grained full control. In other words, all methods declared in <javadoc type="interface">org.zkoss.zk.ui.util.Composer</javadoc> and <javadoc type="interface">org.zkoss.zk.ui.util.ComposerExt</javadoc> will be invoked one-by-one against each child and the descendant component. | |
− | |||
− | < | + | For example, suppose we have a composer implementing both <javadoc type="interface">org.zkoss.zk.ui.util.Composer</javadoc> and <javadoc type="interface">org.zkoss.zk.ui.util.FullComposer</javadoc>, and it is assigned as followed |
− | |||
− | |||
− | </ | ||
− | |||
− | |||
− | |||
<source lang="xml"> | <source lang="xml"> | ||
− | < | + | <panel apply="foo.MyFullComposer"> |
− | + | <panelchildren> | |
− | + | <div> | |
− | </ | + | <datebox/> |
+ | <textbox/> | ||
+ | </div> | ||
+ | </panelchildren> | ||
+ | </panel> | ||
</source> | </source> | ||
− | + | Then, <javadoc type="interface" method="doAfterCompose(T)">org.zkoss.zk.ui.util.Composer</javadoc> will be called for datebox, textbox, div and then panel (in the order of ''child-first-parent-last''). If <javadoc type="interface">org.zkoss.zk.ui.util.FullComposer</javadoc> is not implemented, only the panel will be called. | |
− | |||
− | + | Notice that, because <javadoc type="interface" method="doAfterCompose(T)">org.zkoss.zk.ui.util.Composer</javadoc> will be called for each child, the generic type should be <javadoc type="interface">org.zkoss.zk.ui.Component</javadoc> rather than the component's type to which the composer is applied. For example, | |
− | |||
− | <source lang="java | + | <source lang="java"> |
− | public class | + | public class MyFullComposer extends SelectorComposer<Component> implements FullComposer { |
− | + | ... | |
− | |||
− | |||
− | |||
− | |||
</source> | </source> | ||
− | + | == Lifecycle == | |
− | + | Here is a lifecycle of the invocation of a composer: | |
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | + | [[Image:Composer.PNG]] | |
=System-level Composer= | =System-level Composer= | ||
− | + | If you have a composer that shall be invoked for every page, you can register a system-level composer rather than applying it on every page. For example, handling logout logic, or receiving a common event fired by every page. | |
− | + | To register it, specify the composer you implemented in <code>WEB-INF/zk.xml</code>: | |
<source lang="xml"> | <source lang="xml"> | ||
Line 195: | Line 296: | ||
</listener> | </listener> | ||
</source> | </source> | ||
+ | For more information, please refer to [[ZK Configuration Reference/zk.xml/The listener Element|ZK Configuration Reference/zk.xml]]. | ||
− | Each time a ZK page, including ZK pages and richlets, is created, ZK will instantiate one instance for each registered system-level composer and | + | Each time a ZK page, including ZK pages and richlets, is created, ZK will instantiate one instance for each registered system-level composer and then invoke <javadoc method="doAfterCompose(T)" type="interface">org.zkoss.zk.ui.util.Composer</javadoc> for each root component. The system-level composer is usually used to process ZK pages after all components are instantiated successfully, such as adding a trademark. If you want to process only certain pages, you can check the request path by calling <javadoc method="getRequestPath()" type="interface">org.zkoss.zk.ui.Desktop</javadoc> (the desktop instance can be found through the given component). |
If the system-level composer also implements <javadoc type="interface">org.zkoss.zk.ui.util.ComposerExt</javadoc>, it can be used to handle more situations, such as exceptions, like any other composer can do. | If the system-level composer also implements <javadoc type="interface">org.zkoss.zk.ui.util.ComposerExt</javadoc>, it can be used to handle more situations, such as exceptions, like any other composer can do. | ||
Line 202: | Line 304: | ||
If the system-level composer also implements <javadoc type="interface">org.zkoss.zk.ui.util.FullComposer</javadoc>, it will be invoked when each component is created. It provides the finest grain of control but a wrong implementation might degrade the performance. | If the system-level composer also implements <javadoc type="interface">org.zkoss.zk.ui.util.FullComposer</javadoc>, it will be invoked when each component is created. It provides the finest grain of control but a wrong implementation might degrade the performance. | ||
− | Notice that since a new instance of the composer is created for each page, there | + | Notice that since a new instance of the composer is created for each page, there are no concurrency issues. |
− | |||
− | |||
− | |||
== Richlet == | == Richlet == | ||
− | A system-level composer can implement <javadoc type="interface">org.zkoss.zk.ui.util.ComposerExt</javadoc> to handle exceptions for a richlet, such as < | + | A system-level composer can implement <javadoc type="interface">org.zkoss.zk.ui.util.ComposerExt</javadoc> to handle exceptions for a richlet, such as <code>doCatch</code> and <code>doFinally</code>. However, <code>doBeforeCompose</code> and <code>doBeforeComposeChildren</code> won't be called. |
− | <javadoc type="interface">org.zkoss.zk.ui.util.FullComposer</javadoc> is not applicable to richlets. In other words, system-level composers are called only for | + | <javadoc type="interface">org.zkoss.zk.ui.util.FullComposer</javadoc> is not applicable to richlets. In other words, system-level composers are called only for root components. |
=Version History= | =Version History= | ||
− | + | ||
− | {| | + | {| class='wikitable' | width="100%" |
! Version !! Date !! Content | ! Version !! Date !! Content | ||
|- | |- | ||
− | | | + | | 5.0.8 |
− | | | + | | June, 2011 |
− | | | + | | <javadoc>org.zkoss.zk.ui.util.GenericAutowireComposer</javadoc> and its derives allow developers to specify a custom name by use of a component attribute called <code>composerName</code>. |
|} | |} | ||
{{ZKDevelopersReferencePageFooter}} | {{ZKDevelopersReferencePageFooter}} |
Latest revision as of 04:17, 29 January 2024
Custom Controller
A custom controller is called a composer in ZK. To implement it, you can simply extend SelectorComposer. Then, specify it in the UI element that it wants to handle in a ZUML document.
A composer usually does, but not limited to:
- Load data to components, if necessary.
- Handle events and manipulate components accordingly, if necessary.
- Provide the data, if necessary.
In addition, a composer can be used to involve the lifecycle of ZK Loader for doing:
- Exception handling
- Component instantiation monitoring and filtering
A composer can be configured as a system-level composer, such that it will be called each time a ZUML document is loaded.
Implement Composers
To simplify the implementation of the controller part of UI, ZK provides several skeleton implementations. For example, SelectorComposer, as one of the most popular skeletons, wires components, variables and event listeners automatically based on Java annotations you specify. For example, in the following controller and zul,
Controller:
1 package foo;
2 import org.zkoss.zk.ui.select.SelectorComposer;
3 import org.zkoss.zk.ui.select.annotation.Wire;
4 import org.zkoss.zk.ui.select.annotation.Listen;
5 import org.zkoss.zul.*;
6
7 public class MyComposer extends SelectorComposer<Window> {
8
9 @Wire
10 Textbox input;
11 @Wire
12 Label output;
13
14 @Listen("onClick=#ok")
15 public void submit() {
16 output.setValue(input.getValue());
17 }
18 @Listen("onClick=#cancel")
19 public void cancel() {
20 output.setValue("");
21 }
22
23 }
- Line: 9-12: The member fields
input
,output
are automatically assigned with components with identifiers of "input" and "output", respectively. - Line 14-21: The methods
submit()
andcancel()
will be called when user clicks on the corresponding buttons.
ZUL:
<window apply="foo.MyComposer">
<div>
Input: <textbox id="input" />
</div>
<div>
Output: <label id="output" />
</div>
<button id="ok" label="Submit" />
<button id="cancel" label="Clear" />
</window>
In addition to wiring components via identifiers, you could wire by a CSS3-like selector (Selector), such as
@Wire("#foo")
@Wire("textbox, intbox, decimalbox, datebox")
@Wire("window > div > button")
@Listen("onClick = button[label='Clear']")
For more information, please refer to the following sections: Wire Components, Wire Variables and Wire Event Listeners.
Apply Composers
Once a composer is implemented, you usually associate it with a component, so that the composer can control the associated components and its child components.
Associating a composer to a component is straightforward: just specify the class to the apply attribute of the XML element you want to control. For example,
<grid apply="foo.MyComposer">
<rows>
<row>
<textbox id="input"/>
<button label="Submit" id="submit"/>
<button label="Reset" id="reset"/>
</row>
</rows>
</grid>
Applying Multiple Composers
You could specify multiple composers; just separate them with commas. They will be called from left to right.
<div apply="foo.Composer1, foo2.Composer2">
Apply Composer Instances
In addition to the class name, you could specify an instance too. For example, suppose you have an instance called fooComposer
, then
<grid apply="${fooComposer}">
If a class name is specified, each time the component is instantiated, an instance of the specified composer class is instantiated too. Thus, you don't have to worry about the concurrency issue. However, if you specify an instance, it will be used directly. Thus, you have to either create an instance for each request, or make it thread-safe.
Retrieve Composer in EL Expressions
If you have to retrieve the composer back later (such as reference it in an EL expression), you can store the composer into a component's attribute[1].
If the composer extends from one of ZK skeletal implementations (such as SelectorComposer and GenericForwardComposer), it will be stored into an attribute automatically. Thus, for the sake of convenience, you could extend from one of these classes, if you'd like to retrieve the composer back.
Every ZK skeletal implementation provides several ways to name the composer as described in the following sections.
- ↑ It can be done by invoking Component.setAttribute(String, Object), because the component's attribute can be referenced directly in EL expressions. Notice that if you want to reference it in EL expressions, you'd set the attribute in ComposerExt.doBeforeComposeChildren(T) because Composer.doAfterCompose(T) was called after all child components were instantiated.
Default Names of Composer
If a composer extends from one of ZK skeletal implementations (such as SelectorComposer and GenericForwardComposer), the composer is stored in three component attributes called:
$composer
id$composer
id$ClassName
, where id is the component's ID, and ClassName is the class name of the composer. If ID is not assigned, it defaults to an empty string, so the composer will be stored to two component attributes:$composer
and$ClassName
.
Therefore, you can access the composer with one of the above variables e.g.
<window id="mywin" apply="MyComposer">
<textbox value="${mywin$composer.title}"/>
<textbox value="${$composer.title}"/> <!- also refer to MyComposer -->
</window>
Notice that $composer
is always assigned no matter what the ID is, so it is more convenient to use. However, if there are several components assigned with composers, you might have to use ID to distinguish them.
The second name (id$ClassName
) is useful, if there are multiple composers applied.
<window apply="foo.Handle1, foo.Handle2">
<textbox value="${$Handle1.title}"/>
<textbox value="${$Handle2.name}"/>
</window>
Specify Name for Composer
If you prefer to name the composer by yourself, you could specify the name in a component attribute called composerName
. For example,
<window apply="MyComposer">
<custom-attributes composerName="mc"/> <!-- name the composer as mc -->
<textbox value="${mc.title}"/>
</window>
Prepare Data for EL Expressions in Composer
It is a common practice to prepare some data in a composer, such that those data are available when rendering the child components. As described above, the composer will be stored as a component attribute that is accessible directly in EL expressions. Thus, you could provide the data easily by declaring a public getter method. For example,
public class UsersComposer extends org.zkoss.zk.ui.select.SelectorComposer<Window> {
public ListModel<User> getUsers() {
//return a collection of users
}
}
Then, you could access it as follows.
<window title="User List" border="normal" apply="foo.UsersComposer">
<grid model="${$composer.users}>
...
Wire Spring-managed beans
Here is another example that we wire Spring-managed beans with the WireVariable annotation.
@VariableResolver(org.zkoss.zkplus.spring.DelegatingVariableResolver.class)
public class UsersComposer extends SelectorComposer<Window> {
@WireVariable
private List<User> users;
public ListModel<User> getUsers() {
return new ListModelList<User>(users);
}
}
where we register a variable resolver called DelegatingVariableResolver with the VariableResolver annotation. As its name suggests, DelegatingVariableResolver will be used to retrieve Spring-managed beans when @WireVariable
is encountered. For more information, please refer to the Wire Variables section.
Notice that the variables will be wired before instantiating the component and its children, so it is OK to access them in the ZUML document, as below.
<window title="User List" border="normal" apply="foo.UsersComposer">
<grid model="${$composer.users}>
...
Composer with More Control
A composer could also handle the exceptions, if any, control the life cycle of rendering, and intercept how a child component is instantiated. It can be done by implementing the corresponding interfaces, ComposerExt and/or FullComposer.
Initialize Components
If you want to initialize a component's properties with some default values, after ZK creates it, you should override SelectorComposer.doAfterCompose(T).
1 public class MyComposer extends SelectorComposer<Grid> {
2 public void doAfterCompose(Grid comp) {
3 super.doAfterCompose(comp); //wire variables and event listeners
4 //initialize wired components here e.g. myLabel.setValue("default value")
5 }
6 ...
- Line 2: The passed argument,
comp
, is the component that the composer is applied to. In this example, it is the grid. As the name indicates,doAfterCompose
is called after the grid and all its descendants are instantiated. - Line 3: Calling
super.doAfterCompose(comp)
first is required to make@Wire
and@Listen
work.
Exception and Lifecycle Handling with ComposerExt
If you want a composer to handle the exception and/or control the life cycle of rendering, you could also implement ComposerExt. Since SelectorComposer already implements this interface, you only need to override the method you care about if you extend from it.
For example, we could handle the exception by overriding ComposerExt.doCatch(Throwable) and/or ComposerExt.doFinally().
public class MyComposer<T extends Component> extends SelectorComposer<T> {
public boolean doCatch(Throwable ex) {
return ignorable(ex); //return true if ex could be ignored
}
}
For involving the life cycle, you could override ComposerExt.doBeforeCompose(Page, Component, ComponentInfo) and/or ComposerExt.doBeforeComposeChildren(T).
Fine-grained Full Control with FullComposer
In addition to controlling the given component, a composer can monitor the instantiation and exceptions for each child and the descendant component. It is done by implementing FullComposer. SelectorComposer does not implement this interface by default. Thus, you have to implement it explicitly.
There is no implementation method needed for this interface. It is like a decorative interface to indicate that it requires the fine-grained full control. In other words, all methods declared in Composer and ComposerExt will be invoked one-by-one against each child and the descendant component.
For example, suppose we have a composer implementing both Composer and FullComposer, and it is assigned as followed
<panel apply="foo.MyFullComposer">
<panelchildren>
<div>
<datebox/>
<textbox/>
</div>
</panelchildren>
</panel>
Then, Composer.doAfterCompose(T) will be called for datebox, textbox, div and then panel (in the order of child-first-parent-last). If FullComposer is not implemented, only the panel will be called.
Notice that, because Composer.doAfterCompose(T) will be called for each child, the generic type should be Component rather than the component's type to which the composer is applied. For example,
public class MyFullComposer extends SelectorComposer<Component> implements FullComposer {
...
Lifecycle
Here is a lifecycle of the invocation of a composer:
System-level Composer
If you have a composer that shall be invoked for every page, you can register a system-level composer rather than applying it on every page. For example, handling logout logic, or receiving a common event fired by every page.
To register it, specify the composer you implemented in WEB-INF/zk.xml
:
<listener>
<listener-class>foo.MyComposer</listener-class>
</listener>
For more information, please refer to ZK Configuration Reference/zk.xml.
Each time a ZK page, including ZK pages and richlets, is created, ZK will instantiate one instance for each registered system-level composer and then invoke Composer.doAfterCompose(T) for each root component. The system-level composer is usually used to process ZK pages after all components are instantiated successfully, such as adding a trademark. If you want to process only certain pages, you can check the request path by calling Desktop.getRequestPath() (the desktop instance can be found through the given component).
If the system-level composer also implements ComposerExt, it can be used to handle more situations, such as exceptions, like any other composer can do.
If the system-level composer also implements FullComposer, it will be invoked when each component is created. It provides the finest grain of control but a wrong implementation might degrade the performance.
Notice that since a new instance of the composer is created for each page, there are no concurrency issues.
Richlet
A system-level composer can implement ComposerExt to handle exceptions for a richlet, such as doCatch
and doFinally
. However, doBeforeCompose
and doBeforeComposeChildren
won't be called.
FullComposer is not applicable to richlets. In other words, system-level composers are called only for root components.
Version History
Version | Date | Content |
---|---|---|
5.0.8 | June, 2011 | GenericAutowireComposer and its derives allow developers to specify a custom name by use of a component attribute called composerName .
|