Chapter 22. Spring.NET Web Framework

22.1. Introduction to Spring.NET Web Framework

The Spring.NET Web Framework increases your productivity when you write ASP.NET WebForms applications by offering capabilities not found in other .NET web frameworks.

The Spring.NET Web Framework makes it easy to write 'thin and clean' web applications. "Thin" refers to WebForm's role as a small as possible adapter between the HTML- based world of the web and the Object-oriented world of your application. The business logic does not reside in the web tier; it resides in the application layer with which your web form communicates. "Clean" refers to the framework's appropriate separation of concerns, separating web specific processing such as copying data out and into from element from a data model from calling into a buiness tier and redirecting to the next page. This results in an event-handler that does not contain any reference to UI elements thereby making it possible to test your event handler code in integration style tests. The Spring.NET Web Framework reduces the incidental complexity of common tasks in the web tier, for example, the conversion of HTML control data to objects and then vice-versa after the request is processed by the application layer.

Highlights of Spring's Web framework are:

  • Dependency Injection. Provided for all ASP.NET artifacts, inlcuding pages and user controls, modules, providers, and HTTP handlers. Your pages, controls, and so on do not require any dependency on Spring in order to be configured via dependency injection.

  • Bidirectional data binding. Allows you to declaratively define the data that will be marshaled out of your HTML and user controls and into a data model that in turn is generally submitted to the application layer. After the data model is updated in the application layer, those changes are automatically reflected in the HTML and user controls on post back. This process removes large amounts of tedious, error-prone boilerplate code.

  • Web object scopes. Can be defined at the application, session, or request scope. This capability makes it easy to inject, for example, a session scoped shopping cart, into your page without any lower level programming.

  • Data model management. Provides a mechanism similar to view state to help manage your data model. (While ASP.NET manages the view state of your form, it does not offer facilities to manage the data model that you build up to submit to the application layer.)

  • UI-agnostic validation framework. Enables you to declaratively define complex validation rules, for example, that take into account complex relationships in your data model. Spring's error controls easily render validation failure. Thus you can centralize your validation logic and also reuse it on the server side, for example, by using parameter validation advice described in the aspect library chapter.

  • Externalized page navigation through result mapping. Instead of hard-coding URLs and data to direct where a page should go next and what data should be carried along, you can define and configure result mappings externally that associate logical names and a URL (+ data). This capability also allows you to encrypt the values that are sent through Response.Redirect.

  • Improved localization and master page support. Provides advanced localization features (including image localization) and make it easy to declaratively configure which master page to apply to different parts of your web application.

All you know about ASP.NET development still applies. Spring's approach is to 'embrace and extend' the basic ASP.NET programming model to make you as productive as possible.

[Note]Note

Support for ASP.NET MVC is planned for Spring.NET 2.0.

This chapter describes the Spring.NET Web Framework in detail. The framework is not an all-or-nothing solution. For example, you can choose to use only dependency injection and bi-directional data binding. You can adopt the web framework incrementally, addressing problems areas in your current web application with a specific feature.

The Spring.NET distribution ships with a Web Quick Start application and a complete reference application, SpringAir. The Web QuickStart is the best way to learn each Spring.NET Web Framework (also referred to in this document as Spring.Web) feature, by following simple examples. The SpringAir reference application has a Spring.Web-enabled frontend that uses many best practices for Spring.NET web applications, so refer to it as you are reading this (reference) material (see Chapter 41, SpringAir - Reference Application).

22.2. Comparing Spring.NET and ASP.NET

Many developers dislike the ASP.NET programming model because currently it is not a "true MVC" (model-view-controller) implementation; controller-type logic within the page is too tightly coupled to the view. For example, event handlers within the page class typically have references to view elements, such as input controls, in many code behind locations, most typically the event handler. Controller-type logic, such as the code within page event handlers in ASP.NET, should not depend on the view elements.

However, ASP.NET has its good points. Server-side forms and controls make developers significantly more productive and allow you to significantly simplify page markup. They also make cross-browser issues easier to deal with, as each control can make sure that it renders correct markup based on the user's browser. The ability to hook custom logic into the lifecycle of the page, as well as to customize the HTTP processing pipeline, are also very powerful features. The ability to interact with the strongly typed server-side controls instead of manipulating string-based HTTP request collections, such as Form and QueryString, is a much needed layer of abstraction in web development.

Thus, instead of developing a new, pure and true MVC web framework as part of Spring.NET, Spring decided to extend ASP.NET so that most of its shortcomings are eliminated. With the introduction of a 'true MVC framework' to .NET there are several opportunities for integration with IoC containers such as Spring.NET. Furthermore, as Spring for Java has a very popular MVC framework, much of that experience and added value can be transliterated to help developers be more productive when using Spring's future support for ASP.NET MVC.

Spring.Web also supports the application of the dependency injection principle to one's ASP.NET Pages and Controls as well as to HTTP modules and custom provider modules. Thus application developers can easily inject service dependencies into web controllers by leveraging the power of the Spring.NET IoC container. See Dependency Injection for ASP.NET Pages.

Event handlers in code-behind classes should not have to deal with ASP.NET UI controls directly. Such event handlers should rather work with the presentation model of the page, represented either as a hierarchy of domain objects or an ADO.NET DataSet. Spring.NET implemented a bidirectional data binding framework to handle the mapping of values to and from the controls on a page to the underlying data model. The data binding framework also transparently implements data type conversion and formatting, enabling application developers to work with fully typed data (domain) objects in the event handlers of code-behind files. See Bidirectional Data Binding and Model Management.

The Spring.NET Web Framework also addresses concerns about the flow of control through an application. Typical ASP.NET applications use Response.Redirect or Server.Transfer calls within Page logic to navigate to an appropriate page after an action is executed. This usage often leads to hard-coded target URLs in the Page, which is never a good thing. Result mapping solves this problem by allowing application developers to specify aliases for action results that map to target URLs based on information in an external configuration file that can easily be edited. See Result Mapping.

Standard localization support is also limited in versions of ASP.NET prior to ASP.NET 2.0. Even though Visual Studio 2003 generates a local resource file for each ASP.NET Page and user control, those resources are never used by the ASP.NET infrastructure. This means that application developers have to deal directly with resource managers whenever they need access to localized resources, which in the opinion of the Spring.NET team should not be the case. Spring.Web adds comprehensive support for localization using both local resource files and global resources that are configured within and for a Spring.NET container. See Localization and Message Sources.

In addition to the aforementioned core features, Spring.Web ships with lesser features that might be useful to many application developers. Some of these additional features include back-ports of ASP.NET 2.0 features that can be used with ASP.NET 1.1, such as Master Page support. See Master Pages in ASP.NET 1.1 .

To implement some features, the Spring.NET team had to extend (as in the object-oriented sense) the standard ASP.NET Page and UserControl classes. This means that in order to take advantage of the full feature stack of Spring.Web (most notably bidirectional data binding, localization and result mapping), your code-behind classes must extend Spring.Web specific base classes such as Spring.Web.UI.Page. However, powerful features such as dependency injection for ASP.NET Pages, controls, and providers can be leveraged without having to extend Spring.Web-specific base classes. By taking advantage of some of the more useful features offered by Spring.Web, you will be coupling the presentation tier of your application(s) to Spring.Web. The choice of whether or not this is appropriate is, of course, left to you.

22.3. Automatic context loading and hierarchical contexts

22.3.1. Configuration of a web application

Spring.Web builds on top of the Spring.NET IoC container, and makes heavy use (internally) of the easy pluggability and standardized configuration afforded by the IoC container. ASP.NET Pages and UserControls that make up a typical Spring.Web-enabled application are configured with the same standard Spring.NET XML configuration syntax used for non web objects. To integrate with the ASP.NET runtime you need to make a few modifications to your Web.config file.

Spring.Web uses a custom PageHandlerFactory implementation to load and configure a Spring.NET IoC container, which is in turn used to locate an appropriate Page to handle a HTTP request. The WebSupportModule configures miscellaneous Spring infrastructure classes for use in a web environment, for example setting the storage strategy of LogicalThreadContext to be HybridContextStorage.

The instantiation and configuration of the Spring.NET IoC container by the Spring.Web infrastructure is wholly transparent to application developers, who typically never have to explicitly instantiate and configure an IoC container manually (by, for example, using the new operator in C#). To effect the transparent bootstrapping of the IoC container, you need to insert the following configuration snippet into the root Web.config file of every Spring.Web-enabled web application. (You can of course change the verb and path properties from the values that are shown.)

[Note]Note

If you are using the solution templates that ship with Spring.NET this configuration will be done for you automatically whent he solution is created.

<system.web>
    <httpHandlers>
        <add verb="*" path="*.aspx" type="Spring.Web.Support.PageHandlerFactory, Spring.Web"/>
    </httpHandlers>
    <httpModules>
        <add name="Spring" type="Spring.Context.Support.WebSupportModule, Spring.Web"/>
    </httpModules>
    ...
</system.web>

This snippet of standard ASP.NET configuration is only required in the root directory of each Spring.Web web application (that is, in the Web.config file present in the top level virtual directory of an ASP.NET web application).

The above XML configuration snippet directs the ASP.NET infrastructure to use Spring.NET's page factory, which in turn creates instances of the appropriate .aspx Page, possibly injects dependencies into that Page (as required), and then forwards the handling of the request to the Page.

After the Spring.Web page factory is configured, you also need to define a root application context by adding a Spring.NET configuration section to that same Web.config file. The final configuration file should resemble the following; your exact configuration may vary in particulars.

<?xml version="1.0" encoding="utf-8"?>
<configuration>

    <configSections>
        <sectionGroup name="spring">
          <section name="context" type="Spring.Context.Support.WebContextHandler, Spring.Web"/>
        </sectionGroup>
    </configSections>

    <spring>
        <context>
            <resource uri="~/Config/CommonObjects.xml"/>
            <resource uri="~/Config/CommonPages.xml"/>

            <!-- TEST CONFIGURATION -->
            <!--
            <resource uri="~/Config/Test/Services.xml"/>
            <resource uri="~/Config/Test/Dao.xml"/>
            -->

            <!-- PRODUCTION CONFIGURATION -->

            <resource uri="~/Config/Production/Services.xml"/>
            <resource uri="~/Config/Production/Dao.xml"/>

        </context>
    </spring>

    <system.web>
        <httpHandlers>
            <add verb="*" path="*.aspx" type="Spring.Web.Support.PageHandlerFactory, Spring.Web"/>
        </httpHandlers>
        <httpModules>
            <add name="Spring" type="Spring.Context.Support.WebSupportModule, Spring.Web"/>
        </httpModules>
    </system.web>

</configuration>

Notes about the preceding configuration:

  • Define a custom configuration section handler for the <context> element. If you use Spring.NET for many applications on the same web server, it might be easier to move the whole definition of the Spring.NET section group to your machine.config file.

  • The custom configuration section handler is of the type Spring.Context.Support.WebContextHandler which in turn instantiates an IoC container of the type Spring.Context.Support.WebApplicationContext. This ensures that all features provided by Spring.Web, such as request and session-scoped object definitions, are handled properly.

  • Within the <spring> element, define a root context element. Next, specify resource locations that contain the object definitions that are used within the web application (such as service or business tier objects) as child elements within the <context> element. Object definition resources can be fully-qualified paths or URLs, or non-qualified, as in the example above. Non-qualified resources are loaded using the default resource type for the context, which for the WebApplicationContext is the WebResource type.

  • The object definition resources do not have to be the same resource type (for example, all file://, all http://, all assembly://, and so on). This means that you can load some object definitions from resources embedded directly within application assemblies (assembly://) while continuing to load other object definitions from web resources that can be more easily edited.

22.3.1.1. Configuration for IIS 7.0 on Windows Server 2008 and Windows Vista

There is some configuration that is specific to using IIS7, the appropriate code snippit to place in web.config shown below.

<system.webServer>
  <validation validateIntegratedModeConfiguration="false"/>
  <modules>
    <add name="Spring" type="Spring.Context.Support.WebSupportModule, Spring.Web"/>
  </modules>
  <handlers>
    <add name="SpringPageHandler" verb="*" path="*.aspx" type="Spring.Web.Support.PageHandlerFactory, Spring.Web"/>
    <add name="SpringContextMonitor" verb="*" path="ContextMonitor.ashx" type="Spring.Web.Support.ContextMonitor, Spring.Web"/>
  </handlers>
</system.webServer>

22.3.2. Context hierarchy

ASP.NET has a hierarchical configuration mechanism that enables application developers to override configuration settings specified at a higher level in the web application directory hierarchy with configuration settings specified at the lower level.

For example, a web application's root Web.config file overrides settings from the (higher level) machine.config file. In the same fashion, settings specified within the web.config file within a subdirectory of a web application will override settings from the root Web.config and so on. You can also add seettings to lower level Web.config files that were not previously defined anywhere.

Spring.Web leverages this ASP.NET feature to provide support for a context hierarchy. You can add new object definitions to lower level Web.config files or override existing ones per virtual directory.

What this means to application developers is that one can easily componentize an application by creating a virtual directory per component and creating a custom context for each component that contains the necessary configuration info for that particular context. The configuration for a lower level component generally contains only those definitions for the pages that the component consists of and (possibly) overrides for some definitions from the root context (for example, menus).

Because each such lower level component usually contains only a few object definitions, application developers are encouraged to embed those object definitions directly into the Web.config for the lower level context instead of relying on an external resource containing object definitions. This is easily accomplished by creating a component Web.config similar to the following one:

<?xml version="1.0" encoding="utf-8"?>
<configuration>

  <configSections>
    <sectionGroup name="spring">
       <section name="objects" type="Spring.Context.Support.DefaultSectionHandler, Spring.Core"/>
    </sectionGroup>
  </configSections>

  <spring>
    <context type="Spring.Context.Support.WebApplicationContext, Spring.Web">
        <resource uri="config://spring/objects"/>
    </context>

    <objects xmlns="http://www.springframework.net">
        <object type="MyPage.aspx" parent="basePage">
              <property name="MyRootService" ref="myServiceDefinedInRootContext"/>
              <property name="MyLocalService" ref="myServiceDefinedLocally"/>
              <property name="Results">
                 <!-- ... -->
              </property>
        </object>
        <object id="myServiceDefinedLocally" type="MyCompany.MyProject.Services.MyServiceImpl, MyAssembly"/>
    </objects>
  </spring>
</configuration>

The <context/> element seen above (contained within the <spring/> element) simply tells the Spring.NET infrastructure code to load (its) object definitions from the spring/objects section of the web.config configuration file.

If Spring.NET is used for multiple applications on the same server, you can avoid the need to specify the <configSections/> element as shown in the previous example, by moving the configuration handler definition for the <objects> element to a higher level (root) Web.config file, or even to the level of the machine.config file.

This component-level context can reference definitions from its parent context(s). If a referenced object definition is not found in the current context, Spring.NET searches all ancestor contexts in the context hierarchy until it finds the object definition (or ultimately fails and throws an exception).

22.4. Dependency injection for ASP.NET pages

An example of how Spring.Web builds on the capabilities of ASP.NET is the way in which Spring.Web has used the code-behind class of the Page mechanism to satisfy the Controller portion of the MVC architectural pattern. In MVC-based (web) applications, the Controller is typically a thin wrapper around one or more service objects. It is important that service object dependencies be easily injected into Page Controllers. Accordingly, Spring.Web provides first class support for dependency injection in ASP.NET Pages. Application developers can inject any required service object dependencies (and indeed any other dependencies) into their Pages using the standard Spring.NET configuration instead of having to rely on custom service locators or manual object lookups in a Spring.NET application context.

After an application developer configures the Spring.NET web application context, the developer can easily create object definitions for the pages that compose that web application.

<objects xmlns="http://www.springframework.net">

  <object name="basePage" abstract="true">
    <property name="MasterPageFile" value="~/Web/StandardTemplate.master"/>
  </object>

  <object type="Login.aspx">
      <property name="Authenticator" ref="authenticationService"/>
  </object>

  <object type="Default.aspx" parent="basePage"/>

</objects>

The preceding example contains three definitions:

  • An abstract definition for the base page from which many other pages in the application will inherit. In this case, the definition simply specifies which page is to be referenced as the master page, but it typically also configures localization-related dependencies and root folders for images, scripts, and CSS stylesheets.

  • A login page that neither inherits from the base page nor references the master page. This page shows how to inject a service object dependency into a page instance (the authenticationService is defined elsewhere).

  • A default application page that, in this case, simply inherits from the base page in order to inherit the master page dependency, but apart from that it does not need any additional dependency injection configuration.

The configuration of ASP.NET pages differs from the configuration of other .NET classes in the value passed to the type attribute. As can be seen in the above configuration snippet, the type name is actually the path to the .aspx file for the Page, relative to its directory context. When configuring other .NET classes one would specify at minimum the fully qualified type name and the partial assembly name.

In the case of the above example, those definitions are in the root context ,so Login.aspx and Default.aspx files also must be located in the root of the web application's virtual directory. The master page is defined using an absolute path because it could conceivably be referenced from child contexts that are defined within subdirectories of the web application.

The definitions for the Login and Default pages do not specify either of the id and name attributes, in marked contrast to typical object definitions in Spring.NET, where the id or name attributes are usually mandatory (although not always, as in the case of inner object definitions). In the case of Spring.Web manged Page instances, one typically wants to use the name of the .aspx file name as the identifier. If an id is not specified, the Spring.Web infrastructure will simply use the name of the .aspx file as the object identifier (minus any leading path information, and minus the file extension too).

Nothing prevents an application developer from specifying an id or name value explicitly; explicit naming can be useful when, for example, one wants to expose the same page multiple times using a slightly different configuration, such as Add / Edit pages. To use abstract object definitions and have your page inherit from them, use the name attribute instead of the id attribute on the abstract object definition.

22.4.1. Injecting dependencies into controls

Spring.Web also allows application developers to inject dependencies into controls (both user controls and standard controls) that are contained within a page. You can accomplish this globally for all controls of a particular Type by using the location of the .ascx as the object type identifier. This process is similar to injecting into .aspx pages, shown above.

<object type="~/controls/MyControl.ascx" abstract="true">
   <!-- inject dependencies here... -->
</object>
[Note]Note

In either case, be sure to mark the object definition as abstract (by adding abstract="true" to the attribute list of the <object/> element).

22.4.2. Injecting dependencies into custom HTTP modules

You can inject dependencies into custom HTTP modules by using the class Spring.Context.Support.HttpApplicationConfigurer. You register your custom HTTP module as you would normally; for example, a module of the type HtmlCommentAppenderModule, taken from the Web Quick Start, appends additional comments into the http response. It is registered as follows:

<httpModules>
  <add name="HtmlCommentAppender" type="HtmlCommentAppenderModule"/>
</httpModules>

To configure this module, you use naming conventions to identify the module name with configuration instructions in the Spring configuration file. The ModuleTemplates property of HttpApplicationConfigurer is a dictionary that takes as a key the name of the HTTP module, in this case HtmlCommentAppender, and the Spring object definition that describes how to perform dependency injection. The object definition is in the standard <object/> style that you are used to normally when configuring an object with Spring. An example is shown below. HttpApplicationConfigurer' that configures the HtmlCommentAppender's AppendText property.

<object name="HttpApplicationConfigurer" type="Spring.Context.Support.HttpApplicationConfigurer, Spring.Web">
  <property name="ModuleTemplates">
     <dictionary>
       <entry key="HtmlCommentAppender"> <!-- this name must match the module name -->
         <object>
           <!-- select "view source" in your browser on any page to see the appended html comment -->
           <property name="AppendText" value="My configured comment!" />
         </object>
       </entry>
     </dictionary>
  </property>
</object>

You can see this example in action in the Web Quick Start.

22.4.3. Injecting dependencies into HTTP handlers and handler factories

Performing dependency injection on instances of IHttpHandlers and IHttpHandlerFactory allows for a fully Spring-managed <httpHandlers> configuration section. To perform dependency injection onan IHttpHandler or IHttpHandlerFactory, register Spring's MappingHandlerFactory with a specific path or wildcard string (that is, *.aspx) using the standard configuration of an <httpHandler> in web.config. For example:

<system.web>
  <httpHandlers>
    <!--
      the lines below map *any* request ending with *.ashx or *.whatever
      to the global(!) MappingHandlerFactory. Further "specialication"
      of which handler to map to is done within MappingHandlerFactory's configuration -
      use MappingHandlerFactoryConfigurer for this (see below)
    -->
    <add verb="*" path="*.ashx" type="Spring.Web.Support.MappingHandlerFactory, Spring.Web" validate="true"/>
    <add verb="*" path="*.whatever" type="Spring.Web.Support.MappingHandlerFactory, Spring.Web" validate="false"/>
  </httpHandlers>
</system.web>

Spring's MappingHandlerFactory serves a layer of indirection so that you can configure multiple handler mappings with Spring. You do this by configuring a IDictionary HandlerMap property on the class MappingHandlerFactoryConfigurer. The dictionary key is a regular expression that matches the request URL, and the value is a reference to the name of a Spring managed instance of an IHttpHandler or IHttpHandlerFactory . The Spring managed instance is configured via dependency injection using the standard <object/> XML configuraiton schema.

The configuration of MappingHandlerFactoryConfigurer is shown:

<objects xmlns="http://www.springframework.net">

    <!-- configures the global GenericHandlerFactory instance -->
    <object name="mappingHandlerFactoryConfigurer" type="Spring.Web.Support.MappingHandlerFactoryConfigurer, Spring.Web">
        <property name="HandlerMap">
            <dictionary>
                <!-- map any request ending with *.whatever to NoOpHandler -->
                <entry key="\.whatever$" value="myCustomHandler" />
                <entry key="\.ashx$" value="standardHandlerFactory" />
            </dictionary>
        </property>
    </object>

    <object name="standardHandlerFactory" type="Spring.Web.Support.DefaultHandlerFactory, Spring.Web" />

    <!-- defines a standard singleton that will handle *.whatever requests -->
    <object name="myCustomHandler" type="MyCustomHttpHandler, App_Code">
        <property name="MessageText" value="This text is injected via Spring" />
    </object>

    <!--
        used for configuring ~/DemoHandler.ashx custom handler
        note, that this is an abstract definition because 'type' is not specified
    -->
    <object name="DemoHandler.ashx">
        <property name="OutputText">
            <value>This text is injected via Spring</value>
        </property>
    </object>
</objects>

Spring's DefaultHandlerFactory uses the .NET class System.Web.UI.SimpleHandlerFactory to create handler instances and configures each instance by using an object definition whose name matches the request URL's filename. The abstract object definition of DemoHandler.ashx is an example of this approach. You can also configure standard classes that implement the IHttpHandler interface as demonstrated in the example above for the class MyCustomHttpHandler.

Refer to the Web Quick Start application too see this in action.

22.4.4. Injecting dependencies in custom ASP.NET providers

Custom providers can be configured via dependency injection with Spring. The approach to configuration for providers is to use a family of adapters that correspond 1-to-1 with the standard ASP.NET providers that are registered via the standard ASP.NET mechanism. The adapters inherit from their correspondingly named provider class in the .NET class library.

  • MembershipProviderAdapter

  • ProfileProviderAdapter

  • RoleProviderAdapter

  • SiteMapProviderAdapter

Here is an example of how to register the adapter for membership providers.

        <membership defaultProvider="mySqlMembershipProvider">
            <providers>
                <clear/>
                <add connectionStringName="" name="mySqlMembershipProvider" type="Spring.Web.Providers.MembershipProviderAdapter, Spring.Web"/>
            </providers>
        </membership>

The name of the provider must match the name of the object in the Spring configuration that will serve as the actual provider implementation. Configurable versions of the providers are found in ASP.NET so that you can use the full functionality of Spring to configure these standard provider implementations, by using property placeholders, and so on. The providers are:

  • ConfigurableActiveDirectoryMembershipProvider

  • ConfigurableSqlMembershipProvider

  • ConfigurableSqlProfileProvider

  • ConfigurableSqlRoleProvider

  • ConfigurableXmlSiteMapProvider

This example configuration taken from the Web Quick Start application sets the description property and connection string.

    <object id="mySqlMembershipProvider" type="Spring.Web.Providers.ConfigurableSqlMembershipProvider">
        <property name="connectionStringName" value="MyLocalSQLServer" />
        <property name="parameters">
            <name-values>
                <add key="description" value="membershipprovider description" />
            </name-values>
        </property>
    </object>

Your own custom providers of course will contain additional configuration specific to your implementation.

22.4.5. Customizing control dependency injection

You may need to customize Spring.Web's dependency injection processing, such as when using GridViews or other complex 3rd party custom controls. Often these controls are not configured using dependency injection but Spring considers each control and its nested child controls as candidates for DI. With very large (>1000) nested controls that candidate evaluation process can unecessarily slow down your page. To address this problem, you can tell Spring to not attempt to configure via DI the sections of your page that contain these controls or implementing the interface ISupportsWebDependencyInjection and explicitly ask Spring to inject dependencies on a particular contorol. These approaches are shown below

[C#]
class MyControl : Control, ISupportsWebDependencyInjection
{
  private IApplicationContext _defaultApplicationContext;

  public IApplicationContext DefaultApplicationContext
  {
    get { return _defaultApplicationContext; }
    set { _defaultApplicationContext = value; }
  }

  override protected AddedControl( Control control, int index )
  {
    // handle DI for children ourselves -
    // defaults to a call to InjectDependenciesRecursive
    WebUtils.InjectDependenciesRecursive( _defaultApplicationContext, control );
    base.AddedControl( control, index );
  }
}

A Spring server control, Panel, provides an easier way to turn off dependency injection for parts of your page:

<spring:Panel runat="server"
   suppressDependencyInjection="true"
   renderContainerTag="false">

   .. put your heavy controls here - they won't be touched by DI

</spring:Panel>

By wrapping the performance-sensitive parts of your page within this panel, you can easily turn off DI by setting the attribute suppressDependencyInjection to true. By default <spring:Panel/> will not render a container tag (<div>, <span>, and so on). You can modify this behavior by setting the attribute renderContainerTag accordingly.

22.5. Web object scopes

Spring.NET web applications support an additional attribute within object definition elements that allows you to control the scope of an object:

<object id="myObject" type="MyType, MyAssembly" scope="application | session | request"/>

Possible values for the scope attribute are application, session, and request. Application scope is the default, and is used for all objects with an undefined scope attribute. This scope creates a single instance of an object for the duration of the IIS application, so that the objects works exactly like the standard singleton objects in non-web applications. Session scope defines objects so that an instance is created for each HttpSession. This scope is ideal for objects such as user profile, shopping cart, and so on that you want bound to a single user.

Request scope creates one instance per HTTP request. Unlike calls to prototype objects, calls to IApplicationContext.GetObject return the same instance of the request-scoped object during a single HTTP request. This allows you, for example, to inject the same request-scoped object into multiple pages and then use server-side transfer to move from one page to another. As all the pages are executed within the single HTTP request in this case, they share the same instance of the injected object.

Objects can only reference other objects that are in the same or broader scope. This means that application-scoped objects can only reference other application-scoped objects, session-scoped objects can reference both session and application-scoped objects, and request-scoped objects can reference other request-, session-, or application-scoped objects. Also, prototype objects (including all ASP.NET web pages defined within Spring.NET context) can reference singleton objects from any scope, as well as other prototype objects.

22.6. Support for ASP.NET 1.1 master pages in Spring.Web

Support for ASP.NET 1.1 master pages in Spring.Web is very similar to the support for master pages in ASP.NET 2.0.

A web developer can define a layout template for the site as a master page and specify content placeholders that other pages can then reference and populate. A sample master page (MasterLayout.ascx) could look like this:

<%@ Control language="c#" Codebehind="MasterLayout.ascx.cs" AutoEventWireup="false" Inherits="MyApp.Web.UI.MasterLyout" %>
<%@ Register TagPrefix="spring" Namespace="Spring.Web.UI.Controls" Assembly="Spring.Web" %>
<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.0 Transitional//EN" >
<html>
    <head>
        <title>Master Page</title>
        <link rel="stylesheet" type="text/css" href="<%= Context.Request.ApplicationPath %>/css/styles.css">
        <spring:ContentPlaceHolder id="head" runat="server"/>
    </head>
    <body>
        <form runat="server">
            <table cellPadding="3" width="100%" border="1">
                <tr>
                    <td colspan="2">
                        <spring:ContentPlaceHolder id="title" runat="server">
                            <!-- default title content -->
                        </spring:ContentPlaceHolder>
                    </td>
                </tr>
                <tr>
                    <td>
                        <spring:ContentPlaceHolder id="leftSidebar" runat="server">
                            <!-- default left side content -->
                        </spring:ContentPlaceHolder>
                    </td>
                    <td>
                        <spring:ContentPlaceHolder id="main" runat="server">
                            <!-- default main area content -->
                        </spring:ContentPlaceHolder>
                    </td>
                </tr>
            </table>
        </form>
    </body>
</html>

In the preceding code, the master page defines the overall layout for the page, in addition to four content placeholders that other pages can override. The master page can also include default content within the placeholder that will be displayed if a derived page does not override the placeholder.

A page that uses this master page (Child.aspx) might look like this:

<%@ Register TagPrefix="spring" Namespace="Spring.Web.UI.Controls" Assembly="Spring.Web" %>
<%@ Page language="c#" Codebehind="Child.aspx.cs" AutoEventWireup="false" Inherits="ArtFair.Web.UI.Forms.Child" %>
<html>
    <body>

        <spring:Content id="leftSidebarContent" contentPlaceholderId="leftSidebar" runat="server">
            <!-- left sidebar content -->
        </spring:Content>

        <spring:Content id="mainContent" contentPlaceholderId="main" runat="server">
            <!-- main area content -->
        </spring:Content>

    </body>
</html>

The <spring:Content/> control in the example uses the contentPlaceholderId attribute (property) to specify exactly which placeholder from the master page is to be overridden. Because this particular page does not define content elements for the head and title placeholders, the content elements are defined by the default content supplied in the master page.

Both the ContentPlaceHolder and Content controls can contain any valid ASP.NET markup: HTML, standard ASP.NET controls, user controls, and so on.

[Tip]Tip

Technically, the <html> and <body> tags from the previous example are not strictly necessary because they are already defined in the master page. However, if these tags are omitted, Visual Studio 2003 complains about a schema, and IntelliSense does not work. So it is much easier to work in the HTML view if those tags are included. They are ignored when the page is rendered.

22.6.1. Linking child pages to their master page file

The Spring.Web.UI.Page class exposes a property called MasterPageFile, which you can use to specify the master page.

The recommended way to do this is by leveraging the Spring.NET IoC container and creating definitions similar to the following:

<?xml version="1.0" encoding="utf-8" ?>
<objects xmlns="http://www.springframework.net">

  <object name="basePage" abstract="true">
      <property name="MasterPageFile" value="~/MasterLayout.ascx"/>
  </object>

  <object type="Child.aspx" parent="basePage">
      <!-- inject other objects that page needs -->
  </object>

</objects>

This approach allows application developers to change the master page for a number of pages within a web application. You can still override the master page on a per context or per page basis by creating a new abstract page definition within a child context, or by specifying the MasterPageFile property directly.

22.7. Bidirectional data binding and data model management

The existing data binding support in ASP.NET is one-way only. It allows application developers to bind page controls to the data model and display information from the data model, but it does not permit the extraction of values from the controls when the form is submitted. Spring.Web adds bidirectional data binding to ASP.NET by allowing developers to specify data binding rules for their page, and by automatically evaluating configured data binding rules at the appropriate time in the page's lifecycle.

ASP.NET does support model management within the postbacks. It has a ViewState management, but that takes care of the control state only and does not address the state of any presentation model objects to which these controls are bound. To manage a model within ASP.NET, developers typically use an HTTP session object to store the model between the postbacks. This process results in boilerplate code that can and should be eliminated, which is exactly what Spring.Web does by providing a simple set of model management methods.

To take advantage of the bidirectional data binding and model management support provided by Spring.Web, you will have to couple your presentation layer to Spring.Web; this is because features require you to extend a Spring.Web.UI.Page instead of the usual System.Web.UI.Page class.

Spring.Web data binding is very easy to use. Simply override the protected InitializeDataBindings method and configure data binding rules for the page. You also need to override three model management methods: InitializeModel, LoadModel and SaveModel. This process is illustrated by an example from the SpringAir reference application. First, take a look at the page markup:

<%@ Page Language="c#" Inherits="TripForm" CodeFile="TripForm.aspx.cs" %>

<asp:Content ID="body" ContentPlaceHolderID="body" runat="server">
    <div style="text-align: center">
        <h4><asp:Label ID="caption" runat="server"></asp:Label></h4>
        <table>
            <tr class="formLabel">
                <td>&nbsp;</td>
                <td colspan="3">
                    <spring:RadioButtonGroup ID="tripMode" runat="server">
                        <asp:RadioButton ID="OneWay" runat="server" />
                        <asp:RadioButton ID="RoundTrip" runat="server" />
                    </spring:RadioButtonGroup>
                </td>
            </tr>
            <tr>
                <td class="formLabel" align="right">
                    <asp:Label ID="leavingFrom" runat="server" /></td>
                <td nowrap="nowrap">
                    <asp:DropDownList ID="leavingFromAirportCode" runat="server" />
                </td>
                <td class="formLabel" align="right">
                    <asp:Label ID="goingTo" runat="server" /></td>
                <td nowrap="nowrap">
                    <asp:DropDownList ID="goingToAirportCode" runat="server" />
                </td>
            </tr>
            <tr>
                <td class="formLabel" align="right">
                    <asp:Label ID="leavingOn" runat="server" /></td>
                <td nowrap="nowrap">
                    <spring:Calendar ID="departureDate" runat="server" Width="75px" AllowEditing="true" Skin="system" />
                </td>
                <td class="formLabel" align="right">
                    <asp:Label ID="returningOn" runat="server" /></td>
                <td nowrap="nowrap">
                    <div id="returningOnCalendar">
                        <spring:Calendar ID="returnDate" runat="server" Width="75px" AllowEditing="true" Skin="system" />
                    </div>
                </td>
            </tr>
            <tr>
                <td class="buttonBar" colspan="4">
                    <br/>
                    <asp:Button ID="findFlights" runat="server"/></td>
            </tr>
        </table>
    </div>

 </asp:Content>

Ignore for the moment the fact that none of the label controls have text defined; defining label controls is described later when we discuss localization in Spring.NET. For the purposes of the current discussion, a number of input controls are defined: tripMode radio button group, leavingFromAirportCode and goingToAirportCode dropdown lists, as well as two Spring.NET Calendar controls, departureDate and returnDate.

Take a look at the model to which you bind the form:

namespace SpringAir.Domain
{
    [Serializable]
    public class Trip
    {
        // fields
        private TripMode mode;
        private TripPoint startingFrom;
        private TripPoint returningFrom;

        // constructors
        public Trip()
        {
            this.mode = TripMode.RoundTrip;
            this.startingFrom = new TripPoint();
            this.returningFrom = new TripPoint();
        }

        public Trip(TripMode mode, TripPoint startingFrom, TripPoint returningFrom)
        {
            this.mode = mode;
            this.startingFrom = startingFrom;
            this.returningFrom = returningFrom;
        }

        // properties
        public TripMode Mode
        {
            get { return this.mode; }
            set { this.mode = value; }
        }

        public TripPoint StartingFrom
        {
            get { return this.startingFrom; }
            set { this.startingFrom = value; }
        }

        public TripPoint ReturningFrom
        {
            get { return this.returningFrom; }
            set { this.returningFrom = value; }
        }
    }

    [Serializable]
    public class TripPoint
    {
        // fields
        private string airportCode;
        private DateTime date;

        // constructors
        public TripPoint()
        {}

        public TripPoint(string airportCode, DateTime date)
        {
            this.airportCode = airportCode;
            this.date = date;
        }

        // properties
        public string AirportCode
        {
            get { return this.airportCode; }
            set { this.airportCode = value; }
        }

        public DateTime Date
        {
            get { return this.date; }
            set { this.date = value; }
        }
    }

    [Serializable]
    public enum TripMode
    {
        OneWay,
        RoundTrip
    }
}

As you can see, Trip class uses the TripPoint class to represent departure and return, which are exposed as StartingFrom and ReturningFrom properties. It also uses TripMode enumeration to specify whether the trip is one way or return trip, which is exposed as Mode property.

Here is the code-behind class that ties everything together:

public class TripForm : Spring.Web.UI.Page
{
    // model
    private Trip trip;
    public Trip Trip
    {
        get { return trip; }
        set { trip = value; }
    }

    // service dependency, injected by Spring IoC container
    private IBookingAgent bookingAgent;
    public IBookingAgent BookingAgent
    {
        set { bookingAgent = value; }
    }

    // model management methods
    protected override void InitializeModel()
    {
        trip = new Trip();
        trip.Mode = TripMode.RoundTrip;
        trip.StartingFrom.Date = DateTime.Today;
        trip.ReturningFrom.Date = DateTime.Today.AddDays(1);
    }

    protected override void LoadModel(object savedModel)
    {
        trip = (Trip) savedModel;
    }

    protected override object SaveModel()
    {
        return trip;
    }

    // data binding rules
    protected override void InitializeDataBindings()
    {
        BindingManager.AddBinding("tripMode.Value", "Trip.Mode");
        BindingManager.AddBinding("leavingFromAirportCode.SelectedValue", "Trip.StartingFrom.AirportCode");
        BindingManager.AddBinding("goingToAirportCode.SelectedValue", "Trip.ReturningFrom.AirportCode");
        BindingManager.AddBinding("departureDate.SelectedDate", "Trip.StartingFrom.Date");
        BindingManager.AddBinding("returnDate.SelectedDate", "Trip.ReturningFrom.Date");
    }

    // event handler for findFlights button, uses injected 'bookingAgent'
    // service and model 'trip' object to find flights
    private void SearchForFlights(object sender, EventArgs e)
    {
        FlightSuggestions suggestions = bookingAgent.SuggestFlights(trip);
        if (suggestions.HasOutboundFlights)
        {
            // redirect to SuggestedFlights page
        }
    }
}

Note the following about the three preceding pieces of code:

  1. When the page is initially loaded (IsPostback == false), the InitializeModel() method is called, which initializes the trip object by creating a new instance and setting its properties to desired values. Right before the page is rendered, the SaveModel() method is invoked, and the value it returns is stored within the HTTP session. On each postback, the LoadModel() method is called, and the value returned by the previous call to SaveModel is passed to SaveModel as an argument.

    In this particular case the implementation is very simple because our whole model is just the trip object. As such, SaveModel() simply returns the trip object, and LoadModel() casts the SaveModel() argument to Trip and assigns it to the trip field within the page. In more complex scenarios, the SaveModel() method will typically return a dictionary that contains your model objects. Those values will be read from the dictionary within the LoadModel() method.

  2. InitializeDataBindings method defines the binding rules for all of the five input controls on the form. The controls are represented by the variables tripMode, leavingFromAirportCode, goingToAirportCode, departueDate, and returnDate. The binding rules are created by invoking the AddBinding method on the BindingManager exposed by the page. The AddBinding method is heavily overloaded and it allows you to specify a binding direction and a formatter to use in addition to the source and target binding expressions that are used above. These optional parameters are discussed later in this chapter. For now, focus on the source and target expressions.

    The Spring.NET data binding framework uses Spring.NET Expression Language to define binding expressions. In most cases, as in the example above, both source and target expression will evaluate to a property or a field within one of the controls or a data model. This is always the case when you are setting a bidirectional binding, as both binding expressions need to be "settable". The InitializeDataBindings method is executed only once per page type. Basically, all binding expressions are parsed the first time the page is instantiated, and are then cached and used by all instances of that same page type that are created at a later time. This is done for performance reasons, as data binding expression parsing on every postback is unnecessary and would add a significant overhead to the overall page processing time.

  3. Notice that the SearchForFlights event handler has no dependencies on the view elements. It simply uses the injected bookingAgent service and a trip object in order to obtain a list of suggested flights. Furthermore, if you make any modifications to the trip object within your event handler, bound controls are updated accordingly just before the page is rendered.

    [Note]Note

    The lack of view elements in the event handler accomplishes one of the major goals we set out to achieve, allowing developers to remove view element references from the page event handlers and decouple controller-type methods from the view.

22.7.1. Data binding under the hood

This section describes how data binding is actually implemented, the extension points, and additional features that make the data binding framework usable in real-world applications.

The Spring.NET data binding framework revolves around two main interfaces: IBinding and IBindingContainer. The IBinding interface is definitely the more important one of the two, as it has to be implemented by all binding types. This interface defines several methods, with some of them being overloaded for convenience:

public interface IBinding
{
    void BindSourceToTarget(object source, object target, ValidationErrors validationErrors);

    void BindSourceToTarget(object source, object target, ValidationErrors validationErrors,
                            IDictionary variables);

    void BindTargetToSource(object source, object target, ValidationErrors validationErrors);

    void BindTargetToSource(object source, object target, ValidationErrors validationErrors,
                            IDictionary variables);

    void SetErrorMessage(string messageId, params string[] errorProviders);
}

The BindSourceToTarget method is used to extract and copy bound values from the source object to the target object, and BindTargetToSource does the opposite. Both method names and parameter types are generic because the data binding framework can be used to bind any two objects. Using it to bind web forms to model objects is just one of its possible uses, although a very common one and tightly integrated into the Spring.NET Web Framework.

The ValidationErrors parameter requires further explanation. Although the data binding framework is not in any way coupled to the data validation framework, they are in some ways related. For example, while the data validation framework is best suited to validate the populated model according to the business rules, the data binding framework is in a better position to validate data types during the binding process. However, regardless of where specific validation is performed, all error messages should be presented to the user in a consistent manner. In order to accomplish this, Spring.NET Web Framework passes the same ValidationErrors instance to binding methods and to any validators that might be executed within your event handlers. This process ensures that all error messages are stored together and are displayed consistently to the end user, using Spring.NET validation error controls.

The last method in the IBinding interface, SetErrorMessage, enables you to specify the resource id of the error message to be displayed in case of binding error, as well as a list of strings, that server as identifiers to tag error messages for the purposes of linking specific error messages to locations in the page markup. We wil see an example of the SetErrorMessage usage in a later section.

The IBindingContainer interface extends the IBinding interface and adds the following members:

public interface IBindingContainer : IBinding
{
  bool HasBindings { get; }

  IBinding AddBinding(IBinding binding);
  IBinding AddBinding(string sourceExpression, string targetExpression);
  IBinding AddBinding(string sourceExpression, string targetExpression, BindingDirection direction);
  IBinding AddBinding(string sourceExpression, string targetExpression, IFormatter formatter);
  IBinding AddBinding(string sourceExpression, string targetExpression, BindingDirection direction,
                      IFormatter formatter);
}

The IBindingContainer interface has several overloaded AddBinding methods. AddBinding(IBinding binding) is the most generic one, as it can be used to add any binding type to the container. The other four are convenience methods that provide a simple way to add the most commonly used implementation of the IBinding interface, SimpleExpressionBinding. The SimpleExpressionBinding was used under the covers in the example at the beginning of this section to bind our web form to a Trip instance when calling methods on the property BindingManager. Note that the BindingManager property is of the type IBindingContainer. SimpleExpressionBinding uses Spring.NET Expression Language (SpEL) to extract and to set values within source and target objects.

In the TripForm example, the configuration of the BindingManager shows the basic usage of how SpEL can be used to specify a sourceExpression and targetExpression arguments. This code section is repeated below

    protected override void InitializeDataBindings()
    {
        BindingManager.AddBinding("tripMode.Value", "Trip.Mode");
        BindingManager.AddBinding("leavingFromAirportCode.SelectedValue", "Trip.StartingFrom.AirportCode");
        BindingManager.AddBinding("goingToAirportCode.SelectedValue", "Trip.ReturningFrom.AirportCode");
        BindingManager.AddBinding("departureDate.SelectedDate", "Trip.StartingFrom.Date");
        BindingManager.AddBinding("returnDate.SelectedDate", "Trip.ReturningFrom.Date");
    }

In this case, the first argument is a sourceExpression evaluated in the context of the page itself. The sourceExpression 'tripMode.Value' represents the value in the HTML control and the targetExpression "Trip.Mode" represents the value it will be mapped onto whent the page is rendered. When the post-back happens values from in "Trip.Mode" get placed back into the HTML control "tripMode.Value". This is a common case in which bi-directional data mapping is symmetric in terms of the sourceExpression and targetExpression for both the initial rendering of the page and when the post-back occurs. There other overloaded methods that take BindingDirection and IFormatter arguments are discussed in the next section.

22.7.1.1. Binding direction

The direction argument determines whether the binding is bidirectional or unidirectional. By default, all data bindings are bidirectional unless the direction argument is set to either BindingDirection.SourceToTarget or BindingDirection.TargetToSource. If one of these values is specified, binding is evaluated only when the appropriate BindDirection method is invoked, and is completely ignored in the other direction. This configuration is very useful when you want to bind some information from the model into non-input controls, such as labels.

However, unidirectional data bindings are also useful when your form does not have a simple one-to-one mapping to a presentation model. In the earlier trip form example, the presentation model was intentionally designed to allow for simple one-to-one mappings. For the sake of discussion, let's add the Airport class and modify our TripPoint class as follows:

namespace SpringAir.Domain
{
    [Serializable]
    public class TripPoint
    {
        // fields
        private Airport airport;
        private DateTime date;

        // constructors
        public TripPoint()
        {}

        public TripPoint(Airport airport, DateTime date)
        {
            this.airport = airport;
            this.date = date;
        }

        // properties
        public Airport Airport
        {
            get { return this.airport; }
            set { this.airport = value; }
        }

        public DateTime Date
        {
            get { return this.date; }
            set { this.date = value; }
        }
    }

    [Serializable]
    public class Airport
    {
        // fields
        private string code;
        private string name;

       // properties
        public string Code
        {
            get { return this.code; }
            set { this.code = value; }
        }

        public string Name
        {
            get { return this.name; }
            set { this.name = value; }
        }
    }
}

Instead of the string property AirportCode, our TripPoint class now exposes an Airport property of type Airport, which is defined in the preceding example. What was formerly a simple string-to-string binding, with the airport code selected in a dropdown being copied directly into the TripPoint.AirportCode property and vice versa, now becomes a not-so-simple string-to-Airport binding. So let's see how we can solve this mismatch problem of converting a string to an Airport instance and an Airport instance to a string.

Binding from the model to the control, namely the Airport to the string, is still very straightforward. You set up one-way bindings from the model to controls: The Model-To-Control is represented more generally by the enumeration, BindingDirection.TargetToSource.

protected override void InitializeDataBindings()
    {
        BindingManager.AddBinding("leavingFromAirportCode.SelectedValue", "Trip.StartingFrom.Airport.Code", BindingDirection.TargetToSource);
        BindingManager.AddBinding("goingToAirportCode.SelectedValue", "Trip.ReturningFrom.Airport.Code", BindingDirection.TargetToSource);
        ...
    }

You extract the airport code value from the Trip.StartingFrom.Airport.Code instead of Trip.StartingFrom.AirportCode since now the Code in encapsulated inside the Airport class. Unfortunately, binding from the control to the model the same way won't work, we need a way to create an Airport instance from a string. Instead, you need to find an instance of the Airport class based on the airport code and set the TripPoint.Airport property to it. Fortunately, Spring.NET data binding makes this simple, especially because you already have airportDao object defined in the Spring context (see SpringAir Spring context configuration file for details.). The AirportDao has a GetAirport(string airportCode) finder method. You set up data bindings from source to target (control-to-model) that will invoke this finder method when the page is submitted and the binding infrastructure maps the sourceExpression onto the targetExpression.evaluating the source expression.

Our complete set of bindings for these two drop-down lists will then look like this:

protected override void InitializeDataBindings()
    {
        BindingManager.AddBinding("@(airportDao).GetAirport(leavingFromAirportCode.SelectedValue)", "Trip.StartingFrom.Airport", BindingDirection.SourceToTarget);
        BindingManager.AddBinding("leavingFromAirportCode.SelectedValue", "Trip.StartingFrom.Airport.Code", BindingDirection.TargetToSource);

        BindingManager.AddBinding("@(airportDao).GetAirport(goingToAirportCode.SelectedValue)", "Trip.ReturningFrom.Airport", BindingDirection.SourceToTarget);
        BindingManager.AddBinding("goingToAirportCode.SelectedValue", "Trip.ReturningFrom.Airport.Code", BindingDirection.TargetToSource);
        ...
    }

By using a pair of bindings for each control, one for each direction and using SpEL's feature to reference objects defined in the Spring context, you can resolve this data binding issue.

22.7.1.2. formatter argument

The last overloaded methods of IBindingContainer we need to discuss are those that take a IFormatter argument. is an argument to the AddBinding method. This argument allows you to specify a formatter that you use to parse string value from the input control before it is bound to the model, and to format strongly typed model value before the model is bound to the control.

You typically use one of the formatters provided in the Spring.Globalization.Formatters namespace, but if your requirements cannot be satisfied by a standard formatter, you can write your own by implementing a simple IFormatter interface:

public interface IFormatter
{
    string Format(object value);
    object Parse(string value);
}

Standard formatters provided with Spring.NET are: CurrencyFormatter, DateTimeFormatter, FloatFormatter, IntegerFormatter, NumberFormatter and PercentFormatter, which are sufficient for most usage scenarios.

22.7.1.3. Type conversion

Because the data binding framework uses the same expression evaluation engine as the Spring.NET IoC container, it uses any registered type converters to perform data binding. Many type converters are included with Spring.NET (take a look at the classes in Spring.Objects.TypeConverters namespace) and are automatically registered for you, but you can implement your own custom converters and register them by using standard Spring.NET type converter registration mechanisms.

22.7.1.4. Data binding events

Spring.Web's base Page class adds two events to the standard .NET page lifecycle: DataBound and DataUnbound.

You can register for an DataUnbound event which will be fired after the data model is updated with values from the controls. Specifically, in terms of the Page lifecycle, it is fired right after the Load event and only on postbacks, because it not make sense to update the data model with the controls' initial values.

The DataBound event is fired after controls are updated with values from the data model. This event occurs right before the PreRender event.

The fact that the data model is updated immediately after the Load event and that controls are updated right before the PreRender event means that your event handlers can work with a correctly updated data model, as they execute after the Load event, and that any changes you make to the data model within event handlers are reflected in the controls immediately afterwards, as the controls are updated prior to the actual rendering.

22.7.1.5. Rendering binding errors

If errors occur in the databinding (for example, in trying to bind a string 'hello' to an integer property on the model), you can specify how those fundamental binding errors should be rendered. The following snippet is from the Web Quick Start 'RobustEmployeeInfo' example:

[Default.aspx.cs]

protected override void InitializeDataBindings()
{
  // collect txtId.Text binding errors in "id.errors" collection
  BindingManager.AddBinding("txtId.Text", "Employee.Id").SetErrorMessage("ID has to be an integer", "id.errors");
  ...

[Default.aspx]
...
<asp:TextBox ID="txtId" runat="server" />
<!-- output validation errors from "id.errors" collection -->
<spring:ValidationError Provider="id.errors" runat="server" />
...

The SetErrorMessage specifies the message text or resource id of the error message to be displayed. This is followed by a a variable length list of strings that serve to as a means to assign a friendly name to associate with this error should it occur. The same 'tag', or error provider name, can be used across different calls to 'AddBinding'. This is commonly the case if you want to present several errors together in the page. In the preceding example, the 'tag' or error provider name is "id.errors" will be rendered in Spring's ValidationError User Control, for example as shown below in this fragment of page markup. Validation controls are discussed more extensively in this section.

            <td>
                <asp:TextBox ID="txtId" runat="server" EnableViewState="false" />
                <spring:ValidationError ID="errId" Provider="id.errors" runat="server" /><!-- read msg from "id.error" provider -->
            </td>

22.7.1.6. HttpRequestListBindingContainer

HttpRequestListBindingContainer extracts posted raw values from the request and populates the specified IList by creating objects of the type specified and populating each object according to the requestBindings collection.

Please check out the Web Quick Start sample's demo of HttpRequestListBindingContainer. Below is an exerpt from that example showing how to use a HttpRequestListBindingContainer.

protected override void InitializeDataBindings()
{
  // HttpRequestListBindingContainer unbinds specified values from Request -> Productlist
  HttpRequestListBindingContainer requestBindings =
      new HttpRequestListBindingContainer("sku,name,quantity,price", "Products", typeof(ProductInfo));
  requestBindings.AddBinding("sku", "Sku");
  requestBindings.AddBinding("name", "Name");
  requestBindings.AddBinding("quantity", "Quantity", quantityFormatter);
  requestBindings.AddBinding("price", "Price", priceFormatter);

  BindingManager.AddBinding(requestBindings);
}
[Note]Note
Because browsers do not send the values of unchecked checkboxes, you cannot use HttpRequestListBindingContainer with <input type="checkbox" > html controls.

22.7.2. Using DataBindingPanel

To simplify use of Spring's Data Binding feature on web pages and controls, Spring.Web provides a special DataBindingPanel container control. A DataBindingPanel does not render any html code itself, but allows you to define additional, data binding-related attributes for its child controls.

<%@ Page Language="C#" CodeFile="Default.aspx.cs" Inherits="DataBinding_EasyEmployeeInfo_Default" %>
<%@ Register TagPrefix="spring" Namespace="Spring.Web.UI.Controls" Assembly="Spring.Web" %>
<html>
<body>
<spring:DataBindingPanel ID="ctlDataBindingPanel" runat="server">
    <table cellpadding="3" cellspacing="3" border="0">
        <tr>
            <td>Employee ID:</td>
            <td>
                <asp:TextBox ID="txtId" runat="server" BindingTarget="Employee.Id" />              
            </td>
        </tr>
        <tr>
            <td>First Name:</td>
            <td><asp:TextBox ID="txtFirstName" runat="server" BindingTarget="Employee.FirstName" /></td>
        </tr>
    </table>
</spring.DataBindingPanel>
</body>
</html>

Using DataBindingPanel, you can specify the binding information directly on the control declaration. The following attributes are recognized by a DataBindingPanel:

  • BindingTarget corresponds to the target expression used in IBindingContainer.AddBinding().

  • BindingSource corresponds to the source expression used in IBindingContainer.AddBinding(). For standard controls you don't need to specify the source expression. If you are binding to some custom control, of course you must specific this attribute.

  • BindingDirection is one of the values of the BindingDirection enumeration.

  • BindingFormatter is the object name of a custom formatter. The formatter instance is obtained by a call to IApplicationContext.GetObject() each time it is needed.

  • BindingType is the type of a completely customized binding. Note that a custom binding type must implement the following constructor signature:

    ctor(string source,string target, BindingDirection, IFormatter)

[Note]Note
The Visual Studio Web Form Editor complains about binding attributes because it does not recognize them. You can safely ignore those warnings.

22.7.3. Customizing model persistence

As mentioned in the chapter introduction, model management needs an application developer to override InitializeModel(), SaveModel() and LoadModel() in order to store model information between requests in the user's session. On web farms, storing information in a user's session is not a good strategy. You can choose another persistence strategy by setting the ModelPersistenceMedium property on Spring's base Page or UserContorl class (e.g. Spring.Web.UI.UserControl)

<object id="modelPersister" type="Sample.DatabaseModelPersistenceMedium, MyCode"/>

<object type="UserRegistration.aspx">
    <property name="ModelPersistenceMedium" ref="modelPersister"/>
</object>

To implement any arbitrary persistence strategy, implement the IModelPersistenceMedium interface:

public interface IModelPersistenceMedium
{
  // Load the model for the specified control context.
  object LoadFromMedium( Control context );

  // Save the specified model object.
  void SaveToMedium( Control context, object modelToSave );
}

22.8. Localization and message sources

Although the .NET framework has excellent localization support, the support within ASP.NET 1.x is incomplete. Spring provides support for localization in ASP.NET 1.1 apps in the manner of ASP.NET 2.0. Despite the initial focus on righer localization for ASP.NET 1.1 applications, using Spring's localization features in ASP.NET 2.0 or higher applications does provide some useful additional features with a similar programming model, such as image localization, push mechansims, and built-in support for user culture management via various mechansims.

Every .aspx page in an ASP.NET project has a resource file associated with it, but those resources are never used by the current ASP.NET infrastructure). ASP.NET 2.0 changes this and allow application developers to use local resources for pages. In the meantime, the Spring.NET team built in to Spring.Web support for using local pages resources, thus allowing ASP.NET 1.1 application developers to using ASP.NET 2.0-like page resources.

Spring.Web supports several different approaches to localization within a web application, which can be mixed and matched as appropriate. You can use push and pull mechanisms, as well as globally defined resources when a local resource cannot be found. Spring.Web also supports user culture management and image localization, which are described in later sections.

[Tip]Tip

For introductory information covering ASP.NET globalization and localization, see Globalization Architecture for ASP.NET and Localization Practices for ASP.NET 2.0 by Michele Leroux Bustamante.

22.8.1. Working with localizers

A localizer is an object that implements the Spring.Globalization.ILocalizer interface. Spring.Globalization.AbstractLocalizer is a convenient base class for localization: this class has one abstract method, LoadResources. This method must load and return a list of all resources that must be automatically applied from the resource store.

To apply resources automatically, a localizer needs to be injected into all pages that require automatic resource application. You typically accomplish configuration using dependency injection of a page base page definition that other page definitions will inherit from. The injected localizer inspects the resource file when the page is first requested, caches the resources that start with the '$this' marker string value, and applies the values to the controls that populate the page prior to the page being rendered.

Spring.NET ships with one concrete implementation of a localizer, Spring.Globalization.Localizers.ResourceSetLocalizer, that retrieves a list of resources to apply from the local resource file. Future releases of Spring.NET may provide other localizers that read resources from an XML file or even from a flat text file that contains resource name-value pairs that allow application developers to store resources within the files in a web application instead of as embedded resources in an assembly. Of course, if an application developer prefers to store such resources in a database, the developer can write a custom ILocalizer implementation that loads a list of resources to apply from a database.

You typically configure the localizer to be used within an abstract base definition for those pages that require localization:

<object id="localizer" type="Spring.Globalization.Localizers.ResourceSetLocalizer, Spring.Core"/>

<object name="basePage" abstract="true">
    <description>
        Pages that reference this definition as their parent
        (see examples below) will automatically inherit following properties.
    </description>
    <property name="Localizer" ref="localizer"/>
</object>

Of course, nothing prevents an application developer from defining a different localizer for each page in the application; in any case, one can always override the localizer defined in a base (page) definition. Alternatively, if one does want any resources to be applied automatically one can completely omit the localizer definition.

One last thing to note is that Spring.NET UserControl instances will (by default) inherit the localizer and other localization settings from the page that they are contained within, but one can similarly also override that behavior using explicit dependency injection.

22.8.2. Automatic localization with localizers ("push" localization)

With push localization, an application developer specifies localization resources in the resource file for the page, and the framework automatically applies those resources to the user controls on the page. For example, an application developer could define a page such as UserRegistration.aspx:

<%@ Register TagPrefix="spring" Namespace="Spring.Web.UI.Controls" Assembly="Spring.Web" %>
<%@ Page language="c#" Codebehind="UserRegistration.aspx.cs"
    AutoEventWireup="false" Inherits="ArtFair.Web.UI.Forms.UserRegistration" %>
<html>
    <body>
        <spring:Content id="mainContent" contentPlaceholderId="main" runat="server">
            <div align="right">
                <asp:LinkButton ID="english" Runat="server" CommandArgument="en-US">English</asp:LinkButton>&nbsp;
                <asp:LinkButton ID="serbian" Runat="server" CommandArgument="sr-SP-Latn">Srpski</asp:LinkButton>
            </div>
            <table>
                <tr>
                    <td><asp:Label id="emailLabel" Runat="server"/></td>
                    <td><asp:TextBox id="email" Runat="server" Width="150px"/></td>
                </tr>
                <tr>
                    <td><asp:Label id="passwordLabel" Runat="server"/></td>
                    <td><asp:TextBox id="password" Runat="server" Width="150px"/></td>
                </tr>
                <tr>
                    <td><asp:Label id="passwordConfirmationLabel" Runat="server"/></td>
                    <td><asp:TextBox id="passwordConfirmation" Runat="server" Width="150px"/></td>
                </tr>
                <tr>
                    <td><asp:Label id="nameLabel" Runat="server"/></td>
                    <td><asp:TextBox id="name" Runat="server" Width="150px"/></td>
                </tr>
...

                <tr>
                    <td colspan="2">
                        <asp:Button id="saveButton" Runat="server"/>&nbsp;
                        <asp:Button id="cancelButton" Runat="server"/>
                    </td>
                </tr>
            </table>
        </spring:Content>
    </body>
</html>

In the preceding .aspx code, none of the Label or Button controls have had a value assigned to the Text property. The values of the Text property for these controls are stored in the local resource file (of the page) using the following convention to identify the resource (string).

$this.controlId.propertyName

The corresponding local resource file, UserRegistration.aspx.resx, is shown below.

<root>
  <data name="$this.emailLabel.Text">
    <value>Email:</value>
  </data>
  <data name="$this.passwordLabel.Text">
    <value>Password:</value>
  </data>
  <data name="$this.passwordConfirmationLabel.Text">
    <value>Confirm password:</value>
  </data>
  <data name="$this.nameLabel.Text">
    <value>Full name:</value>
  </data>

...

  <data name="$this.countryLabel.Text">
    <value>Country:</value>
  </data>
  <data name="$this.saveButton.Text">
    <value>$messageSource.save</value>
  </data>
  <data name="$this.cancelButton.Text">
    <value>$messageSource.cancel</value>
  </data>
</root>
[Tip]Viewing .resx file in Visual Studio 2003

To view the .resx file for a page, you may need to enable "Project/Show All Files" in Visual Studio. When "Show All Files" is enabled, the .resx file appears like a "child" of the code-behind page.

When Visual Studio creates the .resx file, it includes an xds:schema element and several reshead elements. Your data elements will follow the reshead elements. When working with the .resx files, you may want to choose "Open With" from the context menu and select the "Source Code" text editor.

There is no way to visually edit resources in a RESX file. Lutz Roeder has created a tool named Resourcer that you can use to edit them

[Tip]Creating a .resx file in Visual Studio 2005/8

To create a resource file in VS 2005, open your control or page in design mode and select "Tools/Generate local resource" from the menu.

You must create a localizer for the page to enable automatic localization:

<object id="localizer" type="Spring.Globalization.Localizers.ResourceSetLocalizer, Spring.Core"/>

<object type="UserRegistration.aspx">
    <property name="Localizer" ref="localizer"/>
</object>

For more information on configuring localizers see Section 22.8.1, “Working with localizers”

22.8.3. Global message sources

Two resource definitions from the previous section require some additional explanation:

<data name="$this.saveButton.Text">
    <value>$messageSource.save</value>
  </data>
  <data name="$this.cancelButton.Text">
    <value>$messageSource.cancel</value>
  </data>

In some cases it makes sense to apply a resource that is defined globally as opposed to locally. In this example, it makes better sense to define values for the Save and Cancel buttons globally as they will probably be used throughout the application.

The above example demonstrates how one can achieve that by defining a resource redirection expression as the value of a local resource by prefixing a global resource name with the following string.

$messageSource.

In the preceding example, this string tells the localizer to use the save and cancel portions of the resource key as lookup keys to retrieve the actual values from a global message source. You need to define a resource redirect only once, typically in the invariant resource file. Any lookup for a resource redirect falls back to the invariant culture, and results in a global message source lookup using the correct culture.

Global resources are (on a per-context basis) defined as a plain vanilla object definition using the reserved name of messageSource, which you can add to your Spring.NET configuration file:

<object id="messageSource" type="Spring.Context.Support.ResourceSetMessageSource, Spring.Core">
    <property name="ResourceManagers">
        <list>
            <value>MyApp.Web.Resources.Strings, MyApp.Web</value>
        </list>
    </property>
</object>
[Important]for .NET 2.0 or higher

To use resources from your App_GlobalResources folder, specify App_GlobalResources as the assembly name:

<value>Resources.Strings, App_GlobalResources</value>

See the SpringAir example application for more. The global resources are cached within the Spring.NET IApplicationContext and are accessible through the Spring.NET IMessageSource interface.

The Spring.Web Page and UserControl classes have a reference to their owning IApplicationContext and its associated IMessageSource. As such, they automatically redirect resource lookups to a global message source if a local resource cannot be found.

Currently, the ResourceSetMessageSource is the only message source implementation that ships with Spring.NET.

22.8.4. Applying resources manually ("pull" localization)

Although automatic localization as described above works well for many form-like pages, it doesn't work nearly as well for controls defined within any iterative controls, because the IDs for such iterative controls are not fixed. Nor does automatic localization work well if you need to display the same resource multiple times within the same page. For example, think of the header columns for outgoing and return flights tables within the SpringAir application (see Chapter 41, SpringAir - Reference Application).

These situations call for a pull-style mechanism for localization, which is a simple GetMessage call:

<asp:Repeater id="outboundFlightList" Runat="server">
  <HeaderTemplate>
    <table border="0" width="90%" cellpadding="0" cellspacing="0" align="center" class="suggestedTable">
      <thead>
        <tr class="suggestedTableCaption">
          <th colspan="6">
            <%= GetMessage("outboundFlights") %>
          </th>
        </tr>
        <tr class="suggestedTableColnames">
          <th><%= GetMessage("flightNumber") %></th>
          <th><%= GetMessage("departureDate") %></th>
          <th><%= GetMessage("departureAirport") %></th>
          <th><%= GetMessage("destinationAirport") %></th>
          <th><%= GetMessage("aircraft") %></th>
          <th><%= GetMessage("seatPlan") %></th>
        </tr>
      </thead>
      <tbody>
  </HeaderTemplate>

The GetMessage method is available within both the Spring.Web.UI.Page and Spring.Web.UI.UserControl classes, and it falls back automatically to a global message source lookup if a local resource is not found.

22.8.5. Localizing images within a web application

Unlike text resources, which can be stored within embedded resource files, XML files, or even a database, images in a typical web application are usually stored as files on the file system. Using a combination of directory naming conventions and a custom ASP.NET control, Spring.Web allows you to localize images within the page as easily as you do text resources.

The Spring.Web Page class exposes the ImagesRoot property, with which you define the root directory where images are stored. The default value is Images, which means that the localizer expects to find an Images directory within the application root. But you can set the property to any value in the definition of the page.

To localize images, you create a directory for each localized culture under the ImagesRoot directory:

/MyApp
   /Images
      /en
      /en-US
      /fr
      /fr-CA
      /sr-SP-Cyrl
      /sr-SP-Latn
      ...

Once an appropriate folder hierarchy is in place, you put the localized images in the appropriate directories and make sure that different translations of the same image have the same image name within the folders. To place a localized image on a page, you use the <spring:LocalizedImage>:

<%@ Page language="c#" Codebehind="StandardTemplate.aspx.cs"
                AutoEventWireup="false" Inherits="SpringAir.Web.StandardTemplate" %>
<%@ Register TagPrefix="spring" Namespace="Spring.Web.UI.Controls" Assembly="Spring.Web" %>
<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.0 Transitional//EN" >
<html>
  <body>
    <spring:LocalizedImage id="logoImage" imageName="spring-air-logo.jpg" borderWidth="0" runat="server" />
  </body>
</html>

This control will find the most specific directory that contains an image with the specified name using standard localization fallback rules and the user's culture. For example, if the user's culture is 'en-US', the localizer will look for the spring-air-logo.jpg file in Images/en-US, then in Images/en and finally, if the image file has still not been found, in the root Images directory (which for all practical purposes serves as an invariant culture folder).

22.8.6. User culture management

In addition to global and local resource management, Spring.Web supports user culture management by exposing the current CultureInfo through the UserCulture property on the Page and UserControl classes.

The UserCulture property delegates culture resolution to an implementation of the Spring.Globalization.ICultureResolver interface. You specify the culture resolver to use by configuring the CultureResolver property of the Page class in the relevant object definition:

<object name="BasePage" abstract="true">
    <property name="CultureResolver">
        <object type="Spring.Globalization.Resolvers.CookieCultureResolver, Spring.Web"/>
    </property>
</object>

Several useful implementations of ICultureResolver ship as part of Spring.Web, so it is unlikely that application developers need to implement their own culture resolver. However, you do need to implement your own culture resolver, the resulting implementation should be fairly straightforward as you need to implement only two methods. The following sections discuss each available implementation of the ICultureResolver interface.

22.8.6.1. DefaultWebCultureResolver

DefaultWebCultureResolver, the default culture resolver implementation, is used if you do not specify a culture resolver for a page, or if you inject a DefaultWebCultureResolver into a page definition explicitly. The latter case (explicit injection) is sometimes useful because you can specify a culture that should always be used, by defining the DefaultCulture property on the resolver.

The DefaultWebCultureResolver looks first at the DefaultCulture property and return its value if said property value is not null. If it is null, the DefaultWebCultureResolver falls back to request header inspection. If no 'Accept-Lang' request headers are present , the resolver returns the UI culture of the currently executing thread.

22.8.6.2. RequestCultureResolver

The RequestCultureResolver resolver operates similar to the DefaultWebCultureResolver, except that it always checks request headers first, and only then falls back to the value of the DefaultCulture property or the culture code of the current thread.

22.8.6.3. SessionCultureResolver

The SessionCultureResolver resolver looks for culture information in the user's session and returns the information if it finds it. If not, SessionCultureResolver falls back to the behavior of the DefaultWebCultureResolver.

22.8.6.4. CookieCultureResolver

This resolver looks for culture information in a cookie, and return it if it finds one. If not, it falls back to the behavior of the DefaultWebCultureResolver.

[Warning]Warning

CookieCultureResolver does not work if your application uses localhost as the server URL, which is a typical setting in a development environment.

To work around this limitation, use SessionCultureResolver during development and switch to CookieCultureResolver before you deploy the application in a production. This is easily accomplished in Spring.Web (simply change the config file) but is something that you should be aware of.

22.8.7. Changing cultures

To change the culture, application developers need to define one of the culture resolvers that support culture changes, such as SessionCultureResolver or CookieCultureResolver in the Spring application context. For example,

You also can write a custom ICultureResolver that persists culture information in a database, as part of a user's profile.

  <object id="cultureResolver" type="Spring.Globalization.Resolvers.SessionCultureResolver, Spring.Web" />

Once that requirement is satisfied, you set the UserCulture property to a new CultureInfo object before the page is rendered. In the following .aspx example, two link buttons can be used to change the user's culture. In the code-behind, this is all one need do to set the new culture. A code snippet for the code-behind file (UserRegistration.aspx.cs) is shown below.

protected override void OnInit(EventArgs e)
{
    InitializeComponent();

    this.english.Command += new CommandEventHandler(this.SetLanguage);
    this.serbian.Command += new CommandEventHandler(this.SetLanguage);

    base.OnInit(e);
}

private void SetLanguage(object sender, CommandEventArgs e)
{
    this.UserCulture = new CultureInfo((string) e.CommandArgument);
}

22.9. Result mapping

In many ASP.NET applications, no built-in way exists to externalize the flow of the application. The most common way of defining application flow is by hardcoding calls to the Response.Redirect and Server.Transfer methods within event handlers.

This approach is problematic because any changes to the flow of an application necessitates code changes (with the attendant recompilation, testing, redeployment, and so on). A better way, which works in many MVC ( Model-View-Controller) web frameworks, is to enable you to externalize the mapping of action results to target pages.

Spring.Web adds this functionality to ASP.NET by allowing you to define result mappings within the definition of a page, and to then simply use logical result names within event handlers to control application flow.

In Spring.Web, a logical result is encapsulated and defined by the Result class; thus you can configure results like any other object:

<objects xmlns="http://www.springframework.net">

    <object id="homePageResult" type="Spring.Web.Support.Result, Spring.Web">
        <property name="TargetPage" value="~/Default.aspx"/>
        <property name="Mode" value="Transfer"/>
        <property name="Parameters">
            <dictionary>
                <entry key="literal" value="My Text"/>
                <entry key="name" value="%{UserInfo.FullName}"/>
                <entry key="host" value="%{Request.UserHostName}"/>
            </dictionary>
        </property>
    </object>

    <object id="loginPageResult" type="Spring.Web.Support.Result, Spring.Web">
        <property name="TargetPage" value="Login.aspx"/>
        <property name="Mode" value="Redirect"/>
    </object>

    <object type="UserRegistration.aspx" parent="basePage">
        <property name="UserManager" ref="userManager"/>
        <property name="Results">
            <dictionary>
                <entry key="userSaved" value-ref="homePageResult"/>
                <entry key="cancel" value-ref="loginPageResult"/>
            </dictionary>
        </property>
    </object>

</objects>

The only property for which you must supply a value for each result is the TargetPage property. The value of the Mode property can be Transfer, TransferNoPreserve, or Redirect, and defaults to Transfer if none is specified. TransferNoPreserve issues a server-side transfer with 'preserveForm=false', so that QueryString and Form data are not preserved.

If your target page requires parameters, you can define them with the Parameters dictionary property. You specify literal values or object navigation expressions for such parameter values. An expression is evaluated in the context of the page in which the result is being referenced. In the preceding example, any page that uses the homePageResult needs to expose a UserInfo property on the page class itself.

[Note]Note

In Spring.NET 1.1.0 and earlier, the prefix indicated an object navigation expression in the Parameters dictionary property was the dollar sign, for example, ${UserInfo.FullName}.This convention conflicted with the prefix used to perform property replacement, the dollar sign, as described in the section PropertyPlaceholderConfigurer. As a workaround you can differentiate the prefix and suffix used in PropertyPlaceholderConfigurer, for example prefix = $${ and suffix = }. In Spring. NET 1.1.1, a new prefix character, the percent sign (i.e.%{UserInfo.FullName}.) can be used in the Parameters dictionary to avoid this conflict , so you can keep the familiar NAnt style PropertyPlaceholderConfigurer defaults.

Parameters are handled differently depending on the result mode. For redirect results, every parameter is converted to a string, then URL encoded, and finally appended to a redirect query string. Parameters for transfer results are added to the HttpContext.Items collection before the request is transferred to the target page. Transfers are more flexible because any object can be passed as a parameter between pages. They are also more efficient because they don't require a round-trip to the client and back to the server, so transfer mode is recommended as the preferred result mode (it is also the current default).

[Tip]Tip

If you need to customize how a redirect request is generated, for example, to encrypt the request parameters, subclass the Request object and override one or more protected methods, for example string BuildUrl( string resolvedPath, IDictionary resolvedParameters ). See the API documentation for additional information.

The preceding example shows independent result object definitions, which are useful for global results such as a home- and login- page. Result definitions are only used by one page should be simply embedded within the definition of a page, either as inner object definitions or using a special shortcut notation for defining a result definition:

<object type="~/UI/Forms/UserRegistration.aspx" parent="basePage">
  <property name="UserManager">
    <ref object="userManager"/>
  </property>

  <property name="Results">
    <dictionary>
      <entry key="userSaved" value="redirect:UserRegistered.aspx?status=Registration Successful,user=${UserInfo}"/>
      <entry key="cancel" value-ref="homePageResult"/>
    </dictionary>
  </property>
</object>

The short notation for the result must adhere to the following format...

[<mode>:]<targetPage>[?param1,param2,...,paramN]

Possible values for the mode value referred to in the preceding notation snippet:

  • redirect: calls Response.Redirect(string)

  • redirectNoAbort: calls Response.Redirect(string, false)

  • transfer: calls Server.Transfer(string)

  • TransferNoPreserve: calls Server.Transfer(string, false)

These values correspond to the values of the ResultMode enumeration. A comma separates parameters instead of an ampersand; this avoids laborious ampersand escaping within an XML object definition. The use of the ampersand character is still supported if required, but you then have to specify the ampersand character using the well known & entity reference.

After you define your results, you can use them within the event handlers of your pages (UserRegistration.apsx.cs):

private void SaveUser(object sender, EventArgs e)
{
    UserManager.SaveUser(UserInfo);
    SetResult("userSaved");
}

public void Cancel(object sender, EventArgs e)
{
    SetResult("cancel");
}

protected override void OnInit(EventArgs e)
{
    InitializeComponent();

    this.saveButton.Click += new EventHandler(this.SaveUser);
    this.cancelButton.Click += new EventHandler(this.Cancel);

    base.OnInit(e);
}

You can further refactor the preceding example and use defined constants, which is advisable when a logical result name such as "home" is likely to be referenced by many pages.

22.9.1. Registering user defined transfer modes

You can also register a custom interpreter that can parse the shorthand string representation that creates a Result object. To do this you should view the result mapping string representation as consisting of two parts:

<resultmode>:<textual result representation>

The interface IResultFactory is responsible for creating an IResult object from these two pieces:

public interface IResultFactory
{
    IResult CreateResult( string resultMode, string resultText );
}

You use a ResultFactoryRegistry to associate a given resultmode string with an IResultFactory implementation:

class MySpecialResultLogic : IResult
{
  ...
}

class MySpecialResultLogicFactory : IResultFactory
{
   IResult Create( string mode, string expression ) {
     /* ... convert 'expression' into MySpecialResultLogic */
   }
}

// register with global factory
ResultFactoryRegistry.RegisterResultFactory( "mySpecialMode", new MySpecialResultLogicFactory );

You then use the custom continue mode in your page:

<-- configure your Results -->
<object type="mypage.aspx">
   <property name="Results">
      <dictionary>
         <entry key="continue" value="mySpecialMode:<some MySpecialResultLogic string representation>" />
      </dictionary>
   </property>
</object>

The result redirection is done as before, by calling myPage.SetResult("cancel");

22.10. Client-side scripting

ASP.NET supports client-side scripting through the use of the Page.RegisterClientScriptBlock and Page.RegisterStartupScript methods. However, neither method allows you to output a registered script markup within a <head> section of a page, which in many cases is exactly what you need to do.

22.10.1. Registering scripts within the head HTML section

Spring.Web adds several methods to enhance client-side scripting to the base Spring.Web.UI.Page class: RegisterHeadScriptBlock and RegisterHeadScriptFile, each with a few overrides. You can call these methods from your custom pages and controls in order to register script blocks and script files that must be included in the <head> section of the final HTML page.

You must use the <spring:Head> server-side control to define your <head> section instead of using the standard HTML <head> element. This is shown below.

<%@ Page language="c#" Codebehind="StandardTemplate.aspx.cs"
                AutoEventWireup="false" Inherits="SpringAir.Web.StandardTemplate" %>
<%@ Register TagPrefix="spring" Namespace="Spring.Web.UI.Controls" Assembly="Spring.Web" %>
<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.0 Transitional//EN" >
<html>
  <spring:Head runat="server" id="Head1">
    <title>
      <spring:ContentPlaceHolder id="title" runat="server">
        <%= GetMessage("default.title") %>
      </spring:ContentPlaceHolder>
    </title>
    <LINK href="<%= CssRoot %>/default.css" type="text/css" rel="stylesheet">
    <spring:ContentPlaceHolder id="head" runat="server"></spring:ContentPlaceHolder>
  </spring:Head>
  <body>
  ...
  </body>
</html>

The preceding example above shows how you typically set-up a <head> section within a master page template to be able to change the title value and to add additional elements to the <head> section from the child pages using <spring:ContentPlaceholder> controls. However, only the <spring:Head> declaration is required in order for Spring.NET Register* scripts to work properly.

22.10.2. Adding CSS definitions to the head section

In a similar fashion, you can add references to CSS files, or even specific styles, directly to the <head> HTML section using Page.RegisterStyle and Page.RegisterStyleFile methods. The latter one simply allows you to include a reference to an external CSS file, while the former one allows you to define embedded style definitions by specifying the style name and definition as the parameters. The final list of style definitions registered this way will be rendered within the single embedded style section of the final HTML document.

22.10.3. Well-known directories

To make the manual inclusion of client-side scripts, CSS files and images easier, the Spring.Web Page class exposes several properties that help you reference such artifacts with absolute paths. This capability gives web application developers convenience functionality straight out of the box if they stick to common conventions such as a web application (directory) structure.

These properties are ScriptsRoot, CssRoot and ImagesRoot. They have default values of Scripts, CSS and Images, which work well if you create and use these directories in your web application root. However, if you prefer to place them somewhere else, you can always override default values by injecting new values into your page definitions (you will typically inject these values only in the base page definition, as they are normally shared by all the pages in the application). An example of such configuration is shown below:

<object name="basePage" abstract="true">
    <description>
        Convenience base page definition for all the pages.

        Pages that reference this definition as their parent (see the examples below)
        will automatically inherit the following properties....

    </description>
    <property name="CssRoot" value="Web/CSS"/>
    <property name="ImagesRoot" value="Web/Images"/>
</object>

22.11. Spring user controls

Spring provides several custom user controls that are located in the Spring.Web.UI.Controls namespace. This section lists the controls and points to other documentation to provide additional information. Check the SDK docs for descriptions of controls that are not mentioned here.

22.11.1. Validation controls

You can specify the location in the web page where validation errors are to be rendered by using the ValidationSummary and ValidationError controls. Two controls exist because they have different defaults for how errors are rendered. ValidationSummary is used to display potentially multiple errors identified by the validation framework. ValidationError is used to display field-level validation errors. Please refer to the section ASP.NET usage tips in the chapter on the Validation Framework more information.

22.11.2. Databinding controls

Some standard controls are not easy to use with Spring's databinding support. Examples are check boxes and ratio button groups. Here you should use the CheckBoxList and RadioButtonGroup controls. You can do databinding itself by using the DataBindingPanel instead of the using the BindingManager API within the code behind page.

22.11.3. Calendar control

A pop-up DHTML calendar control is provided. It is a slightly modified version of the Dynarch.com DHTML Calendar control written by Mihai Bazon.

22.11.4. Panel control

You can suppress dependency injection for controls inside your ASP.NET by using the Panel control. See Customizing control dependency injection .