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专业外文翻译 题 目 基于J2EE在分布式环境下的 底层结构的自动动态配置的应用 系 （院） 专 业 班 级 学生姓名 学 号 指导教师 职 称 滨州学院教务处 二〇一〇年三月一日 滨州学院本科毕业设计（专业外文翻译） Infrastructure for Automatic Dynamic Deployment Of J2EE Application in Distributed Environments Anatoly Akkerman, Alexander Totok, and Vijay Karamcheti 1. Introduction In recent years, we have seen a significant growth in component-based enterprise application development. These applications are typically deployed on company Intranets or on the Internet and are characterized by high transaction volume, large numbers of users and wide area access. Traditionally they are deployed in a central location, using server clustering with load balancing (horizontal partitioning) to sustain user load. However, horizontal partitioning has been shown very efficient only in reducing application-related overheads of user-perceived response times, without having much effect on network-induced latencies. Vertical partitioning (e.g., running web tier and business tier in separate VMs) has been used for fault isolation and load balancing but it is sometimes impractical due to significant run-time overheads (even if one would keep the tiers on a fast local-area network) related to heavy use of remote invocations. Recent work in the context of J2EE component based applications has shown viability of vertical partitioning in wide-area networks without incurring the aforementioned overheads. The key conclusions from that study can be summarized as follows: • Using properly designed applications, vertical distribution across wide-area networks improves user-perceived latencies. • Wide-area vertical layering requires replication of application components and maintaining consistency between replicas. • Additional replicas may be deployed dynamically to handle new requests. • Different replicas may, in fact, be different implementations of the same component based on usage (read-only, read-write). • New request paths may reuse components from previously deployed paths. Applying intelligent monitoring and AI planning techniques in conjunction with the conclusions of that study, we see a potential for dynamic adaptation in industry-standard J2EE component-based applications in wide area networks Through deployment of additional application components dynamically based on active monitoring. However, in order to achieve such dynamic adaptation, we need an infrastructure for automating J2EE application deployment in such an environment. This need is quite evident to anyone who has ever tried deploying a J2EE application even on a single application server, which is a task that involves a great deal of configuration of both the system services and application components. For example one has to set up JDBC data sources, messaging destinations and other resource adapters before application components can be configured and deployed. In a wide area deployment that spans multiple server nodes, this proves even more complex, since more system services that facilitate inter-node communications need to be configured and started and a variety of configuration data, like IP addresses, port numbers, JNDI names and others have to be consistently maintained in various configuration files on multiple nodes. This distributed deployment infrastructure must be able to: • address inter-component connectivity specification and define its effects on component configuration and deployment, • address application component dependencies on application server services, their configuration and deployment, • provide simple but expressive abstractions to control adaptation through dynamic deployment and undeployment of components, • enable reuse of services and components to maintain efficient use of network nodes’ resources, • provide these facilities without incurring significant additional design effort on behalf of application programmers. In this paper we propose the infrastructure for automatic dynamic deployment of J2EE applications, which addresses all of the aforementioned issues. The infrastructure defines architecture description languages (ADL) for component and link description and assembly. The Component Description Language is used to describe application components and links. It provides clear separation of application components from system components. A flexible type system is used to define compatibility of component ports and links. A declaration and expression language for configurable component properties allows for specification of inter-component dependencies and propagation of properties between components. The Component (Replica) Assembly Language allows for assembly of replicas of previously defined components into application paths by connecting appropriate ports via link replicas and specifying the mapping of these component replicas onto target application server nodes. The Component Configuration Process evaluates an application path’s correctness, identifies the dependenciesof application components on system components, and configures component replicas for deployment. An attempt is made to match and reuse any previously deployed replicas in the new path based on their configurations. We implement the infrastructure as a part of the JBoss open source Java application server and test it on several technology sample J2EE applications – Java Pets tore, Rubies and TPC-W-NYU . The infrastructure implementation utilizes the JBoss’s extendable micro-kernel architecture, based on the JMX specification. Componentized architecture of JBoss allows incremental service deployments depending on the needs of deployed applications. We believe that dynamic reconfiguration of application servers through dynamic deployment and undeployment of system services is essential to building a resource-efficient framework for dynamic distributed deployment of J2EE applications. The rest of the paper is organized as follows. Section 2 provides necessary background for understanding the specifics of the J2EE component technology which are relevant to this study. Section 3 gives a general description of the infrastructure architecture, while section 4 goes deeper in describing particularly important and interesting internal mechanisms of the infrastructure. Section 5 describes the implementation of the framework, and related work is discussed in section 6. 2. J2EE Background 2.1 Introduction Component frameworks. A component framework is a middleware system that supports applications consisting of components conforming to certain standards. Application components are “plugged” into the component framework, which establishes their environmental conditions and regulates the interactions between them. This is usually done through containers, component holders, which also provide commonly required support for naming, security, transactions, and persistence. Component frameworks provide an integrated environment for component execution, as a result significantly reduce the effort .it takes to design, implement, deploy, and maintain applications. Current day industry component framework standards are represented by Object Management Group’s CORBA Component Model, Sun Microsystems’ Java 2 Platform Enterprise Edition (J2EE) and Microsoft’s .NET, with J2EE being currently the most popular and widely used component framework in the enterprise arena. J2EE. Java 2 Platform Enterprise Edition (J2EE) is a comprehensive standard for developing multi-tier enterprise Java applications. The J2EE specification among other things defines the following: • Component programming model, • Component contracts with the hosting server, • Services that the platform provides to these components, • Various human roles, • Compatibility test suites and compliance testing procedures. Among the list of services that a compliant application server must provide are messaging, transactions, naming and others that can be used by the application components. Application developed using J2EE adhere to the classical 3-Tier architectures – Presentation Tier, Business Tier, and Enterprise Information System (EIS) Tier (see Fig. 1). J2EE components belonging to each tier are developed adhering to the Specific J2EE standards. 1. Presentation or Web tier. This tier is actually subdivided into client and server sides. The client side hosts a web browser, applets and Java applications that communicate with the server side of presentation tier or the business tier. The server side hosts Java Servlet components, Java Server Pages (JSPs) and static web content. These components are responsible for presenting business data to the end users. The data itself is typically acquired from the business tier and sometimes directly from the Enterprise Information System tier. The server side of the presentation tier is typically accessed through HTTP(S) protocol. 2. Business or EJB tier. This tier consists of Enterprise Java Beans (EJBs) that model the business logic of the enterprise application. These components provide persistence mechanisms and transactional support. The components in the EJB tier are invoked through remote invocations (RMI), in-JVM invocations or asynchronous message delivery, depending on the type of EJB component. The EJB specification defines several types of components. They differ in invocation style (synchronous vs. asynchronous, local vs. remote) and statefulness: completely stateless (e.g., Message-Driven Bean), stateful non-persistent (e.g., Stateful Session Bean), stateful persistent (e.g., Entity Bean). Synchronously invocable EJB components expose themselves through a special factory proxy object (an EJB Home object, which is specific to a given EJB), which is typically bound in JNDI by the deployer of the EJB. The EJB Home object allows creation or location of an EJB Object, which is a proxy to a particular instance of an EJB 1. 3. Enterprise Information System (EIS) or Data tier. This tier refers to the enterprise information systems, like relational databases, ERP systems, messaging systems and the like. Business and presentation tier component communicate with this tier with the help of resource adapters as defined by the Java Connector Architecture. The J2EE programming model has been conceived as a distributed programming model where application components would run in J2EE servers and communicate with each other. After the initial introduction and first server implementations, the technology, most notably, the EJB technology has seen some a significant shift away from purely distributed computing model towards local interactions There were very legitimate performance-related reasons behind this shift, however the Distributed features are still available. The J2EE specification has seen several revisions, the latest stable being version 1.3, while version 1.4 is going through last review phases 3. We shall focus our attention on the former, while actually learning from the latter. Compliant commercial J2EE implementations are widely available from BEA Systems , IBM, Oracle and other vendors. Several open source implementations, including JBoss and JOnAS claim compatibility as well. A Recent addition to the list is a new Apache project Geronimo. 2.2 J2EE Component Programming Model Before we describe basic J2EE components, let’s first address the issue of defining what a component is a software component is a unit of composition with contractually specified interfaces and explicit context dependencies only. A software component can be deployed independently and is subject to composition by third parties.According to this definition the following entities which make up a typical J2EE application would be considered application components (some exceptions given below): • EJBs (session, entity, message-driven), • Web components (servlets, JSPs), • messaging destinations, • Data sources, EJB and Web components are deployed into their corresponding containers provided by the application server vendor. They have well-defined contracts with their containers that govern lifecycle, threading, persistence and other concerns. Both Web and EJB components use JNDI lookups to locate resources or other EJB components they want to communicate with. The JNDI context in which these lookups are performed is maintained separately for each component by its container. Bindings messaging destinations, such as topics and queues, are resources provided by a messaging service implementation. Data sources are resources provided by the application server for data access by business components into the enterprise information services (data) tier, and most commonly are exemplified by JDBC connection pools managed by the applicationServer. A J2EE programmer explicitly programs only EJBs and Web components. These custom-written components interact with each other and system services both implicitly and explicitly. For example, an EJB developer may choose explicit transaction demarcation (i.e., Bean-Managed Transactions) which means that the developer assumes the burden of writing explicit programmatic interaction with the platform’s Transaction Manager Service through well-defined interfaces. Alternatively, the developer may choose Container-Managed transaction demarcation, where transactional behavior of a component is defined through its descriptors and handled completely by the EJB container, thus acting as an implicit dependency of the EJB on the underlying Transaction Manager service. 2.3 Links Between Components 2.3.1 Remote Interactions J2EE defines only three basic inter-component connection types that can cross application server boundaries, in all three cases; communication is accomplished through special Java objects. • Remote EJB invocation: synchronous EJB invocations through EJB Home and EJB Object interfaces. • Java Connector outbound connection: synchronous message receipt, synchronous and asynchronous message sending, Database query using Connection Factory and Connection interfaces. • Java Connector inbound connection: asynchronous message delivery into Message-Driven Beans (MDBs) only, utilizing Activation Spec objects. In the first two cases, an application component developer writes the code that performs lookup of these objects in the component’s run-time JNDI context as well as code that issues method invocations or sends and receives messages to and from the remote component. The component’s run-time JNDI context is created for each deployment of the component. Bindings in the context are initialized at component deployment time by the deployed (usually by means of component’s deployment descriptors). These bindings are assumed to be static, since the specification does not provide any contract between the container and the component to inform of any binding changes In the case of Java Connector inbound communication, Activation Spec object lookup and all subsequent interactions