1、Chapter 16 Software Reuse,1,Ian Sommerville, Software Engineering, 9th Edition Pearson Education, Addison-Wesley,CS 425 November 15, 2010,Note: These are a modified version of Ch 16 slides available from the authors site http:/www.cs.st-andrews.ac.uk/ifs/Books/SE9/,Topics covered,The reuse landscape
2、 Application frameworks Software product lines COTS product reuse,Chapter 16 Software reuse,2,Software reuse,In most engineering disciplines, systems are designed by composing existing components that have been used in other systems. Software engineering has been more focused on original development
3、 but it is now recognised that to achieve better software, more quickly and at lower cost, we need a design process that is based on systematic software reuse. There has been a major switch to reuse-based development over the past 10 years.,Reuse-based software engineering,Application system reuse T
4、he whole of an application system may be reused either by incorporating it without change into other systems or by developing application families (common architecture). Component reuse Components of an application from sub-systems to single objects may be reused. Covered in Chapter 17. Object and f
5、unction reuse Software components that implement a single well-defined object or function may be reused.,Benefits of software reuse,5,Chapter 16 Software reuse,Benefits of software reuse,6,Chapter 16 Software reuse,Problems with reuse,7,Chapter 16 Software reuse,Problems with reuse,8,Chapter 16 Soft
6、ware reuse,The reuse landscape,Although reuse is often simply thought of as the reuse of system components, there are many different approaches to reuse that may be used. Reuse is possible at a range of levels from simple functions to complete application systems. The reuse landscape covers the rang
7、e of possible reuse techniques.,The reuse landscape,10,Chapter 16 Software reuse,Approaches that support software reuse,11,Chapter 16 Software reuse,Approaches that support software reuse,12,Chapter 16 Software reuse,Approaches that support software reuse,13,Chapter 16 Software reuse,Reuse planning
8、factors,The development schedule for the software. e.g. to develop quickly: use COTS instead of individual components. The expected software lifetime. Long life system: focus on the maintainability of the system The background, skills and experience of the development team. Focus on areas where the
9、development team has good skills The criticality of the software and its non-functional requirements. e.g. be careful when using COTS for a critical system.,Reuse planning factors,The application domain. e.g. manufacturing and medical information systems The execution platform for the software. e.g.
10、 .NET is specific to Microsoft platforms,Application frameworks,Frameworks are moderately large entities that can be reused. They are somewhere between system and component reuse. Frameworks are a sub-system design made up of a collection of abstract and concrete classes and the interfaces between t
11、hem. The sub-system is implemented by adding components to fill in parts of the design and by instantiating the abstract classes in the framework.,Framework classes,System infrastructure frameworks Support the development of system infrastructures such as communications, user interfaces and compiler
12、s. Middleware integration frameworks Standards and classes that support component communication and information exchange (e.g. Microsoft .NET). Enterprise application frameworks Support the development of specific types of application such as telecommunications or financial systems. Embed applicatio
13、n domain knowledge and supports the development of end-user applications.,Web application frameworks (WAFs),WAFs are a more recent and very important type of framework. Support the construction of dynamic websites as a front-end for web applications. WAFs are now available for all of the commonly us
14、ed web programming languages e.g. Java, Python, Ruby, etc. Interaction model is based on the Model-View-Controller composite pattern.,Chapter 16 Software reuse,18,Model-view controller,Originally proposed in the 1980s. System infrastructure framework for GUI design. Allows for multiple presentations
15、 of an object and separate interactions with these presentations. When the data is modified through one of the presentations, the system model is changed and the controllers associated with each view update their presentation. MVC framework involves the instantiation of a number of patterns (as disc
16、ussed in Chapter 7) (e.g. Observer pattern, Strategy pattern, etc.).,The Model-View-Controller pattern,20,Chapter 16 Software reuse,WAF features,Security WAFs may include classes to help implement user authentication (login) and access. Dynamic web pages Classes are provided to help you define web p
17、age templates and to populate these dynamically from the system database. Database support The framework may provide classes that provide an abstract interface to different databases. Session management Classes to create and manage sessions (a number of interactions with the system by a user) are us
18、ually part of a WAF. User interaction Most web frameworks now provide AJAX support (Holdener, 2008), which allows more interactive web pages to be created.,Chapter 16 Software reuse,21,Extending frameworks,Frameworks are generic and are extended to create a more specific application or sub-system. T
19、hey provide a skeleton architecture for the system. Extending the framework involves Adding concrete classes that inherit operations from abstract classes in the framework; Adding methods that are called in response to events that are recognised by the framework. Problem with frameworks is their com
20、plexity which means that it takes a long time to use them effectively.,Inversion of control in frameworks,23,Chapter 16 Software reuse,Software product lines,Software product lines or application families are applications with generic functionality that can be adapted and configured for use in a spe
21、cific context. A software product line is a set of applications with a common architecture and shared components, with each application specialized to reflect different requirements. Adaptation may involve: Component and system configuration; Adding new components to the system; Selecting from a lib
22、rary of existing components; Modifying components to meet new requirements.,Application frameworks and product lines,Application frameworks rely on object-oriented features such as polymorphism to implement extensions. Product lines need not be object-oriented (e.g. embedded software for a mobile ph
23、one) Application frameworks focus on providing technical rather than domain-specific support. Product lines embed domain and platform information. Product lines often control applications for equipment. Software product lines are made up of a family of applications, usually owned by the same organiz
24、ation.,Chapter 16 Software reuse,25,Product line specialisation,Platform specialization Different versions of the application are developed for different platforms. Environment specialization Different versions of the application are created to handle different operating environments e.g. different
25、types of communication equipment. Functional specialization Different versions of the application are created for customers with different requirements. Process specialization Different versions of the application are created to support different business processes.,Product line architectures,Archit
26、ectures must be structured in such a way to separate different sub-systems and to allow them to be modified. The architecture should also separate entities and their descriptions and the higher levels in the system access entities through descriptions rather than directly.,The architecture of a reso
27、urce allocation system,28,Chapter 16 Software reuse,The product line architecture of a vehicle dIspatcher,29,Chapter 16 Software reuse,Vehicle dispatching,A specialised resource management system where the aim is to allocate resources (vehicles) to handle incidents. Adaptations include: At the UI le
28、vel, there are components for operator display and communications; At the I/O management level, there are components that handle authentication, reporting and route planning; At the resource management level, there are components for vehicle location and despatch, managing vehicle status and inciden
29、t logging; The database includes equipment, vehicle and map databases.,Product instance development,31,Chapter 16 Software reuse,Product instance development,Elicit stakeholder requirements Use existing family member as a prototype Choose closest-fit family member Find the family member that best me
30、ets the requirements Re-negotiate requirements Adapt requirements as necessary to capabilities of the software Adapt existing system Develop new modules and make changes for family member Deliver new family member Document key features for further member development,Product line configuration,Design
31、 time configuration The product line is adapted and changed according to the requirements of particular customers. Deployment time configuration The product line is configured by embedding knowledge of the customers requirements and business processes. The software source code itself is not changed.
32、,Deployment-time configuration,34,Chapter 16 Software reuse,Levels of deployment time configuration,Component selection, where you select the modules in a system that provide the required functionality. Workflow and rule definition, where you define workflows (how information is processed, stage-by-
33、stage) and validation rules that should apply to information entered by users or generated by the system. Parameter definition, where you specify the values of specific system parameters that reflect the instance of the application that you are creating,Chapter 16 Software reuse,35,COTS product reus
34、e,A commercial-off-the-shelf (COTS) product is a software system that can be adapted for different customers without changing the source code of the system. COTS systems have generic features and so can be used/reused in different environments. COTS products are adapted by using built-in configurati
35、on mechanisms that allow the functionality of the system to be tailored to specific customer needs. For example, in a hospital patient record system, separate input forms and output reports might be defined for different types of patient.,Chapter 16 Software reuse,36,Benefits of COTS reuse,As with o
36、ther types of reuse, more rapid deployment of a reliable system may be possible. It is possible to see what functionality is provided by the applications and so it is easier to judge whether or not they are likely to be suitable. Some development risks are avoided by using existing software. However
37、, this approach has its own risks, as I discuss below. Businesses can focus on their core activity without having to devote a lot of resources to IT systems development. As operating platforms evolve, technology updates may be simplified as these are the responsibility of the COTS product vendor rat
38、her than the customer.,Chapter 16 Software reuse,37,Problems of COTS reuse,Requirements usually have to be adapted to reflect the functionality and mode of operation of the COTS product. The COTS product may be based on assumptions that are practically impossible to change. Choosing the right COTS s
39、ystem for an enterprise can be a difficult process, especially as many COTS products are not well documented. There may be a lack of local expertise to support systems development. The COTS product vendor controls system support and evolution.,Chapter 16 Software reuse,38,COTS-solution and COTS-inte
40、grated systems,39,Chapter 16 Software reuse,COTS solution systems,COTS-solution systems are generic application systems that may be designed to support a particular business type, business activity or, sometimes, a complete business enterprise. For example, a COTS-solution system may be produced for
41、 dentists that handles appointments, dental records, patient recall, etc. Domain-specific COTS-solution systems, such as systems to support a business function (e.g. document management) provide functionality that is likely to be required by a range of potential users.,Chapter 16 Software reuse,40,E
42、RP systems,An Enterprise Resource Planning (ERP) system is a generic system that supports common business processes such as ordering and invoicing, manufacturing, etc. These are very widely used in large companies - they represent probably the most common form of software reuse. The generic core is
43、adapted by including modules and by incorporating knowledge of business processes and rules.,The architecture of an ERP system,42,Chapter 16 Software reuse,ERP architecture,A number of modules to support different business functions. A defined set of business processes, associated with each module,
44、which relate to activities in that module. A common database that maintains information about all related business functions. A set of business rules that apply to all data in the database.,Chapter 16 Software reuse,43,ERP configuration,Selecting the required functionality from the system. Establish
45、ing a data model that defines how the organizations data will be structured in the system database. Defining business rules that apply to that data. Defining the expected interactions with external systems. Designing the input forms and the output reports generated by the system. Designing new busin
46、ess processes that conform to the underlying process model supported by the system. Setting parameters that define how the system is deployed on its underlying platform.,Chapter 16 Software reuse,44,COTS integrated systems,COTS-integrated systems are applications that include two or more COTS produc
47、ts and/or legacy application systems. You may use this approach when there is no single COTS system that meets all of your needs or when you wish to integrate a new COTS product with systems that you already use.,Chapter 16 Software reuse,45,Design choices,Which COTS products offer the most appropri
48、ate functionality? Typically, there will be several COTS products available, which can be combined in different ways. How will data be exchanged? Different products normally use unique data structures and formats. You have to write adaptors that convert from one representation to another. What featu
49、res of a product will actually be used? COTS products may include more functionality than you need and functionality may be duplicated across different products.,Chapter 16 Software reuse,46,A COTS-integrated procurement system,47,Chapter 16 Software reuse,Service-oriented COTS interfaces,COTS integ
50、ration can be simplified if a service-oriented approach is used. A service-oriented approach means allowing access to the application systems functionality through a standard service interface, with a service for each discrete unit of functionality. Some applications may offer a service interface but, sometimes, this service interface has to be implemented by the system integrator. You have to program a wrapper that hides the application and provides externally visible services.,
