Cargando…
Model-Driven and Software Product Line Engineering.
Many approaches to creating Software Product Lines have emerged that are based on Model-Driven Engineering. This book introduces both Software Product Lines and Model-Driven Engineering, which have separate success stories in industry, and focuses on the practical combination of them. It describes t...
| Clasificación: | Libro Electrónico |
|---|---|
| Autor principal: | |
| Otros Autores: | |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
London :
Wiley,
2013.
|
| Colección: | ISTE.
|
| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Cover; Title Page; Copyright; Chapter 1. Introduction; 1.1. Software product line engineering; 1.2. Model-driven engineering; 1.3. Merging model-driven and software product line engineering; 1.4. The FieSta framework; 1.5. Book structure; Chapter 2. Software Product Line Engineering Basics; 2.1. Introduction to product line engineering; 2.2. Brief history; 2.3. Application example: Smart-Home systems; 2.3.1. Smart-Home system's domain; 2.3.2. Requirements of the application example; 2.4. Software product line engineering; 2.5. Domain engineering; 2.5.1. Component-based software engineering.
- 2.6. Variability management2.6.1. Feature modeling; 2.7. Application engineering; 2.7.1. Product configuration; 2.7.2. Product derivation; 2.8. Benefits and drawbacks; 2.9. Issues in product line; 2.9.1. Variability management; 2.9.2. Product derivation; 2.9.3. Testing; 2.9.4. Traceability; 2.9.5. Product line evolution; 2.9.6. Tool support; 2.10. Summary; Chapter 3. Model-Driven Engineering; 3.1. Introduction; 3.2. Models and metamodels; 3.2.1. The 4-level metamodeling framework; 3.2.2. The nature of models; 3.3. UML class diagrams and OCL; 3.4. Model transformations.
- 3.4.1. Scheduling of transformation rules3.4.2. Model transformation patterns; 3.4.3. Classification of model transformations; 3.4.4. Vertical model transformations; 3.4.5. Horizontal model transformations; 3.4.6. Model composition or model weaving; 3.5. Modeling framework; 3.5.1. The eclipse modeling framework; 3.5.2. The topcased toolkit; 3.6. Model transformation languages; 3.6.1. QVT; 3.6.2. ATL; 3.6.3. The openArchitectureWare framework; 3.6.4. The Xtend language; 3.7. Benefits and challenges for SPLE; 3.8. Summary; Chapter 4. Model-Driven and Software Product Line Engineering.
- 4.1. Introduction4.2. Problem space issues; 4.2.1. Separating points of views; 4.2.2. Capturing variability and configuring products; 4.2.3. Relating several points of view; 4.2.4. Configuring products in a multi-staged process; 4.3. Solution space issues; 4.4. Developing core assets; 4.4.1. Developing decision models and deriving products; 4.5. Variability expression and product configuration; 4.5.1. Metamodels; 4.5.2. Feature models; 4.6. Core asset development and product derivation; 4.6.1. Transformation rules in the Smart-Home systems SPL; 4.6.2. Creating and using decision models.
- 4.7. SummaryChapter 5. The FieSta Framework: Fine-Grained Derivation and Configuration; 5.1. Introduction; 5.1.1. Coarse-grained and fine-grained variations; 5.2. Binding models and constraint models; 5.2.1. Binding models; 5.2.2. Constraint models; 5.2.3. The cardinality property; 5.2.4. The structural dependency property; 5.2.5. The constraint metamodel and the binding metamodel; 5.2.6. Validating binding models against constraint models; 5.3. Deriving products based on constraint models and binding models; 5.3.1. The extended decision metamodel.