Software Maintenance and Evolution

5.00 credits

30.0 h + 15.0 h

Teacher(s)

Mens Kim;

Language

English

Main themes

Whereas many software engineering courses focus on building new systems from scratch, in industrial practice software developers are often confronted with already existing software systems that need to be maintained, reused or evolved. This requires specific skills to understand the design and implementation of an existing system and which parts need to be modified, to build software systems that are easier to maintain, and to design systems with reuse and evolution in mind from the very start.

This course will thus study a variety of techniques, tools and methodologies to help building software systems that are easier to understand, maintain, reuse and evolve, such as:

Preliminaries and definitions :
               - need for and problems of software maintenance and evolution
               - definitions, differences between and types of software maintenance and evolution
               - technical debt
               - laws of software evolution

Domain modelling :
               - software product lines
               - domain analysis
               - feature modelling
               - commonalities and variabilities
               - feature diagrams

Software reuse :
               - definition of and needs for software reuse
               - reuse techniques and design for reuse
               - object-oriented techniques for reuse and maintainability
               - object-oriented application frameworks

Software maintenance and evolution :
               - Best programming practices and coding standards
               - Code refactoring and reengineering
               - Bad code smells
               - Software and design patterns
               - Design principles and heuristics

An industrial case study

Learning outcomes

At the end of this learning unit, the student is able to :

Given the learning outcomes of the "Master in Computer Science and Engineering" program, this course contributes to the development, acquisition and evaluation of the following learning outcomes:

INFO1.1 , INFO1.3
INFO2.5
INFO5.5

Given the learning outcomes of the "Master [120] in Computer Science" program, this course contributes to the development, acquisition and evaluation of the following learning outcomes:

SINF1.M3
SINF2.5
SINF5.5

Students completing successfully this course will be able to

Understand the difficulties of developing code in a change context as opposed to 'green field' development
Assess the impact of a change request to an existing product of medium size.
Describe techniques, coding idioms and other mechanisms for implementing designs that are more maintainable.
Understand how design patterns can improve the design of a software system.
Refactor an existing software implementation to improve some aspect of its design.
Identify the principal issues associated with software evolution and explain their impact on the software lifecycle.'
Discuss the advantages and disadvantages of different types of software reuse.

Content

The course will cover a variety of techniques, tools and methodologies to help building software systems that are easier to understand, maintain, reuse and evolve.
Preliminaries:

Definitions and difference between software maintenance, software evolution and software reuse
Different types of software maintenance and evolution
Causes for software maintenance and change
Technical debt
Laws of software evolution

Domain modelling:

Domain modelling and domain analysis
Software product lines
Feature-oriented domain analysis
Feature modelling, commonalities and variabilities
Feature relationships, dependencies and cross-tree constraints
Semantics of feature models and feature model anomalies

Software reuse:

Definitions of reusability, software reuse and reusable components
How object-oriented programming promotes modularity, maintainability and reuse
Encapsulation, information hiding, polymorphism and code sharing
Key object-oriented concepts: object, classes, methods, messages, inheritance
Polymorphism and dynamic binding
Method overriding, self and super calls
Abstract classes and methods
Different kinds of inheritance: single, multiple, interfaces, mixins

Bad code smells:

Bad smells
Bad smells vs. refactorings
Bad smell categories and examples
Coupling and cohesion

Code refactoring:

Refactoring (definitions, motivations, when should you refactor)
Refactoring categories and examples
Refactoring vs. code quality
Merge conflicts due to refactoring

Software patterns:

Christopher Alexander’s building architectural patterns
(Software) design patterns (definitions, motivations, structure)
Abstract Factory design pattern
Factory Method design pattern
Strategy and Decorator design patterns
Antipattern (definition, purpose, example: The Blob)
The 7 deadly sins

Design heuristics:

Design heuristics (definition, purpose, examples)
Design heuristics related to inheritance and polymorphism
Design heuristics related to cohesion
Design heuristics related to coupling

Application frameworks:

Object-oriented application frameworks (definition, purpose, examples)
How frameworks can achieve software reuse
Inversion of Control (the “Hollywood” principle)
Software frameworks vs. libraries
Hotspots and hook methods
Commonality and variability
White vs. grey vs. black box frameworks
Template method design pattern
Design patterns vs. frameworks
Refactoring to a framework
Using template methods to evolve an application into a framework
Refactoring to specialise or generalise class hierarchies

Industrial case study (invited speech by a selected company)
Additional research-related sessions (if time remains) on selected topics such as:

Context-Oriented Software
Reflection and metaprogramming
Aspect-oriented programming

Teaching methods

Theory sessions covering the different course topics
Practical sessions to apply the concepts in practice
Missions to experience the problems related to and solutions for developing and evolving a maintainable and reusable software system.
Invited presentation by a company to illustrate some of the course topics applied in industrial practice.
Optionally some sessions on a theme related to research in the area of software maintenance, reuse and evolution.

Evaluation methods

The course evaluation will be a weighted average of:

10% based on active participation during practical sessions
30 to 40% based on 2 to 3 missions throughout the semester linked to the practical sessions
50 to 60% during the exam session based on
- written answers to theoretical exam questions
- oral presentation related to the missions carried out throughout the semester

For the August exam session, the missions throughout the semester cannot be retaken, only the part of the score related to the exam session.
As for the course, all course evaluations will be in English.

Other information

Even though good quality software may be easier to maintain and evolve, software quality assurance techniques will not be addressed explicitly in this course as they are the topic of a separate course on Software Quality Assurance [LINGI2251]
Expected background:

Having a good knowledge of and experience with object-oriented programming concepts, algorithms and data structures.
Having prior or simultaneous experience with the development of a medium- to large-scale software system.

Online resources

Moodle course website
The course slides as well as other relevant and practical information related to the course will be accessible on Moodle. The same platform will also be the means of communication between the teacher(s) and the students.

Bibliography

French

Compte tenu de la variété des sujets abordés, ce cours ne suivra pas un seul livre de référence, mais sera basé sur du matériel provenant de nombreuses sources différentes. Les slides de cours seront le matériel de référence principale pour ce cours et des pointeurs vers des lectures supplémentaires seront fournis par la plate-forme de cours en ligne.

English

Given the variety of topics covered, this course will not follow a single textbook but is based on material from many different sources. As such, the course slides will be the main reference material for this course and pointers to additional reading material will be provided through the online course platform.

Faculty or entity

INFO

Programmes / formations proposant cette unité d'enseignement (UE)

Title of the programme

Sigle

Credits

Prerequisites

Learning outcomes

Master [120] in Computer Science and Engineering

INFO2M

Master [120] in Computer Science

SINF2M