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Component-based Software Engineering

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Title: Component-based Software Engineering


1
Component-based Software Engineering
Motivations
  • Marcello Bonsangue
  • LIACS Leiden University
  • Fall 2005

2
Component-based Software Engineering
  • Main concerns
  • Development of software from pre-produced parts
  • Reuse of those parts in other applications
  • Easily maintaining and customizing those parts to
    produce new features
  • Goals (users demands)
  • Build more reliable software
  • Less time between versions

3
Component everywhere
  • Concerns and goals are similar in many other
    engineering disciplines
  • Precise assembly of reusable, well-documented,
    quality and trusted parts
  • For them components are well established
  • Civil engineering -gt house prefab,
  • Chemical engineering-gt proteins,
  • Electronic engineering-gt circuit,
  • Industrial engineering -gt cars,

4
Example the automobile lesson
  • Car assembly was a costly, tedious and slow
    process
  • Henry Ford lifes goal
  • Produce cars for the masses by building them
    faster
  • Fords method
  • The assembly line (1914)
  • Idea by reversing the process of beef- trolleys
    butchers removed cuts from the carcass passed by
    until nothing remained.

5
But why not in Software engineering?
  • If the goals of CBSE are no different from
    industrial and civil engineering why is CBS an
    hype only now?
  • Industrial and civil engineering develop final
    products
  • Software is a generic meta-product that can be
    used to create families of instances
  • using different parametrizations

6
Standards
  • Industrial and civil engineering successfully
    develop components because of standards,
    regulations and laws.
  • Before the software crisis (1968) software had no
    standard.

7
Too less, too much
  • Custom-made software
  • Flexible, competitive, if it works
  • Maintenance, interoperability are serious
    problems
  • Very long time to market
  • Fully standard software
  • Short time to market
  • Maintenance, interoperability and evolution are
    vendor business
  • Hard to be competitive, hard to adapt

8
Standard needed
  • Interaction standard for specifying the explicit
    context dependency on other software elements
  • Composition standard for defining how components
    can be composed to create a larger structure and
    how a producer can replace one existing component
    with another one.

9
What are components? (I)
  • A software component is not different from other
    software elements because of the programming
    language used to implement it
  • The difference must be in how software components
    are used
  • Components are not for real programmers.
  • They are for software users
  • Components are for composition
  • Parts can be reused by rearranging them

10
Software users
  • The PC revolution and the Internet have
    interjected a new heavy weight in the software
    arena the software consumer.
  • Before consumerization of software
  • Turn every user into a programmer.
  • After consumerization of software
  • Turn every human into a software user.

11
Two approaches to reuse
  • Design a system monolithically and then find the
    parts (top-down)
  • Often parts are not reusable
  • Design the parts and then compose them into a
    system (bottom-up)
  • Parts must be general (to be really reusable)
  • but not too much (to remain practicable)

12
Software components
  • A software components is a software element that
  • conforms to specific interactions and composition
    standards
  • can be independently deployed and composed
    without modification (according to a composition
    standard)

13
What is not a component
  • The requirement for independence rules out
  • Type declarations
  • C macros
  • C templates
  • Smalltalk blocks

14
What could be a component
  • Procedures
  • Libraries
  • Classes (not objects)
  • Modules

15
What is a component
  • Coarse grain
  • Applications executing in the environment
    provided by an operating system
  • Finer grain
  • Web browsers plug-ins
  • Microsoft Office documents
  • Spreadsheet, document, email, web-page, database,
    presentation

16
Neither custom nor fully-standard
  • Conformity to interaction and composition
    standards allow for
  • robust integration
  • fast time to market
  • and rules out custom-made software
  • Whereas independence is essential to allow for
  • multiple independent vendors
  • independent development
  • and rules out fully-standard software

17
Component abstraction levels
  • To design and develop the internals of a
    components we distinguish four levels of
    abstraction
  • Component specification
  • Component implementation
  • Component executable
  • Component deployment
  • The process can be carried out using techniques
    like UML and OO programming languages, and
    methodologies supporting component production.

18
Component specification
  • It includes the technology independent definition
    of the component but also information to
    facilitate the finding of a component (gap
    fulfilment)
  • It may derives from
  • Component producers desire
  • Solution builders specific needs
  • Industry standard for interactions and
    compositions

19
Component implementation
  • It defines the inside of a component, with its
    internal parts and collaborations.
  • It occurs after the decision of the programming
    language to use for the development
  • It must satisfies the specification
  • One-to-many relationship

20
Component executable
  • It is the real pluggable component used in the
    assembly of the application
  • Each executable may results in more than one
    version
  • There may be more than one executable per
    implementation

21
Component deployment
  • It is the deployment of the component executable
    on a number of nodes
  • There may be several deployment for the same
    executable.

22
Component production
  • A methodology for the production of components
    must support the four component abstraction
    levels
  • It is different from traditional software
    production
  • More time is spent for business rules, business
    process modelling, analysis, and design
  • Less time is spent in development
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