Software component representations: above the representation used in UML, below the representation commonly used by Microsoft's COM objects. The "lollipops" sticking out from the components are their interfaces. Note the characteristic IUnknown interface of the COM component.

Software componentry is a field of study within software engineering. It builds on prior theories of software objectss, software architectures, software frameworks and software design patterns, and the extensive theory of object-oriented programming and object-oriented design of all these. It claims that software components, like the idea of a hardware component used e.g. in telecommunication, can be ultimately made interchangeable and reliable.

A software component is a software technology for encapsulating software functionality, often in the form of objectss (from Object Oriented Programming), in some binary or textual form, adhering to some interface description language (IDL) so that the component may exist autonomously from other components in a computer.

Software componentry is a common and convenient means for inter-process communication (IPC).

Table of contents
1 History of Software Components
2 Differences between Object Oriented Programming and Software Components
3 Architecture
4 Technologies for Software Components
5 See also
6 External links

History of Software Components



Image from
Douglas McIlroy's historic lecture on software components at the NATO conference in Garmisch, Germany.

The idea that software should be componetized - built from prefabricated components - was first published in Douglas McIlroy's address at the NATO conference on software engineering in Garmisch, Germany, 1968 titled Mass Produced Software Components. This conference set out to counter the so-called software crisis. His subsequent inclusion of pipes and filters into the Unix operating system was the first implementation of an infrastructure for this idea.

The modern concept of a software component was largely defined by Brad Cox of Stepstone, who called them Software ICs and set out to create an infrastructure and market for these components by inventing the Objective C programming language. (He summarizes this view in his book Object-Oriented Programming - An Evolutionary Approach 1986.) Cox's attempt did not succeed.

Microsoft paved the way for actual deployment of component software with OLE and COM, a very successful attempt to encapsulate and simplify object interfaces. Nowadays several different successful software component models exist.

Differences between Object Oriented Programming and Software Components

The basic idea in object-oriented programming (OOP) is that software should be written according to a mental model of the actual or imagined objects it represents. OOP and the related disciplines of object-oriented design and object-oriented analysis focus on modelling real-world interactions and attempting to create 'verbs' and 'nouns' which can be used in intuitive ways, ideally by end users as well as by programmers coding for those end users.

Software components, by contrast, makes no such assumptions, and instead states that software should be developed by gluing prefabricated components together much like in the field of electronics or mechanics. It accepts that the definitions of useful components, unlike objects, can be counter-intuitive. In general it discourages anthropomorphism and naming, and is far more pessimistic about the potential for end user programming. Some peers will even talk of software components in terms of a new programming paradigm: component-oriented programming.

Some argue that this distinction was made by earlier computer scientists, with Donald Knuth's theory of "literate programming" optimistically assuming there was convergence between intuitive and formal models, and Edsger Dijkstra's theory in the article The Cruelty of Really Teaching Computer Science, which stated that programming was simply, and only, a branch of mathematics.

In both forms, this notion has led to many academic debates about the pros and cons of the two approaches and possible strategies for uniting the two. Some consider them not really competitors, but only descriptions of the same problem from two different points of view.

It takes significant effort and awareness to write a software component that is reusable effectively. The component needs:

  • to be fully documented;
  • more thorough testing;
  • robust input validity checking;
  • to pass back useful error messages as appropriate;
  • to be built with an awareness that it will be put to unforeseen uses.

Architecture

A computer running several software components is called an application server. Using this combination of application servers and software components is usually called distributed computing. The usual real-world application of this is in financial applications or business software.

Distributed computing with software components is popular with its vendors, but appropriate scepticism is recommended for the end user.

Technologies for Software Components

See also

External links