Simplicity is easily to quote but often ignored in strange ways. Perhaps this is because it is the eye of the beholder.
A language which uses fewer basic elements to achieve the same power is simpler.
Sometimes simplicity is confused with ‘easy to understand”. For example, a two-line solution which uses recursion is a pretty simple, even though some people might find it easier to work though a 10-line solution which avoids recursion.
In XML, “Processing Instructions”, those things which start with “<?” are not simple. They look simple, just an extra sort of thing in the language, but the complicate what was a very clean design of elements and attributes, and a complication in the underlying syntax is has great effect. All specifications which refer to XML processing will have to figure out what to do about processing instructions as well as elements.
When you design a system, or a language, then if the features can be broken into relatively loosely bound groups of relatively closely bound features, then that division is a good thing to be made a part of the design. This is just good engineering. It means that when you want to change the system, you can with luck in the future change only one part, which will only require you to understand (and test) that part. This will allow other people to independently change other parts at the same time. This is just classic good software design and books have been written about it. The corollary, the TOII is less frequently met.
Modular design hinges on the simplicity and abstract nature of the interface definition between the modules. A design in which the insides of each module need to know all about each other is not a modular design but an arbitrary partitioning of the bits.
Being part of a Modular Design
Its is not only necessary to make sure your own system is designed to be made of modular parts. It is also necessary to realize that your own system, no matter how big and wonderful it seems now, should always be designed to be a part of another larger system.
This is often much more difficult than modularity.
Be liberal in what you require but conservative in what you do.
This is the expression of a principle which applies pretty well in life, (it is a typical UU tenet), and is commonly employed in design across the Internet.
Write HTML 4.0-strict. Accept HTML-4.0-Transitional (a superset of strict).
This principle can be contentious. When browsers are lax about what they expect, the system works better but also it encourages laxness on the part of web page writers. The principle of tolerance does not blunt the need for a perfectly clear protocol specification which draws a precise distinction between a conformance and non-conformance. The principle of tolerance is no excuse for a product which contravenes a standard.
This is a principle of the design of distributed systems, including societies. It points out that any single common point which is involved in any operation tends to limit the way the system scales, and produce a single point of complete failure.
Centralization in social systems can apply to concepts, too. For example, if we make a knowledge representation system which requires anyone who uses the concept of “automobile” to use the term “http://www.kr.org/stds/industry/automobile” then we restrict the set of uses of the system to those for whom this particular formulation of what an automobile is works. The Semantic Web must avoid such conceptual bottlenecks just as the Internet avoids such network bottlenecks.
Test of Independent Invention
If someone else had already invented your system, would theirs work with yours?
Does this system have to be the only one of its kind? This simple thought test is described in more detail in “Evolution” in these Design Issues. It is connected to modularity inside-out, designing a system not to be modular in itself, but to be a part of an as-yet unspecified larger system. A critical property here is that the system tries to do one thing well, and leaves other things to other modules. It also has to avoid conceptual or other centralization, as no two modules can claim the need to be the unique center of a larger system.
Principle of Least Power
In choosing computer languages, there are classes of program which range from the plainly descriptive (such as Dublin Core metadata, or the content of most databases, or HTML) though logical languages of limited power (such as access control lists, or conneg content negotiation) which include limited propositional logic, though declarative languages which verge on the Turing Complete (Postscript is, but PDF isn’t, I am told) through those which are in fact Turing Complete though one is led not to use them that way (XSLT, SQL) to those which are unashamedly procedural (Java, C).
The choice of language is a common design choice. The low power end of the scale is typically simpler to design, implement and use, but the high power end of the scale has all the attraction of being an open-ended hook into which anything can be placed, a door to users bounded only by the imagination of the programmer.
Computer Science in the 1960s to 80s spent a lot of effort making languages which were as powerful as possible. Nowadays we have to appreciate the reasons for picking not the most powerful solution but the least powerful. The reason for this is that the less powerful the language, the more you can do with the data stored in that language. If you write it in a simple declarative form, anyone can write a program to analyze it in many ways. The Semantic Web is an attempt, largely, to map large quantities of existing data onto a common language so that the data can be analyzed in ways never dreamed of by its creators. If, for example, a web page with weather data has RDF describing that data, a user can retrieve it as a table, perhaps average it, plot it, deduce things from it in combination with other information. At the other end of the scale is the weather information portrayed by the cunning Java applet. While this might allow a very cool user interface, it cannot be analyzed at all. The search engine finding the page will have no idea of what the data is or what it is about. This the only way to find out what a Java applet means is to set it running in front of a person.
I hope that is a good enough explanation of this principle. There are millions of examples of the choice. I chose HTML not to be a programming language because I wanted different programs to do different things with it, present it differently, extract tables of contents, index it, and so on.
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