Ruby (programming language)
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Ruby is a general-purpose computer programming language made available as open-source software in 1995. It was created by Yukihiro Matsumoto, (commonly called Matz), a Japanese computer professional familiar with a variety of other programming languages. Matz has closely managed the Ruby open-source project in the years since it first appeared, and by 2007, Ruby has been ranked tenth in usage among all programming languages. In 2004, Ruby's place in the U.S. computer industry was boosted by the independent release of Rails, a Ruby-based, open-source web application framework created in the United States by David Heinemeier Hansson, a Danish developer. Use of Ruby is still growing.
As of October 2007, ever-improving versions of the official open-source Ruby implementation have been released on several different operating systems. These runtimes are interpreted, rather than compiled, and thus Ruby is not yet considered to be a high-performance platform suitable for some heavy-load, enterprise applications. Ruby implementations have also been developed by other groups, including JRuby (an attempt to port Ruby to the Java platform), and Rubinius (an interpreter modeled after self-hosting Smalltalk virtual machines).
This article is an overview of several often-cited Ruby characteristics, independent of Rails, for which the language is sometimes both praised and criticized. Like many "newer" programming languages (meaning those created or updated since 1990), Ruby is fully object-oriented and requires the installation of a runtime environment or virtual machine before Ruby programs can be developed or run.
As of 2008, the primary barriers to clinching Ruby as a truly dominant computer programming platform at present (on a par, say, with the Java platform or the .NET framework) may be twofold: 1) the lack of a standard language specification, and 2) the inability of any development environment to support all the major computing platforms.
In its early years, no formal written specification was provided for validating Ruby implementations. So although Ruby could potentially be used to create platform-independent programs, Ruby was not currently guaranteed to be identical across platforms, and newer versions were not always upwardly compatible with older versions. Furthermore, a burgeoning number of books, articles and other documentation were not always in complete agreement about the syntax, semantics, and conventions of the language. There was, however, widespread agreement that Ruby would benefit from having a formal specification. In 2011, the language was accepted as a Japanese Industrial Standard (JIS X 3017) in 2012 and an international standard (ISO/IEC 30170).
A plethora of Ruby tools are being developed as open source software: compilers, test runners, integrated development environments, and bindings to graphical user interface toolkits written in other languages. These include attempts (supported by Sun and Microsoft, respectively) to provide a Ruby compiler that targets both the Java virtual machine and the .NET runtime. These tools do not yet appear able to run on all the major computing environments (Linux, Mac OS X, and Windows), partly because many are not yet written in Ruby itself.
Things people like (and hate) about Ruby
Despite performance and cross-version and compatibility concerns, enthusiasts of Ruby wax eloquent in praising the language, including numerous subjective statements such as "it's fun". Something of Ruby's appeal may be seen in the brevity of this Hello World program:
puts "Hello, world"
But simple as it initially may seem, Ruby is described as having hidden depths, largely as a result of its support for a complex and powerful feature called closures. Peter Cooper, author of a 2007 book about Ruby, introduces the language by stating, "Ruby has more in common with more esoteric languages such as Lisp and Smalltalk than with better known languages such as PHP and C++". Cooper's book, and numerous other sources, list several characteristics of Ruby that may allow programs to be written with more ease, speed and "joy", than with other languages, including:
- a relatively permissive syntax, said to be more like the way people think and talk
- so-called Duck typing, considered convenient for programmers
- good string handling and regular expressions
- extensive libraries for networking and web services
- powerful support for making calls out to the native operating system if needful
Closures are a powerful and complex feature, implemented in their most flexible form in only a few programming languages such as Lisp and Smalltalk. A full discussion of closures deserves an article of its own but cannot be avoided in any serious discussion of Ruby, which encourages their widespread use. The definition and importance of closures has been widely debated with all the politeness for which the computer industry is known. The learning curve for closures appears to be steep enough to cause some dissonance with the common claim that "Ruby makes programming easier".
A closure occurs when a procedure (or a so-called block--an unnamed procedure) is physically situated inside another procedure, and the inner procedure can be referenced (called) from outside of the enclosing procedure. In some languages, the inner procedure can only read the variables in the enclosing scope; other languages (including Ruby) allow read/write access. Closures become really powerful when the inner procedure can be referenced (called) from anywhere else in the code, not just from within the enclosing procedure. Languages such as C, C++, Java or C#, which implement local variables using stack frames, mostly do not allow procedures to exist inside other procedures. So-called inner classes in Java and C# are closure-like but are mainly restricted to use as event handlers for the enclosing class. Ruby allows and encourages unrestricted use of closures.
Knowing when and how to make use of a true closure--what it can be good for--is neither obvious nor simple to many developers. Ruby advocates often struggle to illustrate the potential power of closures, which formerly were not required learning for a majority of programmers (to whom they were usually not available anyway). The often-cited example of closure use in Ruby is the .each procedure, which provides a more convenient way of iterating through collections than conventional looping. But sceptics counter that even Java now provides its own very simple syntax for iterating through collections (i.e., the "enhanced for loop").
A warning written by the Gang of Four in their influential 1995 Design Patterns book hints at the risks of a complex feature such as closures: "Dynamic, highly parameterized software is harder to understand than more static software."
The fact that unaware programmers may hang themselves due to the complexity of a feature is not necessarily a reason to withhold that power from a programmer. Advocates claim the added power and elegance of design is worth added difficulty that results when trying to read somebody else's code that uses closures.
Ruby tries to be tolerant of syntax styles from several different programming languages, and this makes it easier for programmers to migrate from those languages into Ruby. The downside of this is that a programmer who is used to only one form of the syntax will now need to become familiar with both (or multiple) syntactic styles. This is not an issue when learning to write one's own code, but it becomes apparent when reading code from other people, a common maintenance task for programmers. In fact, the vast size and permissiveness of Ruby syntax not only creates a larger learning curve than a language with less syntactic options would have, it also makes the creation of development tools more complex.
Establishing variable types at run-time, and its trade-off
Sometimes Ruby is described as being a "dynamic" language, or even a "scripting" language, which appears to refer to the fact it is interpreted rather than compiled. Ruby does not require variable types to be declared, and instead decides the type based on the kind of thing first assigned to the variable (so-called "duck typing"). This is a trade-off between programmer convenience, as weighed against the increased risk of a run-time error because there was no compile-time type checking. This is one reason why web application programmers requiring very high reliability might choose a language such as Java over Ruby.
Strings and regular expressions
Ruby has a lot of useful, built-in libraries for strings and symbols (which are like "interned" strings in Java or C#). Ruby also has special syntax allowing the use of "hashes", which are similar to keyword-based collections in Java or C#.
Networking, including web services
The power of Ruby's networking libraries, and its support for SOAP-based web services, equals or surpasses those in Java or C#.
Calling into the OS
This feature may be regarded as a double-edged sword. On the one hand, it's very helpful to be able to take advantage of operating system facilities to expand the power of the Ruby language. On the other hand, doing so makes code less likely to be portable to another operating system.
On a historic note, Pascal (a once very promising programming language) may have failed to achieve immortality due the inability of programmers to make calls to the underlying operating system without great difficulty. The designers of Ruby (and other programming languages created after Pascal) have taken this "object lesson" to heart and provided facilities to empower calls into the OS if needed. It can reasonably be argued that Ruby makes this easier than most other languages at present.
- "TIOBE Programming Community Index". TIOBE Software (2007). Retrieved on 2007-10-10.
- "Beginning Ruby: From Novice to Professional". Apress paperback book, Introduction p. xxix (2007). Retrieved on 2007-10-10.
- Design Patterns: Elements of Reusable Object-Oriented Software (page 21). Addison-Wesley (2007). Retrieved on 2007-05-24.