REXX
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REXX (Restructured Extended Executor) is a programming language which was developed at IBM, and several implementations are available under open source licenses. It is a structured high-level programming language which was designed to be both easy to learn and easy to read. Both commercial and open source Interpreters for REXX are available on a wide range of computing platforms, and compilers are available for IBM mainframes.
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Features
REXX has the following characteristics and features:
- character string basis
- dynamic data typing (no declarations)
- no reserved keywords (except in local context)
- arbitrary numerical precision
- decimal arithmetic (floating-point)
- a rich selection of built-in functions (especially string and word processing)
- automatic storage management
- crash protection
- content-addressable data structures
- straightforward access to system commands and facilities
- simple error-handling, and built-in tracing and debugger
- few artificial limitations
- simplified I/O facilities.
REXX has just twenty-three, largely self-evident, instructions (e.g., call, parse, and select) with minimal punctuation and formatting requirements. It is essentially a free-form language with only one data-type, the character string; this philosophy means that all data are visible (symbolic) and debugging and tracing are simplified.
REXX syntax looks similar to PL/I, but has fewer notations; this makes it harder to parse (by program) but easier to use.
History
REXX was designed and first implemented as an ‘own-time’ project between 20 March 1979 and mid-1982 by Mike Cowlishaw of IBM, originally as a scripting programming language to replace the languages EXEC and EXEC 2. It was designed to be a macro or scripting language for any system. As such, REXX is considered a precursor to Tcl and Python.
It was first described in public at the SHARE 56 conference in Houston, Texas, in 1981, where customer reaction, championed by Ted Johnston of SLAC, led to it being shipped as an IBM product in 1982.
Over the years IBM included REXX in almost all of its operating systems (VM/CMS, VM/GCS, MVS TSO/E, AS/400, OS/2, VSE/ESA, AIX, CICS/ESA, and PC-DOS), and has made versions available for Novell Netware, Windows, Java, and Linux.
The first non-IBM version was written for PC-DOS by Charles Daney in 1984/5. Other versions have also been developed for Atari, Amiga, Unix (many variants), Solaris, DEC, Windows, Windows CE, PocketPC, MS-DOS, Palm OS, QNX, OS/2, Linux, BeOS, EPOC32, AtheOS, OpenVMS, OpenEdition, Macintosh, and Mac OS X.
Several freeware versions are available. In 1992, the two most widely-used open-source ports appeared: Ian Collier's REXX/imc for Unix and Anders Christensen's Regina (later adopted by Mark Hessling) for Windows and Linux. BREXX is well-known for WinCE and PocketPC platforms.
In 1996 ANSI published a standard for REXX: ANSI X3.274–1996 “Information Technology – Programming Language REXX”. More than two dozen books on REXX have been published since 1985.
Since the mid-1990s, two newer variants of REXX have appeared:
- NetRexx – which compiles to Java byte-code via Java source code; this has no reserved keywords at all, and uses the Java object model, and is therefore not upwards-compatible with ‘classic’ REXX
- ObjectRexx – which is an object-oriented upwards-compatible version of REXX.
In 1990, Cathy Dager of SLAC organized the first independent REXX symposium, which led to the forming of the REXX Language Association. Symposiums are held annually.
Rexx marked its 25th anniversary on 20 March 2004, which was celebrated at the REXX Language Association’s 15th International REXX Symposium in Böblingen, Germany, in May 2004.
On October 12, 2004, IBM announced their plan to release their ObjectRexx implementation under the Common Public License
On February 22, 2005, the first public release of ooRexx (Open Object Rexx) was announced.
Syntax
Looping
The DO control structure always begins with a DO and ends with an END.
DO UNTIL:
do until [condition] [instructions] end
DO WHILE:
do while [condition is true] [instructions] end
Stepping through a variable:
do i = x to y by z [instructions] end
Looping forever until exiting with LEAVE:
do forever
if [condition] then leave
end
Looping a fixed number of times
do i = x to y by z for a [instructions] end
Conditionals
Testing conditions with IF
if [condition] then
do
[instructions]
end
else
do
[instructions]
end
For single instructions, DO and END can also be omitted:
if [condition] then
[instruction]
else
[instruction]
Testing for multiple conditions
SELECT is REXX’s CASE structure
select
when [condition] then
[instruction]
when [condition] then
do
[instructions]
end
otherwise
[instructions] or NOP
end
NOP indicates no instruction is to be executed.
PARSE
The PARSE instruction is particularly powerful; it combines some useful string-handling functions. Its syntax is:
parse [upper] origin template
where origin specifies the source:
- arg (command line variable)
- linein (keyboard)
- pull (REXX data queue)
- source (OS/2 info on how program was executed)
- value (an expression) with
- (the keyword with is required to indicate where the expression ends)
- var (a variable)
- version (version/release number)
and template can be:
- list of variables
- column number delimiters
- literal delimiters
upper is optional; it you specify it, data will be converted to upper case.
Examples:
Using a list of variables as template
myVar = "John Smith" parse var MyVar firstName lastName say "First name is:" firstName say "Last name is:" lastName
displays the following
First name is: John Last name is: Smith
Using a delimiter as template:
myVar = "Smith, John" parse var MyVar LastName "," FirstName say "First name is:" firstName say "Last name is:" lastName
also displays the following
First name is: John Last name is: Smith
Using column number delimiters:
myVar = "(202) 123-1234" parse var MyVar 2 AreaCode 5 7 SubNumber say "Area code is:" AreaCode say "Subscriber number is:" SubNumber
displays the following
Area code is: 202 Subscriber number is: 123-1234
A template can use a combination of variables, literal delimiters, and column number delimiters.
Flexible Variables
Variables in REXX are typeless, and initially are evaluated as their names, in upper case. Thus a variable's type can vary with its use in the program:
do say hello => HELLO hello = 25 say hello => 25 hello = "say 5 + 3" say hello => say 5 + 3 interpret hello => 8 drop hello say hello => HELLO end
Array support
REXX does not have explicit variable declarations, and likewise no arrays. However, a stem structure, similar to an array can be produced easily:
do i = 1 to 10 stem.i = 10 - i end
Afterwards the following variables with the following values exist: stem.1 = 9, stem.2 = 8, stem.3 = 7...
The drop stem. instruction unsets all ten variables of the form stem.i.
Unlike arrays, the index for a stem variable is not required to have an integer value. For example, the following code is valid:
i = 'Monday' stem.i = 2
SIGNAL: A negative example
The REXX SIGNAL instruction is equivalent to the GOTO in other languages. When correctly used, it can be a very useful instruction, for example to intercept errors or other exceptional cases. But one can also produce illegible, difficult to read code:
/* A Rexx Program */ signal define; use: say a signal end; define: a = "hello world" signal use; end: exit
Error and exception treatment in REXX
It is possible in REXX to intercept and deal with errors and other exceptions, using the SIGNAL instruction. There are five system conditions: ERROR, FAILURE, HALT, NOVALUE and SYNTAX. Handling of each can be switched on and off in the source code as desired.
This example will run until stopped by the user:
signal on halt; a = 1 do a = (a + 1) // 10000 say a end halt: say "The program was stopped by the user" exit
Conditions
| error | Positive RC from a system command |
| failure | Negative RC from a system command |
| halt | Abnormal termination |
| novalue | An unset variable was referenced |
| syntax | Invalid REXX program syntax |
When a condition is handled by SIGNAL ON, the SIGL and RC system variables can be analyzed to understand the situation. RC contains the REXX error code and SIGL contains the line number where the error arose.
Under OS/2
REXX is included in the base operating system of OS/2, and is also used as the macro language in many applications. Under OS/2, a REXX program begins with matched comment delimiters, /* */, to indicate to the operating system that it is a REXX program:
/* sample.cmd */ say "Hello World"
Instructions between quotes are passed to the OS:
/* sample.cmd */ 'dir /p /w'
Spelling
In plain text, Cowlishaw seems to prefer Rexx, whereas IBM documents and the majority of the web uses REXX. The ANSI standard uses the form preferred by the standardization committee, which has small capitals for the final three letters: REXX.
Originally just "Rex" because the author liked how it sounded, the extra "x" was added to avoid collisions with other products' names.
Literature
- The Rexx Language: A Practical Approach to Programming, by Michael Cowlishaw, ISBN 0137806515
- Rexx Programmer's Reference (http://search.barnesandnoble.com/booksearch/isbnInquiry.asp?userid=lU2UdsRB17&isbn=0764579967&itm=1) (Wiley/Wrox: 2005), by H. Fosdick, ISBN 0764579967
External links
- REXX language page (http://www.ibm.com/rexx/) at IBM
- REXX Language Association (http://www.rexxla.org)
- Open Object Rexx web site (http://www.oorexx.org/)
- Quercus Systems (http://www.quercus-sys.com): Commercial REXX interpreter for Windows, OS/2, and DOS.
- Regina (http://regina-rexx.sourceforge.net): open-source (LGPL) REXX interpreter for Linux, BSD, Windows, etc.
- REXX/imc (http://users.comlab.ox.ac.uk/ian.collier/Rexx/rexximc.html): open-source (nonstandard license) REXX interpreter for Unix and Linux systems
- REXX for everone (http://www-106.ibm.com/developerworks/library/l-rexx.html): An introduction by David Mertz for IBM developerWorks.