From 37098ac1e4cefad940a5c5cbb6d16d9580933ad4 Mon Sep 17 00:00:00 2001 From: Bastian Kleineidam Date: Sat, 4 Aug 2012 13:40:10 +0200 Subject: [PATCH] Remove generated file. --- tests/data/arexx.dox | 7054 ------------------------------------------ 1 file changed, 7054 deletions(-) delete mode 100644 tests/data/arexx.dox diff --git a/tests/data/arexx.dox b/tests/data/arexx.dox deleted file mode 100644 index 2ae248d..0000000 --- a/tests/data/arexx.dox +++ /dev/null @@ -1,7054 +0,0 @@ - AREXX - - TABLE OF CONTENTS - - AREXX USER'S REFERENCE MANUAL - -INTRODUCTION....................................................1 - 1. Organization of this Document...............................1 - 1 Using this Manual.........................................2 - 2 Typographic Conventions...................................2 - 2. Future Directions...........................................2 -CHAPTER 1. WHAT IS AREXX?.......................................3 - 1. Language Features...........................................3 - 2. ARexx on the Amiga..........................................4 - 3. Further Information.........................................4 -CHAPTER 2. GETTING ACQUAINTED...................................5 - 1. Installing ARexx............................................5 - 1 ARexx and Workbench.......................................5 - 2 Installation..............................................5 - 3 Starting the Resident Process.............................6 - 4 Naming Conventions........................................6 - 5 The REXX: Directory.......................................6 - 2. Program Examples............................................7 -CHAPTER 3. ELEMENTS OF THE LANGUAGE............................11 - 1. Format.....................................................11 - 2. Tokens.....................................................11 - 1 Comment Tokens...........................................11 - 2 Symbol Tokens............................................11 - 3 String Tokens............................................12 - 4 Operators................................................12 - 5 Special Character Tokens.................................13 - 3. Clauses....................................................14 - 1 Null Clauses.............................................14 - 2 Label Clauses............................................14 - 3 Assignment Clauses.......................................14 - 4 Instruction Clauses......................................15 - 5 Command Clauses..........................................15 - 6 Clause Classification....................................15 - 4. Expressions................................................16 - 1 Symbol Resolution........................................16 - 2 Order of Evaluation......................................16 - 5. Numbers and Numeric Precision..............................17 - 1 Boolean Values...........................................17 - 2 Numeric Precision........................................17 - 6. Operators..................................................18 - 1 Arithmetic Operators.....................................18 - 2 Concatenation Operators..................................20 - 3 Comparison Operators.....................................20 - 4 Logical (Boolean) Operators..............................21 - 7. Stems and Compound Symbols.................................21 - - i - -CHAPTER 3. ELEMENTS OF THE LANGUAGE (CONT).....................11 - 8. The Execution Environment..................................22 - 1 The External Environment.................................22 - 2 The Internal Environment.................................22 - 3 Input and Output.........................................23 - 4 Resource Tracking........................................24 -CHAPTER 4. INSTRUCTIONS........................................25 - 1. ADDRESS....................................................25 - 2. ARG........................................................25 - 3. BREAK......................................................26 - 4. CALL.......................................................26 - 5. DO.........................................................27 - 6. DROP.......................................................28 - 7. ECHO.......................................................28 - 8. ELSE.......................................................28 - 9. END........................................................29 - 10. EXIT......................................................29 - 11. IF........................................................29 - 12. INTERPRET.................................................30 - 13. ITERATE...................................................30 - 14. LEAVE.....................................................31 - 15. NOP.......................................................31 - 16. NUMERIC...................................................31 - 17. OPTIONS...................................................32 - 18. OTHERWISE.................................................32 - 19. PARSE.....................................................33 - 1 Input Sources...........................................33 - 2 Templates...............................................34 - 20. PROCEDURE.................................................35 - 21. PULL......................................................35 - 22. PUSH......................................................36 - 23. QUEUE.....................................................37 - 24. RETURN....................................................37 - 25. SAY.......................................................38 - 26. SELECT....................................................38 - 27. SHELL.....................................................38 - 28. SIGNAL....................................................38 - 29. THEN......................................................39 - 30. TRACE.....................................................40 - 31. UPPER.....................................................40 - 32. WHEN......................................................41 -CHAPTER 5. COMMANDS............................................43 - 1. Command Clauses............................................43 - 2. The Host Address...........................................44 - 3. The Command Interface......................................44 - 4. Using Commands in Macro Programs...........................45 - 5. Using ARexx with Command Shells............................45 - 6. Command Inhibition.........................................46 - - ii - -CHAPTER 6. FUNCTIONS...........................................47 - 1. Syntax and Search Order....................................47 - 1 Search Order.............................................47 - 2 Internal Functions.......................................48 - 3 Built-In Functions.......................................49 - 4 External Function Libraries..............................49 - 5 Function Hosts...........................................50 - 2. The Built-In Function Library..............................50 - 1 ABBREV().................................................51 - 2 ABS()....................................................51 - 3 ADDLIB().................................................51 - 4 ADDRESS()................................................51 - 5 ARG()....................................................52 - 6 B2C()....................................................52 - 7 BITAND().................................................52 - 8 BITCHG().................................................52 - 9 BITCLR().................................................53 - 10 BITCOMP()...............................................53 - 11 BITOR().................................................53 - 12 BITSET()................................................53 - 13 BITTST()................................................53 - 14 BITXOR()................................................54 - 15 C2B()...................................................54 - 16 C2D()...................................................54 - 17 C2X()...................................................54 - 18 CENTER() OR CENTRE()....................................55 - 19 CLOSE().................................................55 - 20 COMPRESS()..............................................55 - 21 COMPARE()...............................................55 - 22 COPIES()................................................55 - 23 D2C()...................................................56 - 24 DATATYPE()..............................................56 - 25 DELSTR()................................................56 - 26 DELWORD()...............................................57 - 27 EOF()...................................................57 - 28 ERRORTEXT().............................................57 - 29 EXISTS()................................................57 - 30 EXPORT()................................................57 - 31 FREESPACE().............................................58 - 32 GETCLIP()...............................................58 - 33 GETSPACE()..............................................58 - 34 HASH()..................................................58 - 35 IMPORT()................................................59 - 36 INDEX().................................................59 - 37 INSERT()................................................59 - 38 LASTPOS()...............................................59 - 39 LEFT()..................................................60 - 40 LENGTH()................................................60 - - iii - - 41 MAX()...................................................60 - 42 MIN()...................................................60 - 43 OPEN()..................................................60 - 44 OVERLAY()...............................................61 - 45 POS()...................................................61 - 46 PRAGMA()................................................61 - 47 RANDOM()................................................62 - 48 RANDU().................................................62 - 49 READCH()................................................62 - 50 READLN()................................................63 - 51 REMLIB()................................................63 - 52 REVERSE()...............................................63 - 53 RIGHT().................................................63 - 54 SEEK()..................................................63 - 55 SETCLIP()...............................................64 - 56 SHOW()..................................................64 - 57 SIGN()..................................................64 - 58 SPACE().................................................64 - 59 STORAGE()...............................................65 - 60 STRIP().................................................65 - 61 SUBSTR()................................................65 - 62 SUBWORD()...............................................66 - 63 SYMBOL()................................................66 - 64 TIME()..................................................66 - 65 TRACE().................................................67 - 66 TRANSLATE().............................................67 - 67 TRIM()..................................................67 - 68 UPPER().................................................67 - 69 VALUE().................................................68 - 70 VERIFY()................................................68 - 71 WORD()..................................................68 - 72 WORDINDEX().............................................68 - 73 WORDLENGTH()............................................68 - 74 WORDS().................................................69 - 75 WRITECH()...............................................69 - 76 WRITELN()...............................................69 - 77 X2C()...................................................69 - 78 XRANGE()................................................69 -CHAPTER 7. TRACING AND INTERRUPTS..............................71 - 1. Tracing Options............................................71 - 2. Display Formatting.........................................72 - 1 Tracing Output...........................................72 - 2 Command Inhibition.......................................73 - 3. Interactive Tracing........................................73 - 1 Error Processing.........................................74 - 2 The External Tracing Flag................................74 - 4. Interrupts.................................................74 - - iv - -CHAPTER I. PARSING AND TEMPLATES...............................77 - 1. Template Structure.........................................77 - 1 Template Objects.........................................78 - 2 The Scanning Process.....................................78 - 2. Templates in Action........................................79 - 1 Parsing by Tokenization..................................79 - 2 Pattern Parsing..........................................80 - 3 Positional Markers.......................................80 - 4 Multiple Templates.......................................80 -CHAPTER 9. THE RESIDENT PROCESS................................83 - 1. Command Utilities..........................................83 - 1 HI.......................................................83 - 2 RX.......................................................84 - 3 RXSET....................................................84 - 4 RXC......................................................84 - 5 TCC......................................................84 - 6 TCO......................................................84 - 7 TE.......................................................84 - 8 TS.......................................................84 - 2. Resource Management........................................85 - 1 The Global Tracing Console...............................85 - 2 The Library List.........................................85 - 3 The Clip List............................................86 -CHAPTER 10. INTERFACING TO AREXX...............................89 - 1. Basic Structers............................................90 - 2. Designing a Command Interface..............................91 - 1 Receiving Command Messages...............................92 - 2 Result Fields............................................92 - 3 Multiple Host Processes..................................92 - 3. Invoking ARexx Programs....................................93 - 1 Message Packets..........................................93 - 2 Command Invocations......................................94 - 3 Function Invocations.....................................95 - 4 Search Order.............................................95 - 5 Extension Fields.........................................96 - 6 Interpreting the Result Fields...........................97 - 4. Communicating with the Resident Process....................97 - 1 Command (Action) Codes...................................97 - 2 Modifier Flags...........................................99 - 3 Result Fields...........................................100 - 5. External Function Libraries...............................100 - 1 Design Considerations...................................100 - 2 Calling Convention......................................101 - 3 Parameter Conversion....................................101 - 4 Returned Values.........................................101 - 6. Direct Manipulation of Data Structures....................102 - - v - -APPENDIX A. ERROR MESSAGES....................................103 -APPENDIX B. LIMITS AND COMPATIBILITY..........................109 - 1 Limits.....................................................109 - 2 Compatibility..............................................109 -APPENDIX C. THE AREXX SYSTEMS LIBRARY.........................111 - 1 Functional Groups..........................................111 - 2 Library Functions..........................................113 -APPENDIX D. THE AREXX SUPPORT LIBRARY.........................127 - 1 ALLOCMEM()...............................................127 - 2 CLOSEPORT()..............................................127 - 3 FREEMEM()................................................128 - 4 GETARG().................................................128 - 5 GETPKT().................................................128 - 6 OPENPORT()...............................................128 - 7 REPLY()..................................................129 - 8 SHOWDIR()................................................129 - 9 SHOWLIST()...............................................129 - 10 STATEF()................................................130 - 11 WAITPKT()...............................................130 -APPENDIX E. DISTRIBUTION FILES................................131 - 1 Directories................................................131 - 1 The :C Directory.........................................131 - 2 The :INCLUDE Directory...................................131 - 3 The :LIBS Directory......................................132 - 4 The :REXX Directory......................................132 - 5 The :TOOLS Directory.....................................132 - 6 Miscellaneous Files......................................132 - 2 Listings of Header Files...................................133 - 1 storage.h................................................133 - 2 rxslib.h.................................................139 - 3 rexxio.h.................................................142 - 4 errors.h.................................................144 -GLOSSARY......................................................147 -INDEX.........................................................151 - - vi - - INTRODUCTION - -Welcome to ARexx,an implementation of the REXX language for the Amiga computer. -ARexx is a powerful programming took,but one which by virtue of its clean -syntax and sparse vocabulary is also easy to learn and easy to use. - -1 ORGANIZATION OF THIS DOCUMENT - -This document will attempt to fill the roles of User's Manual,Language -Reference,and Programmer's Guide. The chapters that follow have been organized -to provide a gently introduction to the language. - -Chapter 1,What is ARexx?,gives an overview of the ARexx language and its -implementation of the Amiga. - -Chapter 2,Getting Acquainted,tells how to install ARexx on your Amiga and -presents several example programs to illustrate the features of the language. - -Chapter 3,Elements of the Language,introduces the language structure and -syntax. - -Chapter 4,Instructions,describes the action statements of ARexx. - -Chapter 5,Commands,describes the program statements used to communicate with -external programs. - -Chapter 6,Functions,explains how functions are called and documents the Built- -In Function library. - -Chapter 7,Tracing and Interrupts,describes the source level debugging features -useful for developing and testing programs. - -Chapter 8,Parsing and Templates,describes the instructions used to extract -words or fields from strings. - -Chapter 9,The Resident Process,describes the capabilities of the global -communications and resources manager. - -Chapter 10,Interfacing to ARexx,describes how to design and implement an -interface between ARexx and an external program. - -Appendix A,Error Messages,lists the error messages issued by the interpreter. - -Appendix B,Limits and Compatibility,discusses the compatibility of ARexx with -the language standard. - -Appendix C,The ARexx Systems Library,documents the functions of ARexx systems -library. - -Appendix D,The Support Library,documents the library of Amiga specific -functions. - -Appendix E,Distribution Files,lists the files on the distribution disk. - -Finally,a Glossary and an Index are provided. - - 1 - -USING THIS MANUAL - -If you are new to the REXX language,or perhaps to programming itself,you should -review chapters 1 through 4 and then play with ARexx by running some of the -sample programs given in chapter 2. Further examples are available in the :rexx -directory of the distribution disk. - -If you are already familiar with REXX you may wish to skip directly to chapter -5,which begins to present some of the system-dependent features of this -implementation. A summary of the compatibility of ARexx with the language -definition is contained in Appendix B. - -TYPOGRAPHIC CONVENTIONS - -Describing a language is sometimes difficult because of the multiple and -changing contexts involved. To help clarify the presentation here,a simply -typographic convention has been adopted throughout the document. All of the -terms and words specific to the REXX language,as well as the program examples -and computer input and output,have been set in typewriter font like this. This -should help to distinguish the language keywords and examples from the -surrounding text. - -2 FUTURE DIRECTIONS - -ARexx,like most software products,will probably envolve somewhat over the next -few years as new features are added,old bugs are removed,and market imperatives -become more apparant. While the core language will probably undergo few -modifications,many capabilities will be added to the function libraries -supported by ARexx. Your comments and suggestions for improvements to ARexx are -most welcome. - -The author sincerely hopes that other software developers will consider using -ARexx with their products. The advantages of having a rich variety of software -products sharing a common user interface and a common procedural interface -cannot be overstated. This is the underlying promise of the Amiga's -multitasking capability,and that which most sets it apart from other -inexpensive computers. - -Example Programs. One of the best ways to learn a computer language is to study -examples written by more experienced programmers. The ARexx distribution disk -includes a few example programs in the :rexx directory,and more programs will -be added in future releases. - -If you have written REXX language program(for any computer)that you think would -be of interest to a more general audience,please send it to the author for -consideration. Programs should be of interest either in terms of their specific -funtionality or as an example of programming technique. Each program submitted -should include an author credit and a few lines of commentary on its intended -fuction. - - 2 - -ARexx is a high-level language useful for prototyping,software integration,and -general programming tasks. It is an implementation of the REXX language -described by M.F. Cowlishaw in The REXX Language:A Practical Approach to -Programming(Prentice-Hall,1985),and follow the language definition closely. -ARexx is particularly well suited as a command language. Command programs, -sometimes called "scripts" or "macros",are widely used to extend the predefined -commands of an operating system or to customize an applications program. - -As a programming language,ARexx can be useful to a wide cross section of users. -For the novice programmer,ARexx is an easy-to-learn yet powerful language that -serves as a good introduction to programming techniques. Its source-level -debugging facilities will help take some of the mystery out of how programs -work(or don't work,as is more frequently the case.) - -For the more sophisticated user,ARexx provides the means to build fully -integrated software packages,combining different applications programs into an -environment tailored to their needs. A common command language among -applications that support ARexx will bring uniformity to procedural interfaces, -much as the Amiga's Intuition provides uniformity in the graphical interface. - -Finally,for the software developer,ARexx offers a straightforward way to build -fully programmable applications programs. Developers can concentrate their -efforts on making the basic operations of their programs fast and efficient,and -let the end user add the frills and custom features. - -1-1 LANGUAGE FEATURES - -Some of the important features of the language are: - -TYPELESS DATA. Data are treated as typeless character strings. Variables do not -have to be declared before being used,and all operations dynamically check the -validity of the operands. - -COMMAND INTERFACE. ARexx programs can issue commands to external programs that -provide a suitable command interface. Any software package that implements the -command interface is then fully programmable using ARexx,and can be extended -and customized by the end user. - -TRACING AND DEBUGGING. ARexx includes source-level debugging facilities that -allow the programmer to see the step-by-step actions of a program as it runs, -thereby reducing the time required to develop and test programs. An internal -interrupt system permits special handling of errors that would otherwise cause -the program to terminate. - - 3 - -INTERPRETED EXECUTION. ARexx programs are run by an interpreter,so separate -compilation and linking steps are not required. This makes it especially useful -for prototyping and as a learning tool. - -FUNCTION LIBRARIES. External function libraries can be used to extend the -capabilities of the language or as bridges to other programs. Libraries also -allow ARexx programs to be used as "test drivers" for software development and -testing. - -AUTOMATIC RESOURCE MANAGEMENT. Internal memory allocation related to the -creation and destruction of strings and other data structures is handled -automatically. - -1-2 AREXX ON THE AMIGA - -ARexx was designed to run on the Amiga,and makes use of many of the features of -its multitasking operating system. ARexx programs run as separate tasks and -may communicate with each other or with external programs. The interpreter -follows the design guidelines expected of well-behaved programs in a -multitasking environment: specifcally,it uses as little memory as possible and -is careful to reutrn resources to the operating system when they are no longer -needed. Memory requirements were minimized by implementing the entire ARexx -system as a shared library,so that only one copy of the program code must be -loaded. - -1-3 FURTHER INFORMATION - -The aforementioned book by M.F. Cowlishaw is highly recommended to those -interested in further information about REXX. It presents an interesting -discussion of the design and development of the language. - - 4 - - CHAPTER 2 GETTING ACQUAINTED - -This chapter explains how to install ARexx on your Amiga computer and shows -some example programs. - -2-1 INSTALLING AREXX - -ARexx requires an Amiga computer with at least 256k of memory,and will operate -under V1.1 or V1.2 of the operating system. It uses the double-precision math -library called "mathieeedoubbas.library" that is supplied with the Amiga -WorkBench disk,so make sure that this file is present in your LIBS: directory. -The distribution disk includes the language system,some example programs,and a -set of the INCLUDE files required for integrating ARexx with other software -packages. The distribution files are listed in Appendix E. - -AREXX AND WORKBENCH - -ARexx can be installed and loaded from within the icon-based environment -provided by the Amiga WorkBench. However,it is a primarily a text-oriented -language system and requires a good text editor and file management environment -to be most effective. Unless you purchased ARexx as part of an applications -package that includes an integrated editor,you'll probably find it useful to -become familiar with the Commmand Line Interface (CLI)environment on the Amiga. - -INSTALLATION - -The ARexx language system consists of a shared library,a resident program,and -several command utilities. All of the required files are contained in the :c -and :libs directories of the distribution disk. ARexx may be installed on any -of the system disks with which it will be used,but first check the :c and :libs -directores of each disk to make sure that there are no naming conflicts. The -following steps will then install ARexx on the system disk,provided that two -disk drives are available: - -1. Activate a CLI window. -2. Copy the ARexx :libs directory to the system LIBS: directory with the -command "copy df1:libs to libs:". -3. Copy the ARexx :c directory to the system C: directory with the command -"copy df1:C to c:". - -SINGLE DRIVE SYSTEMS. Installing software in a single-drive system can be very -confusing,so an installation utility has been provided with the ARexx -distribution disk. It copies the :c and :libs directories of the distribution -disk into memory,and then prompts the user to insert each disk that is to -receive the files. Follow these steps to run the installation utility: - - 5 - -1. Activate a CLI window. -2. Insert the distribution disk into drive 0 and type "df0:rxinstall". -3. At the program prompt,insert the system disk on which ARexx is to be -installed into drive 0. -4. Repeat step 3 as required. - -STARTING THE RESIDENT PROCESS - -ARexx programs are launched by a background program called the resident -process. It can be started by issuing the command rexxmast and must be active -before any ARexx programs can be run. The rexxmast program briefly displays a -small window to announce itself,and then disappears into the background to -await your next request. If you will be using ARexx frequently,you can place -the rexxmast command in the "startup-sequence" file that resides in the system -S: directory. This will start the resident process automatically when you -reboot the computer. - -After the resident process has been loaded,ARexx programs can be run from the -CLI by typing the command rx followed by the program name and any arguments. -For example,the sample program calc.rexx,which evaluates an expression,could be -run by typeing "rx :rexx/calc 1+1." - -You may not need to start up the resident process if you are using a software -package that starts it automatically. Applications that use ARexx can test -whether the resident process is active by checking for a public message port -named "REXX." If the port hasn't been opened,the program can issue the rexxmast -command directly. - -The resident process can be closed using the command rxc;it will then exit as -soon as the last ARexx program finishes execution. Unless you are very short on -memory space,there is usually no reason to close ARexx,as it simply waits in -the background for the next program to run. - -NAMING CONVENTIONS - -ARexx programs can be named anything,but adopting a simple naming convention -will make managing the programs much easier. Programs to be run from the CLI -are usually given the file extention .rexx to distinguish them from programs -written in other languages. Programs written as "macros" or "scripts" for a -particular applications program should be given a file extension specific to -that program. For example,a macro written for a communications program called -"MyComm" might be named "download.myc". ARexx uses this file extention when it -searches for a program file to be executed. - -THE REXX: DIRECTORY - -You can designate one directory as the system-wide source for ARexx programs by -defining a REXX: "device" with the assign command. This directory should reside -on a volume that is usually mounted,such as SYS: or a hard disk. For example, -the command "assign rexx: sys:rexx" defines the REXX: device as the :rexx -directory on the system disk. Once defined,the REXX: device is searched after -the current directory when looking for an ARexx program. - - 6 - -2-2 PROGRAM EXAMPLES - -Before introducing the structure and syntax of the language,let's look at a few -examples of ARexx programs. Readers familiar with other high-level programming -languages should find many points of similarity between ARexx and other -languages. In the examples that follow,new terms are highlighted in the text as -they are introduced,and will be convered in depth in the next few chapters. - -These short programs can be created using any text editor and then run from the -Command Line Interface (CLI),or may simply be read as samples of the language. -If the examples are to be run,first complete the installation procedures -outlined in the previous section,and then start the ARexx resident process. -Example programs can then be run by entering,for example,"rx age" at the CLI -prompt. - -We'll begin with a "Hello,World" program that simply displays a message on the -console screen. - - /* A simple program */ - say 'Hello,World' - -This program consists of a comment line that describes the program and an -instruction that displays text on the console. For historical reasons, ARexx -programs begin with a comment line;the initial "/*" says "I'm an ARexx program" -to the interpreter when it searches for a program. - -Instructions are language statements that denote a certain action to be -performed,and always start with a symbol,in this case the word say. Symbols are -translated to uppercase when the program is run,so the symbol say here is -equivalent to SAY. Following say is an example of a string,which is a series of -characters surrounded by quotes ('). Double quotes (") could also have been -used to define the string. - -In the next program we'll display a prompt for input and then read some -information from the user. - - /* Calculate age in days */ - say 'Please enter your age' - pull age - say 'You are about' age*365 'days old' - -This program uses the pull instruction to read a line of input into a variable -called age,which is then used with a say instuction. Variables are symbols that -may be assigned a value. The words following say form an expression in which -strings are joined and an arithmetic calculation is performed. - -Note that the variable age did not have to be declared as a number;instead,its -value was checked when it was actually used in the expression. To see what -would happen if age wasn't a number,try rerunning the program with a -non-numeric entry for the age. The resulting error message shows the line -number and type of error that occurred,after which the program ends. - - 7 - -The next program introduces the do instruction,which allows program statements -to be executed repeatedly. It also illustrates the exponentiation operator, -which is used to raise a number to an integral power. - - /* Calculate some squares and cubes */ - do i = 1 to 10 /* 10 interations */ - say i i**2 i**3 /* calculations */ - end - say ' all done ' - -The do instruction causes the statements between the do and end instructions to -be executed 10 times. The variable i is the index variable for the loop,and is -incremented by 1 for each iteration. The number following the symbol to is the -limit for the do instruction,and could have been a full expression rather than -just the constant 10. Note that the statements within the loop have been -indented. This is not required by the language,but it makes the program more -readable and is therefore good programming practice. - -The subject of the next example is the if instruction,a often-used control -statement that allows statements to be conditionally executed. The numbers from -1 to 10 are classified as even or odd by dividing them by 2 and then checking -the remainder. - - /* Even or odd? */ - do i = 1 to 10 - if i//2 = 0 then type = 'even' - else type = 'odd' - say i 'is' type - end - -This example intoduces the // arithmetic operator,which calculates the -remainder after a division operation. The if instruction tests whether the -remainder is 0 and executes the then branch if it is,thereby setting the -variable type to "even." If the remainder was not 0,the alternative else branch -is executed and type is set to "odd." - -The next example introduces the concept of a function,which is a group of -statements that can be executed by mentioning the function name in a suitable -context. Functions are an important part of most programming languages,as they -allow large,complex programs to be built from smaller modules. Functions are -specified in an expression as a name followed by an open parenthesis. One or -more expressions called arguments may follow the parenthesis;these are used to -pass information to the function for processing. - - 8 - - /* Defining and calling a function */ - do i = 1 to 5 - say i square(i) /* call square */ - end - exit /* all done */ - square: /* function name */ - arg x /* get the "argument" */ - return x**2 /* square it and return*/ - -The function square is defined in the lines followed the label square: up -through the return instruction. Two new instructions are introduced here: arg -retrieves the value of the argument string,and return passes the functon's -result back to the point where the function was called. - -One final example will suffice for now. A new instruction called trace is used -here to activate the tracing features of ARexx. - - /* Demonstrate "results" tracing */ - trace results - sum=0;sumsq=0; - do i = 1 to 5 - sum = sum + i - sumsq = sumsq + i**2 - end - say 'sum=' sum 'sumsq=' sumsq - -When this program is run,the console displays the source lines as they are -excuted,and shows the final results of expressions. This makes it easy to tell -what the program is really doing,and helps reduce the time required to develop -and test a new program. One minor point is illustrated here: the third line -shows two distinct statements separated by a semicolon (;). The semicolon is an -example of a special character,characters that have particular meanings within -ARexx programs. - -The following chapters will present further information on the language -statements illustrated here and will introduce others that have not been shown. -Take heart,though;ARexx is a "small" language and there are relatively few -words and rules to learn. - - 9 - -THERE WAS NO PAGE 10 - - ELEMENTS OF THE LANGUAGE - -This chapter introduces the rules and concepts that make up the REXX language. -The intent is not to present a formalized definition,but rather to convey a -practical understanding of how the language elements "fit together" to form -programs. - -3-1 FORMAT - -ARexx programs are compossed of ASCII characters and may be created using any -text editor. No special formatting of the program statements is required or -imposed on the programmer. - -3-2 TOKENS - -The smallest distinct entities or "words" of the language are called tokens. A -token may be series of characters,as in the symbol MyName,or just a single -character like the "+" operator. Tokens can be categorized into comments, -symbols,strings,operators,and special characters. Each of these groups are -described below. - -COMMENT TOKENS - -Any group of characters beginning with the sequence "/*" and ending with "*/" -defines a comment token. Comments may be placed anywhere in a program and cost -little in terms of execution speed,since they are stripped(removed)when the -program is first scanned by the interpreter. Comments may be "nested" within -one another,but each "/*" must have a matching "*/" in the program. -Examples: - - /* Your basic comment */ - /* a /* nested! */ comment */ - -SYMBOL TOKENS - -Any group of the characters a-z,A-Z,0-9,and .!?$_defines a symbol token. -Symbols are translated to uppercase as the program is scanned by the -interpreter,so the symbol MyName is equivalent to MYNAME. Four types of symbols -are recognized: - - Fixed symbols begin with a digit (0-9) or a period(.). - Simple symbols do not begin with a digit,and do not contain any - periods. - Stem symbols have exactly one period at the end of the symbol name. - Compound symbols include one or more periods in the interior of the - name. - -Stems and compound symbols have special properties that make them useful for -building arrays and lists. - - 11 - -SYMBOLS VALUES. The value used for a fixed symbol is always the symbol name -itself(as translated to uppercase.) Simple,stem,and compound symbols are called -variables and may be assigned a value;the value used for an uninitialized -variable is just the variable name itself. -Examples: - - 123.45 /*a fixed symbol */ - MyName /*same as MyName */ - a. /*a stem symbol */ - a.1.Index /*a compound symbol */ - -STRING TOKENS - -A group of characters beginning and ending with a quote (')or double quote(") -delimiter defines a string token. The delimiter character itself may be -included within the string by a double-delimiter sequence (" or ""). The number -of characters in the string is called its length,and a string of length zero is -called a null string. A string is treated as a literal in an expression;that -is,its value is just the string itself. - -Strings followed immediately by an "X" or "B" character that is not part of a -longer symbol are classified as hex or binary strings,respectively,and must be -composed of hexadecimal digits(0-9,A-F) or binary digits(0,1). Blanks are -permitted at byte boundaries for added readability. Hex and binary strings are -convenient for specifying non-ASCII characters and for machine-specific -information like addresses in a program. They are converted immediately to the -"packed" internal form. -Examples: - "Now is the time" /*a simple example */ - "" /*a null string */ - 'Can't you see??' /*Can't you see?? */ - '4A 3B CO'X /*a hex string */ - '00110111'b /*binary for '7' */ - -OPERATORS - -The characters +-*/=><*| may be combined in the sequences shown in Table 3.1 -to form operator tokens. Operator sequences may include leading,trailing,and -embedded blanks,all of which are removed when the program is scanned. In -addition to the above characters,the blank character as a concatenation -operator if it follows a symbol or string and is not adjacent to an operator or -special character. - -Each operator has an associated priority that determines the order in which -operations will be performed in an expression. Operators with higher priorities -before those with lower priorities. - - 12 - - TABLE 3.1 OPERATOR SEQUENCES - -SEQUENCE PRIORITY OPERATOR DEFINITION - - 8 Logical NOT -+ 8 Prefix Conversion -- 8 Prefix Negation -** 7 Exponentiation -* 6 Multiplication -/ 6 Division -% 6 Integer Division -// 6 Remainder -+ 5 Addition -- 5 Subtration -|| 4 Concatenation -(blank) 4 Blank Concatenation -== 3 Exact Equality -~== 3 Exact Inequality -= 3 Equality -~= 3 Inequality -> 3 Greater Than ->=,~< 3 Greater Than or Equal To -< 3 Less Than -<=,~> 3 Less Than or Equal To -& 2 Logical AND -| 1 Logical Inclusive OR -^,&& 1 Logical Exclusive OR - -SPECIAL CHARACTER TOKENS - -The characters :():,are each treated as a separate special character token and -have particular meanings within an ARexx program. Blanks adjacent to these -special characters are removed,except for those preceding an open parenthesis -or following a close parenthesis. - -COLON (:). A colon,if preceded by a symbol token,defines a label within the -program. Lavels are locations in the program to which control may be -transferred under various conditions. - -OPENING AND CLOSING PARENTHESES (()). Parentheses are used in expressions to -group operators and operands into subexpressions,in order to override the -normal operator primorities. An open parenthesis also serves to identify a -function call within an expression;a symbol or string followed immediately by -an open parenthesis defines a function name. Parentheses must always be -balanced within a statement. - -SEMICOLON (;). The semicolon acts as a program statement terminator. Several -statements may be placed on a single source line if separated by semicolons. - - 13 - -COMMA (,). A comma token acs as the continuation character for statements that -must be entered on several source lines. It is also used to separate the -argument expressions in a function call. - -3-3 CLAUSES - -Tokens are grouped together to form clauses,the smallest language unit that can -be executed as a statement. Every clause in ARexx can be classified as either a -null,label,assignment,instruction,or command clause. The classification process -is very simple,since no more than two tokens are required to classify any -clause. Assignment,instruction,and command clauses are jointly termed -statements. - -CLAUSE CONTINUATION. The end of a source line normally acts as the implicit end -of a clause. A clause can be continued on the next source line by ending the -line with a comma (,). The commas is then removed,and the next line is -considered as a continuation of the clause. There is no limit to the number of -continuations that may occur. String and comment tokens are automatically -continued if a line end before the closing delimiter has been found,and the -"newline" character is not considered to be part of the token. - -MULTIPLE CLAUSES. Several clauses can be placed on a single line by separating -them with semicolons(;). - -NULL CLAUSES - -Lines consisting only of blanks or comments are called null clauses. They have -no function in the execution of a program,except to aid its readability and to -increment the source line count. Null clauses may appear anywhere in a program. -Example: - - /* perform annuity calculations */ - -LABEL CLAUSES - -A symbol followed immediately by a colon defines a label clause. A label acts -as a placemarker in the program,but no action occurs with the "execution" of a -label. The colon is considered as an implicit clause terminator,so each label -stands as a separate clause. Label clauses may appear anywhere in a program. -Examples: - - start: /* begin execution */ - syntax: /* error processing */ - -ASSIGNMENT CLAUSES - -Assignments are identified by a variable symbol followed by an "=" operator. In -this context the operator's normal definition(an equality comparison)is -overridden,and it becomes an assignment operator. The tokens to the right of -the "=" are evaluated as an expression,and the result is assigned to(becomes -the value of)the variable symbol. - - 14 - -Examples: - - when= 'Now is the time' - answ= 3.14 * fact(5) - -INSTRUCTION CLAUSES - -Instructions begin with certain keyword symbols,each of which denotes a -particular action to be performed. Instruction keywords are recognized as such -only at the beginning of a clause,and may otherwise be used freely as symbols -(although such use may become confusing at times.) The ARexx instructions are -described in detail in Chapter 4. -Examples: - - drop a b c /* reset variables */ - say 'please' /* a polite program */ - if j > 5 then leave; /* several instructions */ - -COMMAND CLAUSES - -Commands are any ARexx expression that can't be classified as one of the -preceding types of clauses. The expression is evaluated and the result is -issued as a command to an external host,which might be the native operating -system or an application program. Commands are discussed in Chapter 5,and the -details of the host command interface are given in Chapter 10. -Examples: - - 'delete' 'myfile' /* a DOS command */ - 'jump' current+10 /* an editor command? */ - -CLAUSE CLASSIFICATION - -The process by which program lines are divided into clauses and then classified -is important in understanding the operation of an ARexx program. The language -interpreter splits the program source into groups of clauses as the program is -read,using the end of each line as a clause separator and applying the -continuation rule as required. These groups of one or more clauses are then -tokenized,and each clause is classified into one of the above types. Note that -seemingly small syntactic differences may completely change the semantic -content of a statement. For example, - - SAY 'Hello, Bill' - -is an instruction clause and will display "Hello, Bill" on the console,but - - ""SAY 'Hello, Bill' - -is a command clause,and will issue "SAY Hello, Bill" as a command to an -external program. The presence of the leading null string changes the -classification from an instruction clause to a command clause. - - 15 - -3-4 EXPRESSIONS - -Expression evaluation is an important part of ARexx programs,since most -statements include at least one expression. Expressions are composed of -strings,symbols,operators,and parentheses. Strings are used as literals in an -expression;their value in an operation is just the string itself. Fixed symbols -are also literals(remember that symbols are always translated to uppercase,) -but variable symbols may have an assigned value. Operator tokens represent the -predefined operations of ARexx;each operator has an associated priority that -determines the order in which operations will be performed. Parentheses may be -used to alter the normal order of evaluation in the expression,or to identify -function calls. A symbol or string followed immediately by an open parenthesis -defines the function name,and the tokens between the opening and(final)closing -parenthesis form the argument list for the function. - -For example,the expression "J 'fractorial is' fact(J)" is composed of a symbol -J,a blank operator,the string 'factorial is',another blank,the symbol fact,an -open parenthesis,the symbol J again,and a closing parenthesis. FACT is a -function name and (J) is its argument list,in this case the single expression -J. - -SYMBOL RESOLUTION - -Before the evaluation of an expression can proceed,the interpreter must obtain -a value for each symbol in the expression. For fixed symbols the value is just -the symbol name itself,but variable symbols must be looked up in the current -symbol table. In the example above,the expression after symbol resolution would -be "3 'factorial is' FACT(3)," assuming that the symbol J had the value 3. - -Suppose that the example above had been "FACT(J) 'is' J 'factorial'." Would the -second occurrence of symbol J still resolve to 3 in this case? In general, -function calls may have "side effects" that include altering the values of -variables,so the value of J might have been changed by the call to FACT. In -order to avoid ambiguities in the values assigned to symbols during the -resolution process, ARexx guarantees a strict left-to-right resolution order. -Symbol resolution proceeds irrespective of operator priority or parenthetical -grouping;if a function call is found,the resolution is suspended while the -function is evaluated. Note that it is possible for the same symbol to have -more than one value in an expression. - -ORDER OF EVALUATION - -After all symbol values have been resolved,the expression is evaluated based on -operator priority and subexpression grouping. Operators of higher priority are -evaluated first. ARexx does not guarantee an order of evaluation among -operators of equal priority,and does not employ a "fast path" evaluation of -boolean operators. For example,in the expression - - (1 = 2) & (FACT(3) = 6) - -the call to the FACT function will be made,although it is clear that the final -result will be 0,since the first term of the AND operation is 0. - - 16 - -3-5 NUMBERS AND NUMERIC PRECISION - -An important class of operands are those representing numbers. Numbers consist -of the characters 0-9,.+-,and blanks;an e or E may follow a number to indicate -exponential notation,in which case it must be followed by a (signed) integer). - -Both string tokens and symbol tokens may be used to specify numbers. Since the -language is typeless,variables do not have to be declared as "numeric" before -being used in an arithmetic operation. Instead,each value string is examined -when it is used to verify that it represents a number. The following examples -are all valid numbers: - - 33 - " 12.3 " - 0.321e12 - ' + 15.' - -Note that leading and trailing blanks are permitted,and that blanks may be -embedded between a "+" or "-" sign and the number body(but not within the -body.) - -BOOLEAN VALUES - -The numbers 0 and 1 are used to represent the boolean values False and True, -respectively. The use of a value other than 0 or 1 when a boolean operand is -expected will generate an error. Any number equivalent to 0 or 1,for example -"0.000" or "0.1E1," is also acceptable as a boolean value. - -NUMERIC PRECISION - -ARexx allows the basic precision used for arithmetic calculations to be -modified while a program is executing. The number of significant figures used -in arithmetic operations is determined by the Numeric Digits environment -variable, and may be modified using the NUMERIC instruction. - -The number of decimal places used for a result depends on the operation -performed and the number of decimal places in the operands. Unlike many -languages,ARexx preserves trailing zeroes to indicate the precision of the -result. If the total number of digits required to express a value exceeds the -current Numeric Digits setting,the number is formatted in exponential notation. -Two such formats are provided: - -In SCIENTIFIC notation,the exponent is adjusted so that a single digit is -placed to the left of the decimal point. - -in ENGINEERING notation,the number is scaled so that the exponent is a multiple -of 3 and the digits to the left of the decimal point range from 1 to 999. - -The numeric precision and format can be set using the NUMERIC instruction. - - 17 - -3-6 OPERATORS - -Operators can be grouped into four categories: - -Arithmetic operators require one or two numeric operands,and produce a numeric -result. -Concatenation operators join two strings into a single string. -Comparison operators require two operands,and produce a boolean(0 or 1) result. -Logical Operators require one or two boolean operands,and produce a boolean -result. - -ARITHMETIC OPERATORS - -The aritmetic operators are listed in Table 3.2 below. Note the inclusion of -the integer division(%)and remainder(//)operators,along with the usual -arithmetic operations. The result of an arithmetic operation is always foratted -based on the current Numeric Digits setting,and will never have leading or -trailing blanks. - - TABLE 3.2 ARITHMETIC OPERATORS - SEQUENCE PRIORITY OPERATION - + 8 Prefix Conversion - - 8 Prefix Negation - ** 7 Exponentiation - * 6 Multiplication - / 6 Division - % 6 Integer Division - // 6 Remainder - + 5 Addition - - 5 Subtraction - -PREFIX CONVERSION(+). This unary operator converts the operand to and internal -numeric form and formats the result based on the current Numeric Digits -settings. This causes any leading and trailing blanks to be removed,and may -result in a loss of precision. -Examples: - - ' 3.12 ' ==> 3.12 - 1.5001 ==> 1.500 /* If digits = 3 */ - -PREFIX NEGATION(-). This unary operator negates the operand. The result is -formatted based on the current Numeric Digits setting. - - 18 - -Examples: - - -' 3.12 ' ==> -3.12 - 1.5E2 ==>-150 - -EXPONENTIATION(**). The left operand is raised to the power specified by the -right operand,which must be an integer. The number of decimal places for the -result is the product of the exponent and the number of decimal places in the -base. -Examples: - - 2**3 ==>8 - 3**-1 ==>.333333333 - 0.5**3 ==>0.125 - -MULTIPLICATION(*). The product of two numbers is computed. The number of -decimal places for the result is the sum of the decimal places of the operands. -Examples: - - 12 * 3 ==>36 - 1.5 * 1.50 ==>2.250 - -DIVISION(/). The quotient of two numbers is computed. The number of decimal -places for the result depends on the current setting of the numeric DIGITS -variable;the nuber is formatted to the maximum precision required. -Examples: - - 6 / 3 ==>2 - 8 / 3 ==>2.66666667 - -INTEGER DIVISION(%). The quotient of two numbers is computed,and the integer -part of the quotient is used as the result. -Examples: - - 5 % 3 ==>1 - -8 % 3 ==>-2 - -REMAINDER(//). The result is the remainder after the two operands are divided. -The remainder for "a//b" is calculated as "a-(a%b)*b." If both operands are -positive integers,this operation yields the usual "modulo" result. - - 19 - -Examples: - - 5 // 3 ==>2 - -5 // 3 ==>-2 - 5.1 // 0.2 ==>0.1 - -ADDITION(+). The sum of two numbers is computed. The number of decimal places -for the result is the larger of the decimal places of the operands. -Examples: - - 12 + 3 ==>15 - 3.1 + 4.05 ==>7.15 - -SUBTRATION(-). The difference of two numbers is computed. As in the case of -addition,the number of decimals places for the result is the larger of the -decimal places of the operands. -Examples: - - 12 - 3 ==>9 - 5.55 - 1.55 ==>4.00 - -CONCATENATION OPERATORS - -ARexx defines two concatenation operators,both of which require two operands. -The first,identified by the operator sequence "||",joins two strings into a -single string with no intervening blank. The second concatenation operation is -identified by the blank operator,and joins the two operand strings with one -intervening blank. - -An implicit concatenation operator is recognized when a symbol and a string are -directly abutted in an expression. Concatenation by abuttal uses the "||" -operator,and behaves exactly as though the operator had been provided -explicitly. -Examples: - - 'why me,' || 'Mom?' ==>why me,Mom? - 'good' 'times' ==>good times - one'two'three ==>ONEtwoTHREE - -COMPARISON OPERATORS - -Comparisons are performed in one of three modes,and always result in a boolean -value(0 or 1.) - -Exact comparisons proceed character-by-character,including any leading blanks -that may be present. -String comparisons ignore leading blanks,and pad the shorter string with blanks -if necessary. - - 20 - -Numeric comparisons first convert the operands to an internal numeric form -using the current Numeric Digits setting,and then perform a standard arithmetic -comparison. - -Except for the exact equality and exact inequality operators,all comparison -operators dynamically determine whether a string of numeric comparison is to be -performed. A numeric comparison is performed if both operands are valid numbers -otherwise,the operands are compared as strings. - - TABLE 3.3 COMPARISON OPERATORS - -SEQUENCE PRIORITY OPERATION MODE - -== 3 Exact Equality Exact -~== 3 Exact Inequality Exact -= 3 Equality String/Numeric -~= 3 Inequality String/Numeric -> 3 Greater Than String/Numeric ->=,~< 3 Greater Than or Equal String/Numeric -< 3 Less Than String/Numeric -<=,~> 3 Less Than or Equal String/Numeric - -LOGICAL (BOOLEAN) OPERATORS - -ARexx defines the four logical operations NOT,AND,OR,and Exclusive OR,all of -which require boolean operands and produce a boolean result. Boolean operands -must have values of either 0(False)or 1(True.) An attempt to perform a logical -operation on a non-boolean operand will generate an error. - - TABLE 3.4 LOGICAL OPERATORS - - SEQUENCE PRIORITY OPERATION - - ~ 8 NOT(Inversion) - & 2 AND - | 1 OR - ^,&& 1 Exclusive OR - -3-7 STEMS AND COMPOUND SYMBOLS - -Stems and compound symbols have special properties that allow for some -interesting and unusual programming. A compound symbol can be regarded as -having the structure stem.n1.n2.n3...nk where the leading name is a stem symbol -and each node n1...nk is a fixed or simple symbol. Whenever a compound symbol -appears in a program,its name is expanded by replacing each node with its -current value as a (simple) symbol. The value string may consist of any -characters,including embedded blanks,and is not converted to uppercase. The -result of the expansion is a new name that is used in place of the compound -symbol. For example if j has the value of 3 and k has the value 7,then the -compound symbol a.j.k will expand to A.3.7. - -Stem symbols provide a way to initialize a whole class of compound symbols. -When an assignment is made to a stem symbol,it assigns that value to all -possible compound symbols derived from the stem. Thus,the value of a compound -symbol depends on the prior assignments made to itself or its associated stem. - - 21 - -Compound symbols can be regarded as a form of "associative" or "content- -addressable" memory. For example,suppose that you needed to store and retrieve -a set of names and telephone numbers. The conventional approach would be to set -up two arrays NAME and NUMBER,each indexed by an integer running from one to -the number of entries. A number would be "looked up" by scanning the name array -until the given name was found,say in NAME.12,and then retrieving NUMBER.12. -With compound symbols,the symbol NAME could hold the name to be looked-up,and -NUMBER.NAME would then expand to NUMBER.Bill(for example),which be the -corresponding number. - -Of course,compound symbols can also be used as conventional indexed arrays,with -the added convenience that only a single assignment(to the stem)is required to -initialize the entire array. - -3-8 THE EXECUTION ENVIRONMENT - -The ARexx interpreter provides a uniform environment by running each program as -a separate task(actually,as a DOS process)in the Amiga's multitasking operating -system. This allows for a flexible interface between an external host program -and the interpreter,as the host can either proceed concurrently with its -operations or can simply wait for the interpreted program to finish. - -THE EXTERNAL ENVIRONMENT - -The external environment of a program includes its task(process)structure, -input and output streams,and current directory. When each ARexx task is -created,it inherits the input and output streams and current directory from its -client,the external program that invoked the ARexx program. The current -directory is used as the starting point in a search for a program or data file. - -EXTERNAL PROGRAMS. The external environment usually includes one or more -external programs with which the ARexx program may communicate. Any program -that supports a suitable interface can receive commands from ARexx programs. -The command interface is discussed in Chapter 5. - -THE INTERNAL ENVIRONMENT - -The internal environment of an ARexx program consists of a static global -structure and one or more storage environments. The global data values are -fixed at a time the program is invoked,and include the argument strings,program -source code,and static data strings. The storage environment includes the -symbol table used for variable values,the numeric options,trace options,and -host address strings. While the global environment is unique,there may be many -storage environments during the course of the program execution. Each time an -internal function is called a new storage environment is activated and -initialized. The initial values for most fields are inherited from the previous -environment,but values may be changed afterwards without affecting the caller's -environment. The new environment persists until control returns from the -function. - - 22 - -ARGUMENT STRINGS. A program may receive one or more argument strings when it is -first invoked. These arguments persist for the duration of the program and are -never altered. The number of arguments a program receives depends in part on -the mode of invocation. ARexx programs invoked as commands normally have only -one argument string,although the "command tokenization" option may provide more -than one. A program invoked as a function can have any number of arguments if -called as an internal function,but external functions are limited to a maximum -of 15 arguments. - -The argument strings can be retrieved using either the ARG instruction or the -ARG() Built-In function. ARG() can also return the total number of arguments,or -the status(as "exists" or "omitted")of a particular argument. - -THE SYMBOL TABLE. Every storage environment includes a symbol table to store -the value strings that have been assigned to variables. This symbol table is -organized as a two-level stores entries for simple and stem symbols,and the -secondary level is used for compound symbols. All of the compound symbols -associated with a particular stem are stored in one tree,with the root of the -tree held by the entry for the stem. - -Symbols are not entered into the table until an assignment is made to the -symbol. Once created,entries at the primary level are never removed,even if the -symbol subsequently becomes uninitialized. Secondary trees are released -whenever an assignment is made to the stem associated with the tree. - -For the most part ARexx programmers need not be concerned with the details of -storage environments except to understand what values are saved when a function -is called. Applications developers who need to manipulate environment values -should refer to the structure definitions in the INCLUDE files provided on the -ARexx distribution disk. - -INPUT AND OUTPUT - -Most computer programs require some means of communicating with the outside -world,either to accept input data or to pass along results. The REXX language -includes only a minimal specification of input and output (I/O)operations, -leaving the choice of additional functionality to the language implementor. -This is in keeping with the design of many computer languages. For instance,the -"C" language has no statements dedicated to I/O,but instead relies on a -standardized set of I/O functions. - -ARexx extends the I/O facilities fo REXX by providing Built-In functions to -manipulate external files. Files are referenced by a logical name associated -with the file when it is first opened. The initial input and output streams are -given the names STDIN and STDOUT. - -ARexx maintains a list of all of the files opened by a program and -automatically closes them when the program finishes. There is no limit to the -number of files that may be open simultaneously. - - 23 - -RESOURCE TRACKING - -ARexx provides complete tracking for all of the dynamically-allocated resources -that it uses to execute a program. These resources include memory space,DOS -files and related structures,and the message port structures supported by -ARexx. The tracking system was designed to allow a program to "bail out" at any -point(perhaps due to an execution error)without leaving any hanging resources. - -It is possible to go outside of the interpreter's resource tracking net by -making calls directly to the Amiga's operating system from within an ARexx -program. In these cases it is the programer's responsibility to track and -return all of the allocated resources. ARexx provides a special interrupt -facility so that a program can retain control after an execution error,perform -the required cleanup,and then make an orderly exit. Chapter 7 has information -on the ARexx interrupt system. - - 24 - - CHAPTER 4 INSTRUCTIONS - -Instruction clauses are identified by an initial keyword symbol that is not -followed by a colon(:)or an equals(=)operator. Each instruction signifies a -specific action,and may be followed by one or more subkeywords,expressions,or -other instruction-specific information. Instruction keywords and subkeywords -are recognized only in this specific context,and are therefore not "reserved -words" in the usual sense of the term. Keywords may be used freely as variables -or function names,although such usage may become confusing at times. - -In the descriptions that follow,keywords are shown in uppercase and optional -parts of the instruction are enclosed in brackets. Alternative selections are -separated by a vertical bar(|),and required alternative are enclosed in braces -({}). - -4-1 ADDRESS - -Usage: ADDRESS [Symbol|string|VALUE] [expression]] -This instruction specifies a host address for commands issued by the -interpreter. A host address is the name associated with an external program to -which commands can be sent;external hosts are described in Chapter 5. ARexx -maintains two host addresses:a "current" and a "previous"address is lost,and -the "current" and a "previous" value. Whenever a new host address is supplied, -the "previous" address is lost,and the "current" address becomes the "previous" -one. These host addresses are part of a program's storage environment and are -preserved across internal function calls. The current address can be retrieved -with the Built-In function ADDRESS(). There are four distinct forms for the -ADDRESS instruction: - -ADDRESS {string | symbol} expression. The expression is evaluated and the -result is issued to the host specified by the string or symbol,which is taken -as a literal. No changes are made to the current or previous address strings. -This provides a convenient way to issue a single command to an external host -without disturbing the current host addresses. The return code from the command -is treated as it would be from a command clause. - -ADDRESS {string | symbol}. The string or symbol,taken as a literal,specifies -the new host address. The current host address becomes the previous address. - -ADDRESS [VALUE] expression. The result of the expression specifies the new host -address,and the current address becomes the previous address. The VALUE keyword -may be omitted if the first token of the expression is not a symbol or string. - -ADDRESS. This form interchanges the current and previous hosts. Repeated -execution will therefore "toggle" between the two host addresses. - - Examples: - -address edit /* set an new host address */ -address edit 'top' /* move to the top */ -address VALUE edit n /* compute a new host address */ -address /* swap current and previous */ - - 25 - -Usage: ARG [template] [,template...] -ARG is shorthand form for the PARSE UPPER ARG instruction. It retrieves one or -more of the argument strings available to the program,and assigns values to the -variables in the template. The number of argument strings available depends on -the whether the program was invoked as a command or a function. Command -invocations normally have only one argument string,but functions may have up to -15. The argument strings are not altered by the ARG instruction. - -The structure and processing of templates is described briefly with the PARSE -instruction,and in greater depth in Chapter 8. - Example: - -arg first,second /* fetch arguments */ - -4-3 BREAK - -Usuage: BREAK -The BREAK instruction is used to exit from the range of a DO instruction or -from within an INTERPRETed string,and is valid only in these contexts. If used -within a DO statement,BREAK exits from the innermost DO statement containing -the BREAK. This contrasts with the otherwise similar LEAVE instruction,which -exits only from an interative DO. - Example: - -do /* begin block */ - if i>3 then break /* all done? */ - a = a + 1 - y.a = name - end /* end block */ - -4-4 CALL - -Usage: CALL {symbol | string} [expression] [,expression,...] -The CALL instruction is used to invoke an internal or external function. The -function name is specified by the symbol or string token,which is taken as a -literal. Any expressions that follow are evaluated and become the arguments to -the called function. The value returned by the function is assigned to the -special variable RESULT. It is not an error if a result string is not returned; -in this case the variable RESULT is DROPed(becomes uninitialized.) - -The linkage to the function is established dynamically at the time of the call. -ARexx follows a specific search order in attempting to locate the called -function;this process is described in Chapter 6. - Example: - -call center name,length+4,'+' - - 26 - -Usage: DO [var=exp] [To exp] [BY exp]] [FOR exp] [FOREVER] [WHILE exp | UNTIL -exp] -The DO instruction begins a group of instructions to be executed as a block. -The range of the DO instruction includes all statements up to and including an -eventual END instruction. There are two basic forms of the instruction: - -The DO keyword by itself defines a block of instructions to be executed once. - -If any iteration specifiers follow the DO keyword,the block of instructions is -executed repeatedly until a termination condition occurs. - -An interative DO instruction is sometimes called a "loop",since the interpreter -"loops back" to perform the instruction repeatedly. The various parts of the DO -instruction are described below. - -Initializer expression. An initializer expression of the form "variable= -expression" defines the index variable of the loop. The expression is evaluated -when the DO range is first activated,and the result is assigned to the index -variable. On subsequent iterations an expression of the form "variable = -variable + increment" is evaluated,where the increment is the result of the BY -expression. If specified, the initializer expression must precede any of the -other subkeywords. - -BY expression. The expression following a BY symbol defines the increment to be -added to the index variable in each subsequent iteration. The expression must -yield a numeric result,which may be positive or negative and need not be an -integer. The default increment is 1. - -TO expression. The result of the TO expression specifies the upper(or lower) -limit for the index variable. At each iteration the index variable is compared -to the TO result. If the increment(BY result)is positive and the variable is -greater than the limit,the DO instruction terminates and control passes to the -statement following the END instruction. Similarly,the loop terminates if the -increment is negative and the index variable is less than the limit. - -FOR expression. The FOR expression must yield a positive whole number when -evaluated,and specifies the maximum number of iterations to be performed. The -loop terminates when this limit is reached irrespective of the value of the -index variable. - -FOREVER. The FOREVER keyword can be used if an iterative DO instruction is -required but no index variable is necessary. Presumably the loop will be -terminated by a LEAVE or BREAK instruction contained within the loop body. - -WHILE expression. The WHILE expression is evaluated at the beginning of each -iteration and must result in a boolean value. The iteration proceeds if the -result is 1;otherwise,the loop terminates. - - 27 - -UNTIL expression. The UNTIL expression is evaluated at the end of each -iteration and must result in a boolean value. The instruction continues with -the next iteration if the result is 0,and terminates otherwise. - -The initializer,BY,TO,and FOR expressions are evaluated only when the -instruction is first activated,so the increment and limits are fixed throughout -the execution. Note that a limit need not be supplied;for example,the -instruction "DO i=1" will simply count away forever. Note also that only one of -the WHILE or UNTIL keywords can be specified. -Example: - -do i=1 to limit for 5 while time <50 - y.1=i*time - end - -4-6 DROP - -Usage: DROP variable [variable...] -The specified variable symbols are reset to their uninitialized state,in which -the value of the variable is the variable name itself. It is not an error to -DROP a variable that is already uninitialized. DROPping a stem symbol is -equivalent to DROPping the values of all possible compound symbols derived from -that stem. -Example: - -a=123 /* assign a value */ -drop a b /* drop some */ -say a b /* ==>A B */ - -4-7 ECHO - -Usage: ECHO [expression] -The ECHO instruction is a synonym for the SAY instruction. It displays the -expression result on the console. -Example: - -echo "You don't SAY!" - -4-8 ELSE - -Usage: ELSE [;] [conditional statement] -The ELSE instruction provides the alternative conditional branch for an IF -statement. It is valid only within the range of an IF instruction,and must -follow the conditional statement of the THEN branch. If the THEN branch wasn't -executed,the statement following the ELSE clause is performed. - -Binding. ELSE clauses always bind to the nearest(preceding)IF statement. It may -be necessary to provide "dummy" ELSE clauses for the inner IF ranges of a -compound IF statement in order to allow alternative branches for the outer IF -statements. In this case it is not sufficient to follow the else with a -semicolon or a null clause. Instead,the NOP(no-operation)instruction can be -used for this purpose. - - 28 - -Example: - -if 1 > 2 then say 'really?' - else say 'I thought so' - -4-9 END - -Usage: END [variable] -The END instruction terminates the range of a DO or SELECT instruction. If the -optional variable symbol is supplied,it is compared to the index variable of -the DO statement(which must therefore be iterative). An error is generated if -the symbols do not match,so this provides a simple mechanism for matching the -DO and END statements. -Example: - -do i=1 to 5 /* index variable is I */ - say i - end i /* end "I" loop */ - -4-10 EXIT - -Usage: EXIT [expression] -The EXIT instruction terminates the execution of a program,and is valid -anywhere within a program. The evaluated expression is passed back to the -caller as the function or command result. - -Results Processing. The processing of the EXIT result depends on whether a -result string was requested by the calling program,and whether the current -invocation resulted from a command or function call. If a result string was -requested,the expression result is copied to a block of allocated memory and a -pointer to the block is returned as the secondary result of the call. - -If the caller did not request a result string,and the program was invoked as a -command,then an attempt is made to convert the expression result to an -integer. This value is then returned as the primary result,with 0 as the -secondary result. This allows the EXIT expression to be interpreted as a -"return code" by the caller. Refer to Chapter 10 for further information on -the data structures used to return the result string. -Examples: - -exit /* no result needed */ -exit 12 /* an error return? */ - -4-11 IF - -Usage: IF expression [THEN] [;] [conditional statement] -The IF instruction is used in conjunction with THEN and ELSE instruction to -conditionally execute a statement. The result of the expression must be a -boolean value. If the result is 1 (True),the statement following the THEN -symbol is executed;otherwise,control passes to the next statement(which might -be an ELSE clause.) The THEN keyword need not immediately follow the IF -expression,but may appear as a separate clause. The instruction - - 29 - -is actually analyzed as "IF expression; THEN; statement;." In essence,the IF -statement begins a syntactic range and establishes the test condition that -determines whether subsequent THEN or ELSE clauses will be performed. - -Any valid statement may follow the THEN symbol;in particular,a "DO; ... END;" -group allows a series of statements to be performed conditionally. -Examples: - -if result < 0 then exit /* all done? */ - -4-12 INTERPRET - -Usage: INTERPRET expression -The expression is evaluated and the result is executed as one or more program -statements. The statements are considered as a group,as though surrounded by a -"DO; ...;END" combination. Any statements can be included in the INTERPRETed -source,including DO or SELECT instruction. - -An INTERPRET instruction activates a control range when it is executed,which -serves as a "fence" for LEAVE and ITERATE instructions. These instructions can -therefore be used only with DO-loops defined within the INTERPRET. The BREAK -instuction can be used to terminate the processing of INTERPRETed statements. -While it is not an error to include label clauses within the interpreted -string,only those labels defined in the original source code are searched -during a transfer of control. - -The INTERPRET instruction can be used to solve programming problems in -interesting and novel ways. Programs can be constructed dynamically and then -executed using this instruction,or program fragments may be passed as arguments -to functions,which then INTERPRET them. -Example: - -inst = 'say' /* an instruction */ -interpret inst hello /* ..."say HELLO" */ - -4-13 ITERATE - -Usage: ITERATE [variable] -The ITERATE instruction terminates the current iteration of a DO instruction -and begins the next iteration. Effectively,control passes to the END statement -and then(depending on the outcome of the UNTIL expression)back to the DO -statement. The instruction normally acts on the innermost iterative DO range -containing the instruction. An error results if the LEAVE instruction is not -contained within an iterative DO instruction. - -The optional variable symbol specifies which DO range is to be exited,in the -event that several nested ranges exist. The variable is taken as a literal and -must match the index variable of a currently active DO instruction. An error -results if no such matching DO instruction is found. - - 30 - -Example: - - do i=1 to 3 - if i=j then iterate i - end - -4-14 LEAVE - -Usage:LEAVE [variable] -LEAVE forces an immediate exit from the iterative DO range containing the -instruction. An error results if the LEAVE instruction is not contained within -an iterative DO instruction. - -The optional variable symbol specifies which DO range is to be exited,in the -event that several nested ranges exist. The variable is taken as a literal and -must match the index variable of a currently active DO instruction. An error -results if no such matching DO instruction is found. -Example: - - do i=1 to limit - if i > 5 then leave /* maximum iterations */ - end - -4-15 NOP - -Usage: NOP -The NOP or "no-operation" instruction does just that:nothing. It is provided to -control the binding of ELSE clauses in compound IF statements. -Example: - - if i=j then /* first (outer) IF */ - if j=k then a=o /* inner IF */ - else nop /* binds to inner IF */ - else a=a+1 /* binds to outer IF */ - -4-16 NUMERIC - -Usage: NUMERIC {DIGITS | FUZZ} expression - or: NUMERIC FORM {SCIENTIFIC | ENGINEERING} -This instruction sets options relating to the numeric precision and format. The -valid forms of the NUMERIC instruction are: - -NUMERIC DIGITS expression. Specifies the number of digits of precision for -arithmetic calculations. The expression must evaluate to a positive whole -number. - -NUMERIC FUZZ expression. Specifies the number of digits to be ignored in -numeric comparison operations. This must be a positive whole number that is -less than the current DIGITS setting. - -NUMERIC FORM SCIENTIFIC. Specifies that numbers that require exponential -notation be expressed in SCIENTIFIC notation. The exponent is adjusted so that -the mantissa (for non-zero) numbers) is between 1 and 10. This is the default -format. - - 31 - -NUMERIC FORM ENGINEERING. Selects ENGINEERING format for numbers that require -exponential notation. ENGINEERING format normalizes a number so that its -exponent is a multiple of three and the mantissa(if not 0)is between 1 and -1000. - -The numberic options are preserved when an internal function is called. -Examples: - - numeric digits 12 /* precision */ - numeric form scientific /* format */ - -4-17 OPTIONS - -Usage: OPTIONS [FAILAT expression] - or: OPTIONS [PROMPT expression] - or: OPTIONS [RESULTS] -The OPTIONS instruction is used to set various internal defaults. The FAILAT -expression sets the limit at or above which command return codes will be -signalled as errors,and must evaluate to an integer value. The PROMPT -expression provides a string to be used as the prompt with the PULL (or PARSE -PULL)instruction. The RESULTS keyword indicates that the interpreter should -request a result string when it issues commands to an external host. - -The internal options controlled by this instruction are preserved across -function calls,so an OPTIONS instruction can be issued within an internal -function without affecting the callers environment. If no keyword is specified -with the OPTIONS instuction,all controlled options revert to their default -settings. -Example: - - options failat 10 - options prompt "Yes Boss?" - options results - -4-18 OTHERWISE - -Usage: OTHERWISE [;] [conditional statement] -This instruction is valid only within the range of a SELECT instruction,and -must follow the "WHEN ... THEN" statements. If none of the preceding WHEN -clauses have succeeded,the statement following the OTHERWISE instruction is -executed. An OTHERWISE is not mandatory within a SELECT range. However,an error -will result if the OTHERWISE clause is omitted and none of the WHEN -instructions succeed. -Example: - - select - when i=1 then say 'one' - when i=2 then say 'two' - otherwise say 'other' - end - - 32 - -4-19 PARSE - -Usage: PARSE [UPPER] inputsorce [template] [,template...] -The PARSE instruction provides a mechanism to extract one or more substrings -from a string and assign them to variables. The input string can come from a -variety of sources,including argument strings,an expression,or from the -console. The template provides both the variables to be given values and the -way to determine the value strings. The template may be omitted if the -instruction is intended only to create the input string. The different options -of the instruction are described below. - -INPUT SOURCES - -The sources for the input strings are specified by the keyword symbols listed -below. When multiple templates are supplied,each template receives a new input -string, although for some source options the new string will be identical to -the previous one. The input source string is copied before being parsed,so the -original strings are never altered by the parsing process. - -UPPER. This optional keyword may be used with any of the input sources,and -specifies that the input string is to be translated to uppercase before being -parsed. It must be the first token following PARSE. - -ARG. This input option retrieves the argument strings supplied when the program -was invoked. Command invocations normally have only a single argument string, -but functions may have up to 15 argument strings. Multiple templates may be -given to retrieve successive argument strings. - -EXTERNAL. The input strings is read from the console. If multiple templates are -supplied,each template will read a new string. This source option is the same -as PULL. - -NUMERIC. The current numeric options are placed in a string in the order -DIGITS,FUZZ,and FORM,separated by a single space. - -PULL. Reads a string from the input console. If multiple templates are -supplied,each template will read a new string. - -SOURCE. The "source" string for the program is retrieved. This string is -formatted as "{COMMAND | FUNCTION} {0 | 1} called resolved ext host." The first -token indicates whether the program was invoked as a command or as a function. -The second token is a boolean flag indicating whether a result string was -requested by the caller. The called token is the name used to invoke this -program,while the resolved token is the final resolved name of the program. The -ext token is the file extension to be used for searching(the default is -"REXX"). Finally,the host token is the initial host address for commands. - -VALUE expression WITH. The input string is the result of the supplied -expression. The WITH keyword is required to separate the expression from the -template. The expression result may be parsed repeatedly by using multiple -templates,but the expression is not reevaluated. - -VAR variable. The value of the specified variable is used as the input string. -When multiple templates are provided,each template uses the current value of -the variable. - - 33 - -This value may change if the variable is included as an assignment target in -any of the templates. - -VERSION. The current configuation of the ARexx interpreter is supplied in the -form "ARexx version cpu mpu video freq". The version toekn is the release level -of the interpreter,formatted as V1.0. The cpu token indicates the processor -currently running the program,and will be one of the values 68000,68010,or -68020. The mpu token will be either NONE or 68881 depending on whether a math -coprocessor is available on the system. The video token will indicate either -NTSC or PAL,and the freq token gives the clock(line)frequency as either 60HZ or -50 HZ. - -TEMPLATES - -Parsing is controlled by a template,which may consist of symbols,strings, -operators,and parentheses. During the parsing operation the input string is -split into substrings that are assigned to the variable symbols in the -template. The process continues until all of the variables in the template have -been assigned a value;if the input string is "used up",any remaining variables -are given null values. - -Templates are described in depth in Chapter 8,so only a simplified description -is presented here. The goal of the parsing operation is to associate a -"current" and "next" position with each variable symbol in the template. The -substring between these positions is then assigned as the value to the -variable. There are three basic methods used to determine the value strings. - -PARSING BY TOKENIZATION. When a variable in the template is followed -immediately by another variable,the value string is determined by breaking the -input string into words separated by blanks. Each word is assigned to a -variable in the template. - -Values determined by tokenization will never have leading or trailing blanks. -Normally the last variable in the template receives the untokenized remainder -of the input string,since it is not followed by a symbol. A "placeholder" -symbol,signified by a period(.),may be used to force tokenization. Placeholders -behave like variables in the template except that they are never actually -assigned a value. -Example: - - /* Numeric string is: "9 0 SCIENTIFIC" */ - parse numberic digits fuzz form . - say digits /* =>9 */ - say fuzz /* =>0 */ - say from /*=> SCEIENTIFIC */ - -PARSING BY POSITION. If the fields in the input string have known positions, -value strings can be specified by absolute or relative positions. Relative -positions are indicated by a number preceded by a "+" or "-" operator. Each -positional marker updates the scan position in the string. The value assigned -to a variable is the string from the current position up to,but not including, -the next position in the string. - - 34 - -Example: - - /* assume argument is "1234567890" */ - parse arg 1 a 3 b +2 1 c - say a b c /* ==> 12 34 1234567890 */ - -PARSING WITH PATTERNS. Fields in the input string separated by specific -characters or strings can be parsed using a pattern,which is matched against -the input string. A pattern is specified in the template as a string token,or -alternatively as a symbol enclosed in parentheses. The position in the parse -string matched by the pattern determines the value strings. The pattern is -removed from the input string when a match is found;this is the only parsing -operation that modifies the input string. -Example: - - check = 'one,two,three' - parse var check a ',' b ',' c - say a b c /* ==> one two three */ - -4-20 PROCEDURE - -Usage:PROCEDURE [EXPOSE variable [variable...]] -The PROCEDURE instruction is used within an internal function to create a new -symbol table. This protects the symbols defined in the caller's environment -from being altered by the execution of the function. PROCEDURE is usually the -first statement within the function,although it is valid anywhere withing the -function body. It is an error to execute two PROCEDURE statements within the -function. - -EXPOSING VARIABLES. The EXPOSE subkeyword provides a selective mechanism for -accessing the caller's symbol table,and for passing global variables to a -function. The variables following the EXPOSE keyword are taken to refer to -symbols in the caller's table. Any subsequent changes made to these variables -will be reflected in the caller's environment. - -The variables in the EXPOSE list may include stems or compound symbols,in which -case the ordering of the variables becomes significant. The EXPOSE list is -processed from left to right,and compound symbols are expanded based on the -values in effect in the new generation. For example,suppose that the value of -the symbol J in the previous gneration is 123,and that J is unitialized in the -new generation. Then PROCEDURE EXPOSE J A.J will expose J and A.123,whereas -PROCEDURE EXPOSE A.J J will expose A. J. and J. Exposing a stem has the effect -of exposing all possible compound symbols derived from that stem. -Example: - - fact: procedure /* a recursive function */ - arg i - if i <=1 - then return 1 - else return i*fact(i-1) - - 35 - -Usage:PULL [template] [,template...] -This is a shorthand form of the PARSE UPPER PULL instruction. It reads a string -from the input console,translates it to uppercase,and parses it using the -template. Multiple strings can be ready by supplying additional templates. The -instruction will read from the console even if no template is given. - -Templates are described briefly with the PARSE instruction and in greater depth -in Chapter 8. -Example: - - pull first last. /* read names */ - -4-22 PUSH - -Usage: PUSH [expression] -The PUSH instruction is used to prepare a stream of data to be ready by a -command shell or other program. It appends a "newline" to the result of the -expression and then stacks or "pushes" it into the STDIN stream. Stacked lines -are placed in the stream in "last-in, first-out" order,and are then available -to be ready just as though they had been entered interactively. For example, -after issuing the instructions - - push line 1 - push line 2 - push line 3 - -the steam would be read in the order "line 3," "line 2" and "line 1." - -There are several restrictions governing the use of the PUSH instruction and -its alter ego QUEUE. These instructions use a special I/O mechanism to -accomplish their task,and as a result can be used only with an interactive -(stream-model) I/O device like a console or pipe. The stream must be managed by -with a DOS handler that supports the special ACTION_STACK (for PUSH) or -ACTION_QUEUE (for QUEUE) command. - -PUSH allows the STDIN stream to be used as a private scratchpad to prepare data -for subsequent processing. For example,several files could be concatenated with -delimiters between them by simply reading the input files,PUSHing the lines -into the stream,and inserting a delimiter where required. Once the stacked -lines are exhausted,the stream reverts to its normal source of data. -Example: - - /* Stack commands for compile and link*/ - push "blink c.o+main.o library amiga.lib to myprog" - push "cc main" - - 36 - -4-23 QUEUE - -Usage:QUEUE [expression] -The QUEUE instruction is used to prepare a stream of data to be read by a -command shell or other program. It is very similar to the preceding PUSH -instruction,and differs only that the data lines are placed in the STDIN stream -in "first-in,first-out" order. In this case the instruction - - queue line 1 - queue line 2 - queue line 3 - -would be read in the order "line 1," "line 2," and "line 3." The QUEUEd lines -always precede all interactivly-entered lines,and always follow any PUSHed -(stacked)lines. - -The same restriction noted with the use of the PUSH instruction apply to the -QUEUE instruction. The queueing mechanism uses the ACTION_QUEUE command,so the -DOS handler associated with the STDIN stream must support this command. - -In most cases the choice of whether to use PUSH or QUEUE is just a matter of -convenience or personal preference. Each of them provides a "scratch pad" -facility similar to that provided by an I/O pipe,but useful within one program -or task rather than just for interprocess communications. -Example: - - /* Queue commands for compile and link */ - queue "cc main" - queue "blink c.o+main.o library amiga.lib to myprog" - -4-24 RETURN -RETURN is used to leave a function and return control to the point of the -previous function invocation. The evaluated expression is returned as the -function result. If an expression is not supplied,an error may result in the -caller's environment. Functions called from within an expression must return a -result string,and will generate an error if no result is available. Function -invoked by the CALL instruction need not return a result. - -A RETURN issued from the base environment of a program is not an error,and is -equivalent to an EXIT instruction. Refer to the EXIT instruction for a -description of how result strings are passed back to an external caller. -Example: - - return 6*7 /*the answer */ - - 37 - -4-25 SAY - -Usage:SAY [expression] -The result of the evaluated expression is written to the output console,with a -"newline" character appended. If the expression is omitted,a null string is -sent to the console. -Example: - - say 'The anwer is ' value - -4-26 SELECT - -Usage:SELECT -This instruction begins a group of instructions containing one or more WHEN -clauses and possibly a single OTHERWISE clause,each followed by a conditional -statement. - -Only one of the conditional statements within the SELECT group will be -executed. Each WHEN statement is executed in succession until one succeeds;if -none succeeds,the OTHERWISE statement is executed. The SELECT range must be -terminated by an eventual END statement. -Example: - - select - when i=1 then say 'one' - when i=2 then say 'two' - otherwise say 'other' - end - -4-27 SHELL - -Usage:SHELL [symbol | string] [expression] -The SHELL instruction is a synonym for the ADDRESS instruction. -Example: - - shell edit /* set host to 'EDIT' */ - -4-28 SIGNAL - -Usage: SIGNAL {ON |OFF} condition - or: SIGNAL [VALUE] expression -There are two forms of the SIGNAL instruction. The first form illustrated -controls the state of the internal interrupt flags. Interrupts allow a program -to detect and retain control when certain errors occur,and are discussed in -Chapter 7. In this form SIGNAL must be followed by one of the keywords ON or -OFF and one of the condition keywords listed below. The interrupt flag -specified by the condition symbol is then set to the indicated state. The valid -signal conditions are: - -BREAK_C A "control-C" break was detected. -BREAK_D A "control-D" break was detected. -BREAK_E A "control-E" break was detected. - - 38 - -BREAK_F A "control-F" break was detected. -ERROR A Host command returned a non-zero code. -HALT An external HALT request was detected. -IOERR An error was detected by the I/O system. -NOVALUE An uninitialized variable was used. -SYNTAX A syntax or execution error was detected. - -The condition keywords are interpreted as labels to which control will -transferred if the selected condition occurs. For example,if the ERROR -interrupt is enabled and a command returns a non-zero code,the interpreter will -transfer control to the label ERROR:. The condition label must of course be -defined in the program;otherwise,an immediate SYNTAX error results and the -program exits. - -In the second form of the instruction,the tokens following SIGNAL are evaluated -as an expression. An immediate interrupt is generated that transfers control to -the label specified by the expression result. The instruction thus acts as a -"computed goto." - -INTERRUPTS. Whenever an interrupt occurs,all currently active control ranges -(IF,DO,SELECT,INTERPRET,or interactive TRACE) are dismantled before the -transfer of control. Thus,the transfer cannot be used to jump into the range of -a DO-loop or other control structure. Only the control structures in the -current environment are affected by a SIGNAL condition,so it is safe to SIGNAL -from within an internal function without affecting the state of the caller's -environment. - -SPECIAL VARIABLES. The special variable SIGL is set to the current line number -whenever a transfer of control occurs. The program can inspect SIGL to -determine which line was being executed before the transfer. If an ERROR or -SYNTAX condition causes an interrupt,the special variable RC is set to the -error code that triggered the interrupt. For the ERROR condition,this code is -usually an error secerity level. The SYNTAX condition will always indicate an -ARexx error code. -Examples: - - signal on error /* enable interrupt */ - signal off syntax /* disable SYNTAX */ - signal start /* goto START */ - -4-29 THEN - -Usage:THEN[;] [conditional statement] -The THEN instruction must be the next statement following an IF or WHEN -instruction,and is valid only in that context. It tests whether the preceding -expression evaluated to 1(True),in which case the conditional statement -following the THEN is performed. If the expression result was a 0(False),the -conditional statement is skipped. - - 39 - -Example: - - if i=j - then say 'equal' - else say 'not equal' - -4-30 TRACE - -Usage:TRACE [symbol|string|[[VALUE] expression]] -The TRACE instruction is used to set the internal tracing mode. If a symbol or -string is supplied,it is taken as a literal. Otherwise,the tokens following the -VALUE keyword are evaluated as an expression. The VALUE keyword can be omitted -if the expression doesn't start with a symbol or string token. - -In either case the result string is converted to uppercase and checked first -for one of the "alphabetic" options. The valid alphabetic options are ALL, -COMMANDS,ERRORS,INTERMEDIATES,LABELS,RESULTS,and SCAN. These can be spelled out -in full or shortened to the initial character,and are described in Chapter 7. -If the result doesn't match any of these options,the interpreter attempts to -convert it to an integer. A conversion failure here will be reported as an -error. - -PREFIX CHARACTERS. Two special symbol characters may precede any of the -alphabetic keywords. The "?" character interactive tracing,and the "!" -character controls command inhibition. These characters act as "toggles" to -alternatively select and de-select the respective modes. Any number of prefix -characters may precede an alphabetic option. Interactive tracing and command -inhibition are described in Chapter 7. - -NUMERIC OPTION. If the specified trace option is a negative whole number,it is -accepted as a trace suppression count. The suppression count is the number of -clauses(that would otherwise be traced)to be passed over before resuming the -tracing display. Suppression counts are ignored execept during interactive -tracing. -Examples: - - trace ?r /* interactive RESULTS */ - trace off - trace -20 /* skip 20 clauses */ - -4-31 UPPER - -Usage:UPPER variable [variable...] -The values of the variables in the list are converted to uppercase. It is not -an error to include an uninitialized variable in the list,but it will be -trapped if the NOVALUE interrupt has been enabled. - -The TRANSLATE() or UPPER() Built-In functions could also be used to convert -variables to uppercase,but the instruction form is more concise(and faster) if -several variables are being converted. - - 40 - -Example: - - when='Now is the time' - upper when - say when /* NOW IS THE TIME */ - -4-32 WHEN - -Usage:WHEN expression [THEN [;] [conditional statement]] -The WHEN instruction is similar to the IF instruction,but is valid only within -a SELECT range. Each WHEN expression is evaluated in turn and must result in a -boolean value. If the result is a 1,the conditional statement is executed and -control passes to the END statement that terminates the SELECT. As in the case -of the IF instruction,the THEN need not be part of the same clause. -Example: - - select; - when i1 - say abbrev('almost','alm',4) ==>0 - say abbrev('any','') ==>1 - -ABS() - -Usage:ABS(number) -Returns the absolute value of the number argument,which must be numeric. -Examples: - - say abs(-5.35) ==>5.35 - say abs(10) ==>10 - -ADDLIB() - -Usage ADDLIB(name,priority,[offset,version]) -Adds a function library or a function host to the Library List maintained by -the resident process. The name argument specifies either the name of a function -library or the public message port associated with a function host. The name is -case-sensitive,and any libraries thus declared should reside in the system -LIBS: directory. The priority argument specifies the search priority and must -be an integer between 100 and -100,inclusive. The offset and version arguments -apply only to libraries. The offset is the integer offset to the library's -"query" entry point,and the version is an integer specifying the minimum -acceptable release level of the library. - -The function returns a boolean result that indicates whether the operation was -successful. Note that if a library is specified,it is not actually opened at -this time;similarly,no check is performed as to whether a specified function -host port has been opened yet. -Example: - - say addlib("rexxsupport.library",0,-30,0)==>1 - call addlib "EtherNet",-20 /* a gateway */ - - 51 - -ADDRESS() - -Usage:ADDRESS() -Returns the current host address string. The host address is the message port -to which commands will be sent. The SHOW()function can be used to check whether -the required external host is actually available. -See Also:SHOW() -Example: - - say address() ==>REXX - -ARG() - -Usage:ARG([number],['Exists' | 'Omitted']) -ARG()returns the number of arguments supplied to the current environment. If -the number parameter alone is supplied,the corresponding argument string is -returned. If a number and one of the keywords Exists or Omitted is given,the -boolean return indicates the status of the corresponding argument. Note that -the existence or omission test does not indicate whether the string has a null -value,but only whether a string was supplied. -Examples: - - /* Assume arguments were: ('one,,10) */ - say arg() ==>3 - say arg(1) ==>one - say arg(2,'0') ==>1 - -B2C() - -Usage:B2C(string) -Converts a string of binary digits(0,1)into the corresponding(packed)character -representation. The conversion is the same as though the argument string had -been specified as a literal binary string(e.g. '1010'B). Blanks are permitted -in the string,but only at byte boundaries. This function is particularly useful -for creating strings that are to be used as bit masks. -See also:X2C() -Examples: - - say b2c('00110011') ==>3 - say b2c('01100001') ==>a - -BITAND() - -Usage:BITAND(string1,string2,[pad]) -The argument strings are logically ANDed together,with the length of the result -being the longer of the two operand strings. If a pad character is supplied,the -shorter string is padded on the right;otherwise,the operation terminates at the -end of the shorter string and the remainder of the longer string is appended to -the result. -Example: - - bitand('0313'x,'FFF0'x) ==>'0310'x - - 52 - -BITCHG() -Usage:BITCHG(string,bit) -Changes the state of the specified bit in the argument string. Bit numbers are -defined such that bit 0 is the low-order bit of the rightmost byte of the -string. -Example: - bitchg('0313'x,4) ==>'0303'x - -BITCLR() -Usage:BITCLR(string,bit) -Clears(sets to zero)the specified bit in the argument string. Bit numbers are -defined such that bit 0 is the low-order bit of the rightmost byte of the -string. -Example: - bitclr('0313'x,4) ==>'0303'x - -BITCOMP() -Usage:BITCOMP(string1,string2,[pad]) -Compares the argument strings bit-by-bit,starting at bit number 0. The returned -value is the bit number of the first bit in which the strings differ,or -1 if -the strings are identical. -Examples: - bitcomp('7F'x,'FF'x) ==>7 - bitcomp('FF'x,'FF'x) ==>-1 - -BITOR() -Usage:BITOR(string1,string2,[pad]) -The argument strings are logically ORed together,with the length of the result -being the longer of the two operand strings. If a pad character is supplied,the -shorter string is padded on the right;otherwise,the operation terminates at the -end of the shorter string and the remainder of the longer string is appended to -the result. -Example: - bitor('0313'x,'003F'x) ==>'033F'x - -BITSET() -Usage:BITSET(string,bit) -Sets the specified bit in the argument string is 1. Bit numbers are defined -such that bit 0 is the low-order bit of the rightmost byte of the string. -Example: - bitset('0313'x,2) ==>'0317'x - -BITTST() -Usage:BITTST(string,bit) -The boolean return indicates the state of the specified bit in the argument -string. - - 53 - -Bit numbers are defined such that bit 0 is the low-order bit of the rightmost -byte to the string. -Example: - bittst('0313'x,4) ==>1 - -BITXOR() -Usage:BITAND(string1,string2,[pad]) -The argument strings are logically exclusively-ORed together,with the length of -the result being the longer of the two operand strings. If a pad character is -supplied,the shorter string is padded on the right;otherwise,the operation -terminates at the end of the shorter string and the remainder of the longer -string is appended to the result. -Example: - bitxor('0313'x,'001F'x) ==>'030C'x - -C2B() -Usage:C2B(string) -Converts the character string into the equivalent string of binary digits. -See Also:C2X() -Example: - say c2b('abc') ==>011000010110001001100011 - -C2D() -Usage:C2D(string,[n]) -Converts the string argument from its character representation to the -corresponding decimal number,expressed as ASCII digits(0-9). If n is supplied, -the character string is considered to be a number expressed in n bytes. The -string is truncated or padded with nulls on the left as required,and the sign -bit is extended for the conversion. -Examples: - say c2d('0020'x) ==>32 - say c2d('FFFF') ==>1 - say c2d('FF0100',x,2) ==>256 - -C2X() -Usage:C2X(string) -Converts the string argument from its character representation to the -corresponding hexadecimal number,expressed as the ACSII characters 0-9 and A-F. -See Also:C2B() -Example: - say c2x('abc') ==>616263 - - 54 - -CENTER() or CENTRE() -Usage:CENTER(string,length,[pad])or CENTRE(string,length,[pad]) -Centers the string argument in a string with the specified length. If the -length is longer than that of the string,pad characters or blanks are added as -necessary. -Examples: - say center('abc',6) ==>' abc ' - say center('abc',6,'+') ==>'+abc++' - say center('123456',3) ==>'234' - -CLOSE() -Usage:CLOSE(file) -Closes the file specified by the given logical name. The returned value is a -boolean success flag,and will be 1 unless the specified file was not open. -Example: - say close('input') ==>1 - -COMPRESS() -Usage:COMPRESS(string,[list]) -If the list argument is omitted,the function removes leading,trailing,or -embedded blank characters from the string argument. If the optional list is -supplied,it specifies the characters to be removed from the string. -Examples: - say compress (' why not ') ==>whynot - say compress ('++12-34-+','+-') ==>1234 - -COMPARE() -Usage:COMPARE(string1,string2,[pad]) -Compares two strings and returns the index of the first position in which they -differ,or 0 if the strings are identical. The shorter string is padded as -required using the supplied character or blanks. -Examples: - say compare('abcde','abcce') ==>4 - say compare('abcde',abcde') ==>0 - say compare('abc++','abc+-','+') ==>5 - -COPIES() -Usage:COPIES(string,number) -Creates a new string by concatenating the specified number of copies of the -original. The number argument may be zero,in which case the null string is -returned. - - 55 - -Example: - say copies('abc',3) ==>abcabcabc - -D2C() -Usage:D2C(number) -Creates a string whose value is the binary(packed)representation of the given -decimal number. -Example: - d2c(31) ==>'1F'x - -DATATYPE() -Usage:DATATYPE9string,[option]) -If the option parameter is not specified,DATATYPE()tests whether the string -parameter is a valid number and returns either NUM or CHAR. If an option -keyword is given,the boolean return indicates whether the string satisfied the -requested test. The following option keywords are recognized: - - Table 6.1 DATATYPE()Options - - KEYWORD CHARACTERS ACCEPTED - Alphanumeric Alphabetics (A-Z,a-z) - or Numerics (0-9) - Binary Binary Digits String - Lowercase Lowercase Alphabetics (a-z) - Mixed Mixed Upper/Lowercase - Numeric Valid Numbers - Symbol Valid REXX Symbols - Upper Uppercase Alphabetics (A-Z) - Whole Integer Numbers - X Hex Digits String -Examples: - say datatype('123') ==>NUM - say datatype('1a f2','x') ==>1 - say datatype('aBcde','L') ==>0 - -DELSTR() -Usage:DELSTR(string,n,[length]) -Deletes the substring of the string argument beginning with the nth character -for the specified length in characters. The default length is the remaining -length of the string. -Example: - say delstr('123456',2,3) ==>156 - - 56 - -DELWORD() -Usage:DELWORD(string,n,[length]) -Deletes the substring of the string argument beginning with the nth word for -the specified length in words. The default length is the remaining length of -the string. The deleted string includes any trailing blanks following the last -word. -Examples: - say delword('Tell me a story',2,2)==>'Tell story' - say delword('one two three',3) ==>'one two ' - -EOF() -Usage:EOF(file) -Checks the specified logical file name and returns the boolean value 1(True)if -the end-of-file has been reached,and 0(False)otherwise. -Example: - say eof(infile) ==>1 - -ERRORTEXT() -Usage:ERRORTEXT(n) -Returns the error message associated with the specified ARexx code. The null -string is returned if the number is not a valid error code. -Example: - say errortext(41) ==>Invalid expression - -EXISTS() -Usage:EXISTS(filename) -Tests whether an external file of the given filename exists. The name string -may include device and directory specifications. -Example: - say exists('df0:c/ed') ==>1 - -EXPORT() -Usage:EXPORT(address,[string],[length],[pad]) -Copies data from the (optional) string into a previously-allocated memory area, -which must be specified as a 4-byte address. The length parameter specifies the -maximum number of characters to be copied; the default is the length of the -string. If the specified length is longer than the string,the remaining area is -filled with the pad character or nulls('00'x). The returned value is the number -of characters copied. - -Caution is advised in using this function. Any area of memory can be -overwritten,possibly causing a system crash. Task switching is forbidden while -the copy is being done,so system performance may be degraded if long strings -are copied. -See Also:IMPORT(),STORAGE() - - 57 - -Example: - count = export('0004 0000'x,'The answer') - -FREESPACE() -Usage:FREESPACE(address,length) -Returns a block of memory of the given length to the interpreter's internal -pool. The address argument must be a 4-byte string obtained by a prior call to -GETSPACE(),the internal allocator. It is not always necessary to release -internally-allocated memory,since it will be released to the system when the -program terminates. However,if a very large block has been allocated,returning -it to the pool may avoid memory space problems. The return value is a boolean -success flag. -See Also:GETSPACE() -Example: - say freespace('00042000'x,32) ==>1 - -GETCLIP() -Usage:GETCLIP(name) -Searches the Clip List for an entry matching the supplied name parameter,and -returns the associated value string. The name-matching is case-sensitive,and -the null string is returned if the name cannot be found. The usage and -maintenance of Clip List entries is described in the Chapter 9. -See Also:SETCLIP() -Example: - /* Assume 'numbers' contains 'PI=3.14159' */ - say getclip('numbers') ==>PI=3.14159 - -GETSPACE() -Usage:GETSPACE(length) -Allocates a block of memory of the specified length from the interpreter's -internal pool. The returned value is the 4-byte address of the allocated block, -which is not cleared or otherwise initialized. Internal memory is automatically -returned to the system when the ARexx program terminates,so this function -should not be used to allocate memory for use by external programs. The Support -Library(described in Appendix D)includes the function ALLOCMEM()which to -allocate memory from the system free list. -See Also:FREESPACE() -Example: - say c2x(getspace(32)) ==>'0003BF40'x - -HASH() -Usage:HASH(string) -Returns the hash attribute of a string as a decimal number,and updates the -internal hash value of the string. - - 58 - -Example: - say hash('1') ==>49 - -IMPORT() -Usage:IMPORT(address,[length]) -Creates a string by copying data from the specified 4-byte address. If the -length parameter is not supplied,the copy terminates when a null byte is found. -See Also:EXPORT() -Example: - extval = import('0004 0000'x,8) - -INDEX() -Usage:INDEX(string,pattern,[start]) -Searches for the first occurrence of the pattern argument in the string -argument,beginning at the specified start position. The default start position -is 1. The returned value is the index of the matched pattern,or 0 if the -pattern was not found. -Examples: - say index("123456","23") ==>2 - say index("123456","77") ==>0 - say index("123123","23",3) ==>5 - -INSERT() -Usage:INSERT(new,old,[start],[length],[pad]) -Inserts the new string into the old string after the specified start position. -The default starting position is 0. The new string is truncated or padded to -the specified length as required,using the supplied pad character or blanks. If -the start position is beyond the end of the old string,the old string is padded -on the right. -Examples: - say insert('ab,'12345') ==>ab12345 - say insert('123','++',3,5,'-') ==>++-123-- - -LASTPOS() -Usage:LASTPOS(pattern,string,[start]) -Searches backwards for the first occurrence of the pattern argument in the -string argument,beginning at the specified start position. The default starting -position is the end of the string. The returned value is the index of the -matched pattern,or 0 if the pattern was not found. - - 59 - -Examples: - say lastpos("123234","2") ==>4 - say lastpos("123234","5") ==>0 - say lastpos("123234","2",3) ==>2 - -LEFT() -Usage:LEFT(string,length,[pad]) -Returns the leftmost substring in the given string argument with the specified -length. If the substring is shorter than the requested length,it is padded on -the left with the supplied pad character or blanks. -Examples: - say left('123456',3) ==>123 - say left('123456',8,'+') ==>123456++ - -LENGTH() -Usage:LENGTH(string) -Returns the length of the string. -Example: - say length('three') ==>5 - -MAX() -Usage:MAX(number,number[,number,...]) -Returns the maximum of the supplied arguments,all of which must be numeric. At -least two parameters must be supplied. -Example: - say max(2.1,3,-1_ ==>3 - -MIN() -Usage:MIN(number,number[,number,...]) -Returns the minimum of the supplied arguments,all of which must be numeric. At -least two parameters must be supplied. -Example: - say min(2.1,3,-1) ==>-1 - -OPEN() -Usage:OPEN(file,filename,['Append' | 'Read' | 'Write']) -Opens an external file for the specified operation. The file argument defines -the logical name by which the file will be referenced. The filename is the -external name of the file,and may include device and directory specifications. -The function returns a boolean value that indicates whether the operation was -successful. There is no limit to the number of files that can be open - - 60 - -simultaneusly,and all open files are closed automatically when the program -exits. -See Also:CLOSE(),READ(),WRITE() -Examples: - say open('MyCon','CON:160/50/320/100/MyCon/cds') ==>1 - say open('outfile','ram:temp','W') ==>1 - -OVERLAY() -Usage:OVERLAY(new,old,[start],[length],[pad]) -Overlays the new string onto the old string beginning at the specified start -position,which must be positive. The default starting position is 1. The new -string is truncated or padded to the specified length as required,using the -supplied pad character or blanks. If the start position is beyond the end of -the old string,the old string is padded on the right. -Examples: - say overlay('bb,'abcd') ==>bbcd - say overlay('4','123',5,5,'-') ==>123--4---- - -POS() -Usage:POS(pattern,string,[start]) -Searches for the first occurrence of the pattern argument in the string -argument,beginning at the position specified by the start argument. The default -starting position is 1. The returned value is the index of the matched -string,or 0 if the pattern wasn't found. -Examples: - say pos('23','123234') ==>2 - say pos('77','123234') ==>0 - say pos('23','123234',3) ==>4 - -PRAGMA() -Usage:PRAGMA(option,[value]) -This function allows a program to change various attributes relating to the -system environment within which the program executes. The option argument is a -keyword that specifies an environmental attribute;the currently implemented -options are Directory and Priority. The value argument supplies the new -attribute value to be installed. The value returned by the function depends on -the attribute selected. Some attributes return the previous value -installed,while others may simply set a boolean success flag. The currently -defined option keywords are listed below. - -DIRECTORY. Specifies a new "current" directory. The current directory is used -as the "root" for filenames that do not explicitly include a device -specification. The return value is a boolean success flag. - -PRIORITY. Specifies a new task priority. The priority value must be an integer -in the range -128 to 127,but the practical range is much more limited. ARexx -programs should never be run at a priority higher than that of the resident -process,which currently runs at priority 4. The returned value is the previous -priority level. - - 61 - -Examples: - say pragma('priority',-5) ==>0 - call pragma 'Directory','df0:system' - -RANDOM() -Usage:RANDOM([min],[max],[seed]) -Returns a pseudorandom integer in the interval specified by the min and max -arguments. The default minimum value is 0 and the default maximum value is 999. -The interval max-min must be less than or equal to 1000. If a greater range of -random integers is required,the values from the RANDU()function can be suitable -scaled and translated. - -The seed argument can be supplied to initialize the internal state of the -random number generator. -See Also:RANDU() -Example: - thisroll = random(1,6) /* might be 1 */ - nextroll = random(1,6) /* snake eyes? */ - -RANDU() -Usage:RANDU([seed]) -Returns a uniformly-distributed pseudorandom number between 0 and 1. The number -of digits of precision in the result is always equal to the current Numeric -Digits setting. With the choice of suitable scaling and translation values, -RANDU()can be used to generate pseudorandom numbers on an arbitrary interval. - -The optional seed argument is used to initialize the internal state of the -random number generator. -See Also:RANDOM() -Example: - firsttry = randu() /* 0.371902021? */ - numeric digits 3 - tryagain = randu() /* 0.873? */ - -READCH() -Usage:READCH(file,length) -Reads the specified number of characters from the given logical file into a -string. The length of the returned string is the actual number of characters -read,and may be less than the requested length if,for example,the end-of-file -was reached. -See Also:READLN() -Example: - instring = readch('input',10) - - 62 - -READLN() -Usage:READLN(file) -Reads characters from the given logical file into a string until a "newline" -character is found. The returned string does not include the "newline". -See Also:READCH() -Examples: - instring = readln('MyFile') - -REMLIB() -Usage:REMLIB(name) -Removes an entry with the given name from the Library List maintained by the -resident process. The boolean return is 1 if the entry was found and -successfully removed. Note that this function does not make a distinction -between function libraries and function hosts,but simply removes a named entry. -See Also:ADDLIB() -Example: - say remlib('MyLibrary.library')==>1 - -REVERSE() -Usage:REVERSE(string) -Reverses the sequence of characters in the string. -Example: - say reverse('?ton yhw') ==>why not? - -RIGHT() -Usage:RIGHT(string,length,[pad]) -Returns the rightmost substring in the given string argument with the specified -length. If the substring is shorter than the requested length,it is padded on -the left with the supplied pad character or blanks. -Examples: - say right('123456',4) ==>3456 - say right('123456',8,'+') ==>++123456 - -SEEK() -Usage:SEEK(file,offset,['Begin' | 'Current' | 'End']) -Moves to a new position in the given logical file,specified as an offset from -an anchor position. The default anchor is Current. The returned value is the -new position relative to the start of the file. -Examples: - say seek('input',10,'B') ==>10 - say seek('input',O,'E') ==>356 /* file length */ - - 63 - -SETCLIP() -Usage:SETCLIP(name,[value]) -Adds a name-value pair to the Clip List maintained by the resident process. If -an entry of the same name already exists,its value is updated to the supplied -value string. Entries may be removed by specifying a null value. The function -returns a boolean value that indicates whether the operation was successful. -Examples: - say setclip('path','df0:s') ==>1 - say setclip('path') ==>1 - -SHOW() -Usage:SHOW(option,[name],[pad]) -Returns the names in the resource list specified by the option argument,or -tests to see whether an entry with the specified name is available. The -currently implemented options keywords are Clip,Files,Libraries,and Ports, -which are described below. - -Clip. Examines the names in the Clip List. -Files. Examines the names of the currently open logical file names. -Libraries. Examines the names in the Library List,which are either function -libraries or function hosts. -Ports. Examine the names in the system Ports List. - -If the name argument is omitted,the function returns a string with the resource -names separated by a blank space or the pad character,if one was supplied. If -the name argument is given,the returned boolean value indicates whether the -name was found in the resource list. The name entries are case-sensitive. - -SIGN() -Usage:SIGN(number) -Returns 1 if the number argument is positive or zero,and -1 if number is -negative. The argument must be numeric. -Examples: - say sign(12) ==>1 - say sign(-33) ==>-1 - -SPACE() -Usage:SPACE(string,n,[pad]) -Reformats the string argument so that there are n spaces(blank characters) -between each pair of words. If the pad character is specified,it is used -instead of blanks as the separator character. Specifying n as 0 will remove all -blanks from the string. -Examples: - say space('Now is the time',3) ==>'Now is the time' - say space('Now is the time',0) ==>'Nowisthetime' - say space('1 2 3',1,'+') ==>'1+2+3' - - 64 - -STORAGE() -Usage:STORAGE([address],[string],[length],[pad]) -Calling STORAGE()with no arguments returns the available system memory. If the -address argument is given,it must be a 4-byte string,and the function copies -data from the(optional)string into the indicated memory area. The length -parameter specifies the maximum number of bytes to be copied,and defaults to -the length of the string. If the specified length is longer than the string,the -remaining area is filled with the pad character or nulls('00'x.) - -The returned value is the previous contents of the memory area. This can be -used in a subsequent call to restore the original contents. - -Caution is advised in using this function. Any area of memory can be -overwritten,possibly causing a system crash. Task switching is forbidden while -the copy is being done,so system performance may be degraded if long strings -are copied. -See Also:EXPORT() -Examples: - say storage() ==>248400 - oldval = storage('0004 000'x,'The answer') - call storage '0004 0000'x,,32,'+' - -STRIP() -Usage:STRIP(string,[{'B' | 'L' | 'T'}],[pad]) -If neither of the optional parameters is supplied,the function removes both -leading and trailing blanks from the string argument. The second argument -specifies whether Leading,Trailing,or Both(leading and trailing)characters are -to be removed. The optional pad(or unpad,perhaps)argument selects the character -to be removed. -Examples: - say strip(' say what? ') ==>'say what?' - say strip(' say what? ','L') ==>'say what? ' - say strip('++123+++','B','+') ==>'123' - -SUBSTR() -Usage:SUBSTR(string,start,[length],[pad]) -Returns the substring of the string argument beginning at the specified start -position for the specified length. The starting position must be positive,and -the default length is the remaining length of the string. If the substring is -shorter than the requested length,it is padded on the left with the blanks or -the specified pad character. -Examples: - say substr('23456',4,2) ==>45 - say substr('myname',3,6,'=') ==>name== - - 65 - -SUBWORD() -Usage:SUBWORD(string,n,[length]) -Returns the substring of the string argument beginning with the nth word for -the specified length in words. The default length is the remaining length of -the string. The returned string will never have leading or trailing blanks. -Example: - say subword('Now is the time ',2,2) ==>is the - -SYMBOL() -Usage:SYMBOL(name) -Tests whether the name argument is a valid REXX symbol. If the name is not a -valid symbol,the function returns the string BAD. Otherwise,the returned string -is LIT if the symbol is uninitialized and VAR if it has been assigned a value. -Examples: - say symbol('J') ==>VAR - say symbol('x') ==>LIT - say symbol('++') -->BAD - -TIME() -Usage:TIME(option) -Returns the current system time or controls the internal elapsed time counter. -The valid option keywords are listed below. - - Table 6.2 TIME()Options - - OPTION KEYWORD DESCRIPTION - Elapsed Elapsed time in seconds. - Hours Current time in hours since midnight - Minutes Current time in minutes since midnight - Reset Reset the elapsed time clock - Seconds Current time in seconds since midnight - -If no option is specified,the function returns the current system time in the -form HH:MM:SS. -Examples: - /* Suppose that the time is 1:02 AM ... */ - say time('Hours') ==>1 - say time('m') ==>62 - say time('S') ==>3720 - call time 'R' /* reset timer */ - say time('E') ==>.020 - - 66 - -TRACE() -Usage:TRACE(option) -Sets the tracing mode to that specified by the option keyword,which must be one -of the valid alphabetic or prefix options. The tracing options are described in -Chapter 7. The TRACE()function will alter the tracing mode even during -interactive tracing,when TRACE instructions in the source program are ignored. -The returned value is the mode in effect before the function call;this allows -the previous trace mode to be restored later. -Example: - /* Assume tracing mode is ?AL */ - say trace('Results') ==>?A - -TRANSLATE() -Usage:TRANSLATE(string,[output],[input],[pad]) -This function constructs a translation table and uses it to replace selected -characters in the argument string. If only the string argument is given,it is -translated to uppercase. If an input table is supplied,it modifies the -translation table so that characters in the argument string that occur in the -input table are replaced with the corresponding character in the output table. -Characters beyond the end of the output table are replaced with the specified -pad character or a blank. - -Note that the result string is always of the same length as the original -string. The input and output tables may be of any length. -Examples: - say translate("abcde","123","cbade","+") ==>321++ - say translate("low") ==>LOW - say translate("0110","10","01") ==>1001 - -TRIM() -Usage:TRIM(string) -Removes trailing blanks from the string argument. -Example: - say length(trim(' abc ')) ==>4 - -UPPER() -Usage:UPPER(string) -Translates the strip to uppercase. The action of this function is equivalent to -that of TRANSLATE(string),but it is slightly faster for short strings. -Example: - say upper('One Fine Day') ==>ONE FINE DAY - - 67 - -VALUE() -Usage:VALUE(name) -Returns the value of the symbol represented by the name argument. -Example: - /* Assume that J has the value of 12 */ - say value('j') ==>12 - -VERIFY() -Usage:VERIFY(string,list,['Match']) -If the Match argument is omitted,the function returns the index of the first -character in the string argument which is not contained in the list argument,or -0 if all of the characters are in the list. If the Match keyword is supplied, -the function returns the index of the first character which is in the list,or 0 -if none of the characters are. -Examples: - say verify('123456','0123456789') ==>0 - say verify('123a56','0123456789') ==>4 - say verify('123a45','abcdefghij','m') ==>4 - -WORD() -Usage:WORD(string,n) -Returns the nth word in the string argument,or the null string if there are -fewer than n words. -Example: - say word('Now is the time ',2) ==>is - -WORDINDEX() -Usage:WORINDEX(string,n) -Returns the starting position of the nth word in the argument string,or 0 if -there are fewer than n words. -Example: - say wordindex('Now is the time ',3) ==>8 - -WORDLENGTH() -Usage:WORDLENGTH(string,n) -Returns the length of the nth word in the string argument. -Example: - say wordlength('one two three',3) ==>5 - - 68 - -WORDS() -Usage:WORDS(string) -Returns the number of words in the string argument. -Example: - say words("You don't say!") ==>3 - -WRITECH() -Usage:WRITECH(file,string) -Writes the string argument to the given logical file. The returned value is the -actual number of characters written. -Example: - say writech('output','Testing') ==>7 - -WRITELN() -Usage:WRITELN(file,string) -Writes the string argument to the given logical file with a "newline" appended. -The returned value is the actual number of characters written. -Example: - say writeln('output','Testing') ==>8 - -X2C() -Usage:X2C(string) -Converts a string of hex digits into the(packed)character representation. Blank -characters are permitted in the argument string at byte boundaries. -Examples: - say x2c('12ab') ==>'12ab'x - say x2c('12 ab') ==>'12ab'x - -XRANGE() -Usage:XRANGE([start],[end]) -Generates a string consisting of all characters numerically between the -specified start and end values. The default start character is '00'x,and the -default end character is 'FF'x. Only the first character of the start and end -arguments is significant. -Examples: - say xrange() ==>'00010203 ... FDFEFF'x - say xrange('a','f') ==>'abcdef' - say xrange(,'10'x) ==>'00010203040506070809010'x - - 69 - - CHAPTER 7 TRACING AND INTERRUPTS - -ARexx provides tracing and source-level debugging facilities that are unusual -in a high-level language. Tracing refers to the ability to display selected -statements in a program as the program executes. When a clause is traced,its -line number,source text,and related information are displayed on the console. -The tracing action of the interpreter is determined by a trace option that -selects which source clauses will be traced,and two modifier flags that control -command inhibition and interactive tracing. - -The internal interrupt system enables an ARexx program to detect certain -synchronous or asynchronous events and to take special actions when they occur. -Events such as a syntax error or an external halt request that would normally -cause the program to exit can instead be trapped so that corrective actions can -be taken. - -7-1 TRACING OPTIONS - -Trace options are sometimes called an alphabetic options,since the keywords -that select an option can be shortened to one letter for convenience. The -alphabetic options are: - -ALL. All clauses are traced. -COMMANDS. All command clauses are traced before being sent to the external -host. Non-zero return codes are displayed on the console. -ERRORS. Commands that generate a non-zero return code are traced after the -clause is executed. -INTERMEDIATES. All clauses are traced,and intermediate results are displayed -during expression evaluation. These include the values retrieved for variables, -expanded compound names,and the results of function calls. -LABELS. All label clauses are traced as they are executed. A label will be -displayed each time a transfer of control takes place. -NORMAL. Command clauses will return codes that exceed the current error failure -level are traced after execution,and an error message is displayed. This is the -default trace option. -RESULTS. All clauses are traced before execution,and the final result of each -expression is displayed. Values assigned to variables by ARG,PARSE,or PULL -instructions are also displayed. -SCAN. This is a special option that traces all clauses and checks for errors, -but suppresses the actual execution of the statements. It is helpful as a -preliminary screening steop for a newly-created program. - -The tracing mode can be set using either the TRACE instruction or the TRACE() -Built-In function. The RESULTS trace option is recommended for general-purpose -testing. Tracing can be selectively disabled from within a program so that -previously-tested parts of a program can be skipped. - - 71 - -7-2 DISPLAY FORMATTING - -Each trace line displayed on the console is indented to show the effective -control(nesting)level at that clause,and is identified by a special three- -character code,as shown in Table 7.1 below. The source for each clause is -preceded by its line number in the program. Expression results or intermediates -are enclosed in double quotes so that leading and trailing blanks will be -apparent. - - TABLE 7.1 TRACING PREFIX CODES - - CODE DISPLAYED VALUES - +++ Command or syntax error - >C> Expanded compound name - >F> Result of a function call - >L> Label clause - >O> Result of a dyadic operation - >P> Result of a prefix operation - >U> Uninitialized variable - >V> Value of a variable - >>> Expression or template result - >.> "Placeholder" token value - -TRACING OUTPUT - -The tracing output from a program is always directed to one of two logical -streams. The interpreter first checks for a stream named STDERR,and directs the -output there if the steam exists. Otherwise the trace output goes to the -standard output stream STDOUT and will be interleaved with the normal console -output of the program. The STDERR and STDOUT streams can be opened and closed -under program control,so the programmer has complete control over the -destination of tracing output. - -In some cases a program may not have a predefined output stream. For example,a -program invoked from a host application that did not provide input and output -streams would not have an output console. To provide a tracing facility for -such programs,the resident process can open a special global tracing console -for use by any active program. When this console opens,the interpreter -automatically opens a stream named STDERR for each ARexx program in which -STDERR is not currently defined,and the program then diverts its tracing output -to the new stream. - -The global console can be opened and closed using the command utilities too and -tcc,respectively. The console may not close immediately upon request,however. -The resident process waits until all active programs have diverted their -tracing streams back to the default state before actually closing the console. -Applications programs may provide direct control over the tracing console by -sending request packets to the resident process,which is discussed in Chapter -10. - -The trace stream(STDERR or STDOUT)is also used for trace input,so a program in -interactive tracing mode will wait for user input from this console. The global -tracing console is always shared among all currently active programs. Since it -may be confusing to have several programs simultaneously writing to the same -console,it is recommended that only one program at a time be traced using the -global console. - - 72 - -COMMAND INHIBITION - -ARexx provides a tracing mode called command inhibition that suppresses host -commands. In this mode command clauses are evaluated in the normal manner,but -the command is not actually sent to the external host,and the return code is -set to zero. This provides a way to test programs that issue potentially -destructive commands,such as erasing files or formatting disks. Command -inhibition does not apply to command clauses that are entered interactively. -These commands are always performed,but the value of the special variable RC is -left unchanged. - -Command inhibition may be used in conjunction with any trace option. It is -controlled by the "!" character,which may appear by itself or may precede any -of the alphabetic options in a TRACE instruction. Each occurrence of the "!" -character "toggles" the inhibition mode currently in effect. Command inhibition -is cleared when tracing is set to OFF. - -7-3 INTERACTIVE TRACING - -Interactive tracing is a debugging facility that allows the user to enter -source statements while a program is executing. These statements may be used to -examine or modify variable values,issue commands,or otherwise interact with the -program. Any valid language statements can be entered interactively,with the -same rules and restrictions that apply to the INTERPRET instruction. In -particular,compound statements such as DO and SELECT must be complete within -the entered line. - -Interactive tracing can be used with any of the trace options. While in -interactive tracing mode,the interpreter pauses after each traced clause and -prompts for input with the code "+++." At each pause,three types of user -responses are possible. - - If a null line is entered,the program continues to the next pause - point. - If an "=" character is entered,the preceding clause is executed again. - Any other input is treated as a debugging statement,and is scanned and - executed. - -The pause points during interactive tracing are determined by the tracing -option currently in effect,as the interpreter pauses only after a traced -clause. However,certain instructions cannot be safely(or sensibly)re-executed, -so the interpreter will not pause after executing one of these. The "no-pause" -instructions are CALL,DO,ELSE,IF,THEN,and OTHERWISE. The interpreter will also -not pause after any clause that generate and execution error. - -Interactive tracing mode is controlled by the "?" character,either by itself or -in combination with an alphabetic trace option. Any number of "?" characters -may precede an option,and each occurrence toggles the mode currently in effect. -For example,if the current trace option was NORMAL,then "TRACE ?R" would set -the option to RESULTS and select interactive tracing mode. A subsequent "TRACE -?" would turn off interactive tracing. - - 73 - -ERROR PROCESSING - -The ARexx interpreter provides special error processing while it executes -debugging statements. Errors that occur during interactive debugging are -reported,but do not cause the program to terminate. This special processing -applies only to the statements that were entered interactively. Errors occuring -in the program source statements are treated in the usual way whether or not -the interpreter is in interactive tracing mode. - -In addition to the special error processing,the interpreter also disables the -internal interrupt flags during interactive debugging. This is necessary to -prevent an accidental transfer of control due to an error or uninitialized -variable. However,if a "SIGNAL label" instruction is entered,the transfer will -take place,and any remaining interactive input will be abandoned. The SIGNAL -instruction can still be used to alter the interrupt flags,and the new settings -will take effect when the interpreter returns to normal processing. - -THE EXTERNAL TRACING FLAG - -The ARexx resident process maintains an external tracing flag that can be used -to force programs into interactive tracing mode. The tracing flag can be set -using the ts command utility. When the flag is set,any program not already in -interactive tracing mode will enter it immediately. The internal trace option -is set to RESULTS unless it is currently set to INTERMEDIATES or SCAN,in which -case it remains unchanged. Programs invoked while the external tracing flag is -set will begin executing in interactive tracing mode. - -The external tracing flag provides a way to regain control over programs that -are caught in loops or are otherwise unresponsive. Once a program enters -interactive tracing mode,the user can step through the program statements and -diagnose the problem. There is one caveat,though:external tracing is global -flag,so all currently-active programs are affected by it. The tracing flag -remains set until it is cleared using the "te" command utility. Each program -maintains an internal copy of the last state of the tracing flag,and sets its -tracing option to OFF when it observes that the tracing flag has been cleared. - -7-4 INTERRUPTS - -ARexx maintains an internal interrupt system that can be used to detect and -trap certain error conditions. When an interrupt is enabled and its -corresponding condition arises,a transfer of control to the label specific to -that interrupt occurs. This allows a program to retain control in circumstances -that might otherwise cause the program to terminate. The interrupt conditions -can caused by either synchronous events like a syntax error,or asynchronous -events like a "control-C" break request. Note that these internal interrupts -are completely separate from the hardware interrupt system managed by the EXEC -operating system. - -The interrupts supported by ARexx are described below. The name assigned to -each is actually the label to which control will be tranferred. Thus,a SYNTAX -interrupt will transfer control to the label "SYNTAX:." Interrupts can be -enabled or disabled using the SIGNAL instruction. For example,the instruction -"SIGNAL ON SYNTAX" would enable the SYNTAX interrupt. - - 74 - -BREAK_C. This interrupt will trap a control-C break request generated by DOS. -If the interrupt is not enabled,the program terminates immediately with the -error message "Execution halted" and returns with the error code set to 2. - -BREAK_D. The interrupt will detect and trap a control-D break request issued by -DOS. The break request is ignored if the interrupt is not enabled. - -BREAK_E. The interrupt will detect and trap a control-E break request issued by -DOS. The break request is ignored if the interrupt is not enabled. - -BREAK_F. The interrupt will detect and trap a control-F break request issued by -DOS. The break request is ignored if the interrupt is not enabled. - -ERROR. This interrupt is generated by any host command that returns a non-zero -code. - -HALT. An external halt request will be trapped if this interrupt is enabled. -Otherwise,the program terminates immediately with the error message "Execution -halted" and returns with the error code set to 2. - -IOERR. Errors detected by the I/O system will be trapped if this interrupt is -enabled. - -NOVALUE. An interrupt will occur if an uninitialized variable is used while -this condition is enabled. The usage could be within an expression,in the UPPER -instruction,or with the VALUE()built-in function. - -SYNTAX. A syntax or execution error will generate this interrupt. Not all -errors such errors can be trapped,however. In particular,certain errors -occurring before a program is actually executing,and those detected by the -ARexx external interface,cannot be trapped by the SYNTAX interrupt. - -When an interrupt forces a transfer of control,all of the currently active -control ranges are dismantled,and the interrupt that caused the transfer is -disabled. This latter action is necessary to prevent a possible recursive -interrupt loop. Only the control structures in the current environment are -affected,so an interrupt generated within a function will not affect the -caller's environment. - -SPECIAL VARIABLES. Two special variables are affected when an interrupt occurs. -The variable SIGL is always set to the current line number before the transfer -of control takes place,so that the program can determine which source line was -being executed. When an ERROR or SYNTAX interrupt occurs,the variable RC is set -to the error code that caused the condition. For ERROR interrupts this value -will be a command return code,and can usually be interpreted as an error -severity level. The value for SYNTAX interrupts is always an ARexx error code. - -Interrupts are useful primarily to allow a program to take special -error-recovery actions. Such actions might involve informing external programs -that an error ocurred,or simply reporting further diagnostics to help in -isolating the problem. In the following example,the program issues a "message" -command to an external host called "MyEdit" whenever a syntax error is -detected: - - 75 - - /* A macro program for 'MyEdit' */ - signal on syntax /* enable interrupt */ - . - . (normal processing) - . - exit - syntax: /* syntax error detected*/ - address 'MyEdit' - 'message' 'error' rc errortext(rc) - exit 10 - - 76 - - CHAPTER 8 PARSING AND TEMPLATES - -Parsing is a operation that extracts substrings from a string and assigns them -to variables. It corresponds roughly to the notion of a "formatted read" used -in other languages,but has been generalized in the several ways. Parsing is -performed using the PARSE instruction or its variants ARG and PULL. The input -for the operation is called the parse string and can come from several sources; -these source options are described with the PARSE instruction in Chapter 4. - -Parsing is controlled by a template,a group of tokens that specifies both the -variables to be given values and the way to determine the value strings. -Templates were described briefly with the PARSE instruction;the present chapter -presents a more formal description of their structure and operation. - -8-1 TEMPLATE STRUCTURE - -The tokens that are valid in a template are symbols,strings,operators, -parentheses,and commas. Any blanks that may be present as separators are -removed before the template is processed. The tokens in a template ultimately -serve to specify one of the two basic template objects: - -Markers determine a scan position within the parse string,and -Targets are symbols to be assigned a value. - -With these objects in mind,the parsing process can be described as one of -associating with each target a starting and ending position in the parse -string. The substring between these positions then becomes the value for the -target. - -MARKETS. There are three types of marker objects: - -ABSOLUTE markers specify an actual index position in the parse string, -RELATIVE markers specify a positive or negative offset from the current -position,and -PATTERN markers specify a position implicitly,by matching the pattern against -the parse string beginning at the current scan position. - -TARGETS. Targets,like markers,can affect the scan position if value strings are -being extracted by tokenization. Parsing by tokenization extracts words(tokens) -from the parse string, and is used whenever a target is followed immediately - - 77 - -by another target. During tokenization the current scan position is advanced -past any blanks to the start of the next word. The ending index is the position -just past the end of the word,so that the value string has neither leading nor -trailing blanks. - -TEMPLATE OBJECTS - -Each template object is specified by one or more tokens,which have the -following interpretations. - -SYMBOLS. A symbol token may specify either a target or a marker object. If it -follows an operator token(+,-,or=),it represents a marker,and the symbol value -is used as an absolute or relative position. Symbols enclosed in parentheses -specify pattern markers,and the symbol value is used as the pattern string. - -If neither of the preceding cases applies and the symbol is a variable,then it -specifies a target. Fixed symbols always specify absolute markers and must be -whole numbers,except for the period(.)symbol which defines a placeholder -target. - -STRINGS. A string token always represents a pattern marker. - -PARENTHESES. A symbol enclosed in parentheses is a pattern marker,and the value -of the symbol is used as the pattern string. While the symbol may be either -fixed or variable,it will usually be a variable,since a fixed pattern could be -given more simply as a string. - -OPERATORS. The three operators "+,"-,"and "=" are valid within a template,and -must be followed by a fixed or variable symbol. The value of the symbol is used -as a marker and must therefore represent a whole number. The "+" and "-" -operators signify a relative marker,whose value is negated by the "-" operator. -The "=" operator indicates an absolute marker,and is optional if the marker is -defined by a fixed symbol. - -COMMAS. The comma(,)marks the end of a template,and is used as a separator when -multiple templates are provided with an instruction. The interpreter obtains a -new parse string before processing each succeeding template. For some source -options,the new string will be identical to the previous one. The ARG,EXTERNAL, -and PULL options will generally supply a different string,as will the VAR -option if the variable has been modified. - -THE SCANNING PROCESS - -Scan positions are expressed as an index in the parse string,and can range from -1(the start of the string)to the length of the string plus 1(the end). An -attempt to set the scan position before the start or after the end of the -string instead sets it to the beginning or end,respectively. - -The substring specified by two scan indices includes the characters from the -starting position up to,but not including,the ending position. For example,the -indices 1 and 10 specify characters 1-9 in the parse string. One additional -rule is applied if the second scan index is less than or equal to the first: in -this case the remainder of the parse string is used as the substring. This -means that a template specificaiton like - 78 - - parse arg 1 all 1 first second - -will assign the entire parse string to the variable ALL. Of course,if the -current scan index is already at the end of the parse string,then the remainder -is just the null string. - -When a pattern marker is matched against the parse string,the marker position -is the index of the first character of the matched pattern,or the end of the -string if no match was found. The pattern is removed from the string whenever a -match is found. This is the only operation that modifies the parse string -during the parsing process. - -Templates are scanned from left to right with the initial scan index set to 1, -the start of the parse string. The scan position is updated each time a marker -object is encountered,according to the type and value of the marker. Whenever a -target object is found,the value to be assigned is determined by examining the -next template object. If the next object is another target,the value string is -determined by tokenizing the parse string. Otherwise,the current scan position -is used as the start of the value string,and the position specified by the -following marker is used as the end point. - -The scan continous until all of the objects in the template have been used. -Note that every target will be assigned a value;once the parse string has been -exhausted,the null string is assigned to any remaining targets. - -8-2 TEMPLATES IN ACTION - -The preceding section is rather abstract,so let's look now at some examples of -parsing with templates. - -PARSING BY TOKENIZATION - -Computer programs frequently require splitting a string into its component -words or tokens. This is easily accomplished with a template consisting -entirely of variables(targets). - - /* Assume "hammer 1 each $600.00" was entered */ - pull item qty untils cost . - -In this example the input line from the PULL instruction is split into words -and assigned to the variables in the template. The variable item receives the -value "hammer," qty is set to "1," units is set to "each," and cost gets the -value "$600.00." The final placeholder(.) is given a null value,since there are -only four words in the input. However,it forces the preceding variable cost to -be given a tokenized value. If the placeholder were omitted,the remainder of -the parse string would be assigned to cost,which would then have a leading -blank. - -In the next example,the first word of a string is removed and the remainder is -placed back in the string. The process continues until no more words are -extracted. - - 79 - - /* Assume "result" contains a string of words */ - do forever - /* Get first word of string */ - parse var result first result - if first == '' then leave - /* ... process words ... */ - end - -PATTERN PARSING - -The next example uses pattern markers to extract the desired fields. The -"pattern" in this case is very simple -- just a single character -- but in -general can be an arbitrary string of any length. This form of parsing is -useful whenever delimiter characters are present in the parse string. - - /* Assume an argument string "12,34.5,1 */ - arg hours ',' rate ',' withhold - -Keep in mind that the pattern is actually removed from the parse string when a -match is found. If the parse string is scanned again from the beginning,the -length and structure of the string may be different than at the start of the -parsing process. However,the original source of the string is never modified. - -POSITIONAL MARKERS - -Parsing with positional markers is used whenever the fields of interest are -known to be in certain positions in a string. In the next example,the records -being processed contain a variable length field. The starting position and -length of the field are given in the first part of the record,and a variable -positional marker is used to extact the desired field. - - /* records look like: */ - /* start: 1-5 */ - /* length: 6-10 */ - /* name: @(start,length) */ - parse value record with 1 start +5 length +5 =start name +length - -The "=start" sequence in the above example is an absolute marker whose value is -the position paced in the variable start earlier in the scan. The "+length" -sequence supplies the effective length of the field. - -MULTIPLE TEMPLATES - -It is sometimes useful to specify more than one template with an instruction, -which can be done by separating the templates with a comma. In this next -example,the ARG instruction(or PARSE UPPER ARG)is used to access the argument -strings provided when the program was called. Each template accesses the -succeeding argument string. - - 80 - - /* Assume arguments were ('one two',12,sort) */ - arg first second,amount,action,option - -The first template consists of the variables first and second,which are set to -the values "one" and "two,"respectively. In the next two templates amount gets -the value "12" and action is set to "SORT". The last template consists of the -variable "option,"which is set to the null string,since only three arguments -were available. - -When multiple templates are used with the EXTERNAL or PULL source options,each -additional template requests an additional line of input from the user. In the -next example two lines of input are read: - - /* read last,first,and middle names and ssn */ - pull last ',' first middle,ssn - -The first input line is expected to have three words,the first of which is -followed by a comma,which are assigned to the variables last,first,and middle. -The entire second input line is assigned to the variable ssn. - -Multiple templates can be useful even with a source option that returns the -identical parse string. If the first template included pattern markers that -altered the parse string,the subsequent templates could still access the -original string. Note that subsequent parse strings obtained from the VALUE -source do not cause the expression to be reevaluated,but only retrieve the -prior result. - - 81 - - CHAPTER 9 THE RESIDENT PROCESS - -This chapter describes some of the capabilities of the ARexx resident process, -a global communications and resources manager. The material presented here is -directed to the general user;Chapter 10 covers these topics in greater depth -for software developers who wish to integrate ARexx with other applications -programs. - -The resident process must be active before any ARexx programs can be run. It -announces its presence to the system by opening a public message port named -"REXX,"so applications programs that use ARexx should check for the presence of -this port. If the port is not open,the user can either be informed that the -macro processor is not available,or else the applications program can start up -the resident process. The latter option can be done using the rexxmast command. - -The primary function of the resident process is to launch ARexx programs. When -an applications program sends a "command" or "function" message to the "REXX" -port,the resident process creates a new DOS process to execute the program, and -forwards the invocation message to newly created process. It also creates a new -instance of the ARexx global data structure,which links together all of the -structures manipulated by the program. - -In addition to launching programs,the resident process managers various -resources used by ARexx. These resources include a list of available function -libraries called the Library List,a list of(name,value)pairs called the Clip -List,and a list of the currently active ARexx programs. Built-In functions are -available to manipulate the Library List and Clip List from within an ARexx -program. Applications programs can modify a resource list either by sending a -request packet to the resident process or by direct manipulation of the list. - -9-1 COMMAND UTILITIES - -ARexx is supplied with a number of command utilities to provide various control -functions. These are executable modules that can be run from the CLI,and should -reside in the system command(C:)directory for convenience. These commands are -relevant only when the ARexx resident process is active. - -The functions performed by these utilities may also be available from within an -applications program. All of the utilities are implemented by sending message -packets to the resident process,so an application designed to work closely with -ARexx could easily provide these functions as part of its control menu. - -HI -Usage:HI -Sets the global halt flag,which causes all active programs to receive an -external halt request. Each program will exit immediately unless its HALT -interrupt has been enabled. The halt flag does not remain set,but is cleared -automatically after all current programs have received the request. - - 83 - -RX -Usage:RX name[arguments] -This command launches an ARexx program. If the specified name includes an -explicit path,only that directory is searched for the program;otherwise,the -current directory and the system REXX: device are checked for a program with -the given name. The optional argument string is passed to the program. - -RXSET -Usage:RXSET name value -Adds a(name,value)pair to the Clip List. Name strings are assumed to be in -mixed case. If a pair with the same name already exists,its value is replaced -with the current string. If a name without a value string is given,the entry is -removed from the Clip List. - -RXC -Usage:RXC -Closes the resident process. The "REXX" public port is withdrawn immediately, -and the resident process exits as soon as the last ARexx program finishes. No -new programs can be launched after a "close" request. - -TCC -Usage:TCC -Closes the global tracing console as soon as all active programs are no longer -using it. All read read requests queued to the console must be satisfied before -it can be closed. - -TCO -Usage:TCO -Open the global tracing console. The tracing output from all active programs is -diverted automatically to the new console. The console window can be moved and -resized by the user,and can be closed with the "TCC" command. - -TE -Usage:TE -Clears the global tracing flag,which forces the tracing mode to OFF for all -active ARexx programs. - -TS -Usage:TS -Starts interactive tracing by setting the external trace flag,which forces all -active ARexx programs into interactive tracing mode. Programs will start -producing trace output and will pause after the next statement. This command is -useful for regaining control over programs caught in infinite loops or -otherwise misbehaving. The trace flag remains set until cleared by the TE -command,so subsequent program invocations will begin executing in interactive -tracing mode. - - 84 - -9-2 RESOURCE MANAGEMENT - -Individual ARexx programs manage their internal memory allocation and I/O file -resources,but some resources need to be available to all programs. The -management of these global resources is one of the major functions of the -resident process. Global resources are maintained as doubly-linked lists,in -keeping with the general design principles of the EXEC operating system. Linked -lists provide a flexible and open mechanism for resource management,and help -avoid the built-in limits common with other approaches. - -THE GLOBAL TRACING CONSOLE - -The tracing output from an ARexx program usually goes to the standard output -stream STDOUT,and is therefore interleaved with the normal output of the -program. Since this may be confusing at times,a global trace console can be -opened to display only tracing output. The console can be opened using the tco -command utility or be sending an RXTCOPN request packet to the resident -process. ARexx programs will automatically divert their tracing output to the -new window,which is opened as a standard AmigaDOS console. The user can move it -and resize it as required. - -The tracing console also serves as the input stream for programs during -interactive tracing. When a program pauses for tracing input,the input line -must be entered at the trace console. Any number of programs may use the -tracing console simultaneously,although it is generally recommended that only -one program at a time be traced. - -The tracing console can be closed using the tcc command or by sending an -RXTCCLS request packet to the resident process. The closing is delayed until -all read requests to the console have been satisfied. Only when all of the -active programs indicate that they are no longer using the console will it -actually be closed. - -THE LIBRARY LIST - -The resident process maintains a Library List of the function libraries and -function hosts currently available to ARexx programs. This list is used to -resolve all references to external functions. Each entry has an associated -search priority in the range 100 to -100,with the higher-valued entries being -searched first until the requested function is found. The list is searched by -calling each entry,using the appropriate protocol,until the return code -indicates that the function was found. - -The two types of entities maintained by the list are quite different in some -respects,but the ultimate way in which a function call is resolved is -transparent to the calling program. A function library is a collection of -functions organized as an Amiga shared library,while a function host is a -separate task that manages a message port. Function libraries are called as -part of the ARexx interpreter's task context,but calls to function hosts are -mediated by passing a message packet. The ARexx resident process is itself a -function host,and is installed in the Library List at a priority of -60. - -The resident process provides addition and deletion operations for maintaining -the Library List;these operations are performed by sending an appropriate -message packet. The Library List is always maintained in priority order. Within -a given priority level any new entries are added to the end of the chain, so -that entries added first will be searched fist. The priority levels are - - 85 - -significant if any of the libraries have duplicate function name -definitions,since the function located further down the search chain could -never be called. - -FUNCTION LIBRARIES. Each function library entry in the Library List contains a -library name,a search priority,an entry point offset,and a version number. The -library name must refer to a standard Amiga shared library residing in the -system LIBS: directory so that it can be loaded when needed. Function libraries -can be created and maintained by users or applications developers;Chapter 10 -has information on their design and implementation. - -The "query" function is the library entry point that is actually called by the -interpreter. It must be specified as an integer offset(e.g. "-30")from the -library base. The return code from the query call then indicates whether the -desired function was found;it it was,the function is called with the parameters -passed by the interpreter and the function result is returned to the caller. -Otherwise,the search continues with the next entry in the list. In either event -the library is closed to await the next call. - -A note of caution: not every Amiga shared library can be used as a function -library. Function libraries must have a special entry point to perform the -dynamic linking required to access the functions from within ARexx. Each -library should include documentation providing its version number and the -integer offset to its "query" entry point. - -FUNCITON HOSTS. The name associated with a function host is the name of its -public message port. Function calls are passed to the host as a message packet; -it is then up to the individual host to determine whether the specified -function name is one that it recognizes. The name resolution is completely -internal to the host,so function hosts provide a natural gateway mechanism for -implementing remote procedure calls to other machines in a network. - -THE CLIP LIST - -The Clip List maintains a set of(name,value)pairs that may be used for a -variety of purposes. Each entry in the list consists of a name and a value -string,and may be located by name. Since the Clip List is publicly accessible, -it may be used as a general clipboard-like mechanism for intertask -communication. In general,the names used should be chosen to be unique to an -application to prevent collisions with other programs. Any number of entries -may be posted to the list. - -One potential application for the Clip List is as a mechanism for loading -predefined constants into an ARexx program. The language definition does not -include a facility comparable to the "header file" preprocessor in the "C" -language. However,consider a string in the Clip List of the form - - pi=3.14159; e=2.718; sqrt2=1.414 ... - -i.e.,a series of assignments separated by semicolons. In use,such a string -could be retrieved by name using the Built-In function GETCLIP()and then -INTERPRETed within the program. The assignment statements within the string -would then create the required constant definitions. The following program -fragment illustrates the process:: - - 86 - - /* assume a string called "numbers" is available*/ - numbers=getclip('numbers') /* case-sensitive */ - interpret numbers /* ... assignments*/ - ... - -More generally,the strings would not be restricted to contain only assignment -statements,but could include any valid ARexx statements. The Clip List could -thus provide a series of programs for initializations or other processing -tasks. - -The resident process supports addition and deletion operations for maintaining -the Clip List. The names in the(name,value)pairs are assumed to be in mixed -cases,and are maintained to be unique in the list. An attempt to add a string -with an existing name will simply update the value string. The name and value -strings are copied when an entry is posted to the list,so the program that adds -an entry is not required to maintain the strings. - -Entries posted to the Clip List remain available until explicitly removed. The -Clip List is automatically released when the resident process exits. - - 87 - - CHAPTER 10 INTERFACING TO AREXX - -This chapter discusses the issues involved in designing and implementing an -interface between ARexx and an external applications program. The material -presented here is directed to software developers,so a high degree of -familiarity with programming the Amiga in either "C" or assembly-language is -assumed. - -ARexx can interact with external programs in several ways. The command -interface is used to communicate with an external program running as a separate -task in the Amiga's multitasking environment. The interaction takes place by -passing messages between public message ports,and is in many ways similar to -the interaction of a program with Intution,the Amiga's window and menu manager. -The command interface provides both a means of sharing data and a method of -controlling an applications program. - -Function libraries provide a mechanism for calling external code as part of an -ARexx program's tasks context. The linkages for such calls are established -dynamically at run time rather than when the program is linked,so each function -library must include an entry point to match function names with the address of -the function to be called. - -Function hosts are external tasks that manage a public message port for -communicating with ARexx or other programs. Both function hosts and function -libraries are managed by the Library List,which provides a prioritized search -mechanism for resolving function names. Function hosts may be used as a gateway -into a metwork to provide a remote procedure call facility. ARexx imposes no -constraints on the internal operations of a function host,except to require -that message packets be returned with an appropriate code. - -The resident process acts as the hub for communications between ARexx and -external entities. It opens and manages a public message port named "REXX," and -provides a number of support services. Note that the resident process is itself -a "host application" whose function it is to launch ARexx programs and maintain -global resources. The activation structures for all ARexx programs are linked -into a list maintained by the resident process,and in principle their compete -internal states are accessible to external programs. - -The ARexx interpreter is structured as an Amiga shared library and includes -entry points specifically designed to help implement an interface to ARexx. -Functions are available to create and delete message packets,argument -strings,and other resources. Software developers are rged to use these library -routines whenever possible,as they provide "safe" access to the internal -structures. The ARexx Systems Library functions are documented in Appendix C. -The distribution disk contains the INCLUDE files required to required to work -with the library and data structures. - - 89 - -10-1 BASIC STRUCTURES - -Most developers will need to work with only two of the data structures used by -ARexx. The RexxArg structure is used for all of the strings manipulated by the -interpreter. It is usually passed as an argstring,a pointer offset from the -structure base that may be treated like an ordinary string pointer. The RexxMsg -structure is an extension of an EXEC Message,and is the message packet used for -all communications with external programs. - -ARGSTRINGS. All ARexx strings are maintained as RexxArg structures,which are -diagrammed in Table 10.1 below. Note that his actually a variable-length -structure allocated for each specific string length. String parameters are sent -in the form of argstrings,a pointer to the string buffer area of the RexxArg -structure. The string in the stucture is always given a trailing null byte,so -that external programs can treat argstrings like a pointer to a null-terminated -string. Additional data about the string(its length,hash code,and attributes) -are available at negative offsets from the argstring pointer. - - Table 10.1 The RexxArg Structure - - STRUCTURE RexxArg,0 - LONG ra_Size ; allocated length - UWORD ra_Length ; length of string - UBYTE ra_Flags ; attribute flags - UBYTE ra_Hash ; hash code - STRUCT ra_Buff,8 ; buffer (argstring points here) - -Library functions are available to create and delete argstrings,and for -converting integers into argstring format. The function CreateArgstring() -allocates a structure and copies a string into it,and returns an argstring -pointer to the structure. The function DeleteArgstring()can be used to release -an argstring when it is no longer needed. - -MESSAGE PACKETS. All communications between ARexx and external programs are -mediated with with message packets,whose structure is diagrammed in Table 10.2 -below. Functions are provided in the ARexx Systems Library to create, -initialize,and delete these message packets. Each packet sent from ARexx to an -external program is marked with a special pointer in its name field. This can -be used to distinguish the message packets from those belonging to other -programs,in case a message port is being shared. - -Message packets are created using the CreateRexxMsg()function,and can be -released using the DeleteRexxMsg(). Note that the message packets passed by -ARexx to a host application(as a command,for instance)are identical to the -packets the host would use to invoke an ARexx program. This commonality of -design means that only one set of functions is needed to create and delete -message packets,and that external programs can use the same routines that the -interpreter uses to handle the packets. - -RESOURCE NODES. A somewhat higher-level data structure called a "resource node" -(a RexxRsrc structure)is used extensively within ARexx to maintain resource -lists. These nodes are variable-length structures that include the total -allocated length as a field within the node,and that also provide for an -"auto-delete" function. This latter capability allows the address of a clean-up - - 90 - -function to be associated with the node so that an entire(possibly -inhomogeneous)list of resource nodes can be deallocated with a single function -call. - - Table 10.2 The RexxMsg Structures - - STRUCTURE RexxMsg,MN_SIZE - APTR rm_TaskBlock ; global pointer - APTR rm_LibBase ; library pointer - LONG rm_Action ; command code - LONG rm_Result1 ; primary result - LONG rm_Result2 ; secondary result - STRUCT rm_Args,16*4 ; arguments (ARGO-ARG15) - ; the extension area - APTR rm_PassPort ; forwarding port - APTR rm_CommAddr ; host address - APTR rm_FileExt ; file extention - LONG rm_Stdin ; input stream - LONG rm_Stdout ; output steam - LONG rm_avail ; reserved - LABEL rm_SIZEOF ; 128 bytes - -10-2 DESIGNING A COMMAND INTERFACE - -The minimal command interface between ARexx and an applications program -requires only a public message port and a routine to process the commands -received. For most host applications this will require little extra machinery, -as the program will probably already have several message ports for key and -menu events,timer messages,and so on. Processing the command strings should be -relatively straightforward for command-oriented applications. Hosts that are -entirely menu-driven will require somewhat more additional programming,unless -commands are supported only as simulated menu events. The specific choice of -which commands to support is always left up to the applications designer,as -ARexx imposes no restrictions on the structure of the commands that can be -issued. - -The basic sequence of events in the command interface begins when the host -sends a command invocation message to the ARexx resident process. This is -usually in response primitives supported by the host. When the resident process -receives the message packet,it spawns a new DOS process the run the macro -program. The command line is parsed to extract the command token(the first -word),and the interpreter searches for a file that matches the command name. - -Once a macro program file has been found,it is executed by the interpreter and -(usually)results in one or more commands being issued back to the host -application's public port. The macro program waits while each command is -processed by the host,and takes appropriate actions if the return code -indicates that an error occurred. Eventually the macro program finishes and -returns the invocation message packet back to the host. - -Error handling is an important consideration in the interface design. Macro -programs must receive return codes so that processing actions can be altered -when errors occur. - - 91 - -Normally,the host application should not return a message packet until the -command has been processed and its error status in known. Hosts that support -two streams of commands(from the user and from the command interface)will need -a flag to indicate the source of each command. Errors in user commands might -normally be reported on the screen,but errors in ARexx commands must be -reported by setting the result field in the message packet. - -Return codes should generally be chosen to follow the model of an error -severity level,with small integers representing relatively harmless conditions -and larger values indicating progressively more severe errors. This will allow -a characteristic failure level to be established within a macro program,so that -insignificant errors can be ignored. The choice of the specific return code -values is left to the applications designer. - -RECEIVING COMMAND MESSAGES - -Each host application must open a public message port to support the command -interface. When a macro program issues a command to the host,a message packet -containing the command is sent to this public port. The structure of these -message packets is shown in Table 10.2. The rm_Action field will be set to -RXCOMM,and the ARGO parameter slot will contain the command as an argstring -pointer. Parameter slots ARG1-ARG15 are not used for command messages. Two -other fields are potentially of interest: the rm_RexxTask field contains a -pointer to the global data structure for the program that issued the command, -and the rm_LibBase field has the ARexx library base address. The fields in the -extension area may also be of interest to the host program;these are described -later on. Except for setting the result fields rm_Result1 and rm_Result2,the -host application should not alter the message packet. - -RESULT FIELDS - -When the host program finishes processing the command,it must set the primary -result field rm_Result1 to an error severity level or zero if no errors -occurred. This is the field which will be assigned to the special variable RC -in the macro program. The secondary result field rm_Result2 should be set to -zero unless a result string(as described below)is being returned. The packet -can then be returned to the sender using the EXEC function ReplyMsg(). - -In some cases a macro program may request a result string by setting the -RXFB_RESULT modifier bit in the command code. If possible,the host application -should then return the result as an argstring pointer in the secondary result -field rm-Result2. A result string should only be returned if explicitly -requested and if no errors occurred during the call(rm_Result1 set to zero). -Failure to observe these rules will result either in memory loss or in -corruption of the system free-memory list. - -MULTIPLE HOST PROCESSES - -Many applications programs support concurrent activities on several sets of -data. For example,most text editors allow several files to be edited at once. A -command issued from a particular instance of the editor might invoke an ARexx -macro program,so clearly any commands issued from that macro would have to be -directed to the correct instance of the editor. ARexx provides for this by - - 92 - -allowing the applications program to declare an initial host address when a -program is invoked. A separate message port would be opened for each instance -of the host application,and this port would be named as the initial host -address for all invocations from that instance. In the example above,if the -editor opened two ports named "MyEdit1" and "MyEdit2,"then programs invoked by -the "MyEdit1" instance would send commands back to the "MyEdit1" port. - -MULTIPLE MESSAGE PORTS. Host applications are not limited to having a single -message port for commands. If several different kinds of commands are to be -received,it might be appropriate to set up more than one port. Macro programs -would then use the ADDRESS instruction to direct commands to the appropriate -port. The different ports could be used simultaneously,since ARexx programs -execute as separate tasks. - -10-3 INVOKING AREXX PROGRAMS - -ARexx programs are invoked by sending a message packet to the resident process. -Programs may be invoked as either a command or as a function. The command mode -of invocation is generally simpler,as it requires setting only a few fields in -the message packet. - -MESSAGE PACKETS - -The structure of the message packet supported by ARexx is shown in Table 10.2. -This structure provides fields for passing arguments and for specifying -overrides to various internal defaults. The packets are cleared(set to 0)when -allocated,and the client-supplied fields are never altered by ARexx. Message -packets can be reused after being returned,and generally only one is required. - -COMMAND(ACTION)CODE. The rm_Action field of the message packet determines the -mode of invocation. It can be set to either RXCOMM or RXFUNC for command or -function mode,respectively. Several modifier flags can be used with the command -code;these are described later in this chapter. - -ARGUMENT STRINGS. Command strings,function names,and argument strings must be -supplied as argstrings. Strings can be conveniently packaged into argstrings -using the CreateArgstring()library function,which takes a string pointer and a -length as its arguments. Argstrings point to a null-terminated string and may -be treated like an ordinary string pointer in most cases. In principle,a host -application could build the argstrings directly,but since the strings must -remain unchanged for the duration of a ARexx program,the host might need to -maintain many such structures. - -The argstrng pointer returned by CreateArgstring()is installed in the -appropriate parameter slot of the message package:ARGO for the command string -or function name,and ARG1-ARG15 for argument strings. Argstrings can be -recycled after a packet has returned by calling the DeleteArgstring() function. - -SENDING THE PACKET. Once the required fields have been filled in,the host -application can send the packet to the "REXX" public port using the EXEC -function PutMsg(). The address of the "REXX" port can be obtained by a call to -the FindPort()function,but this address should not be cached internally,since -the port could close at any time. To be absolutely safe,the calls to FindPort() -and PutMsg()should be bracketed by calls to the EXEC routines Forbid()and -Permit(). This will exclude the slight possibility that the message port could -close in the few microseconds before the message packet is actually sent to the -port address. - -After sending the packet the host can return to its normal processing,since the -macro program will execute as a separate task. In most cases it will be -advisable to "lock-out" further user commands while the ARexx program is -running,to preserve te integrity of any shared data structures that may be -accessed externally. - -COMMAND INVOCATIONS - -In the command mode of invocation the host supplies a command string consisting -of a name token followed by an argument string. ARexx parses the string to -extract the command name,which is usually the name of a program file. The -default action is to use the remainder of the command string as the(single) -argument string for the program. This may be overridden by requesting command -tokenization,which is done by setting the RXFB_TOKEN modifier flag in the -action code of the message packet. In this case the entire command string will -be parsed,and the program may have many argument strings.(There is no limit to -the number of arguments that may be derived from the command string,since they -don't have to fit into the parameter slots of the message packet.) - -The parsing process uses "white space" (blanks,tabs,etc.)as the token -separators,and has a several special features. - -QUOTING CONVENTION. Either single(')or double(")quotes may be used to surround -items that include "white space" and would otherwise be separated during -parsing. Single quotes may appear within a double-quote-delimited token,and -vice versa;however,double-delimiter sequences are not accepted. The quotes are -removed from the parsed token. An "implicit" quote at the end of the string is -also recognized. If the command string ends before the closing delimiter has -been found,the null byte is accepted as the final delimiter. For example, - look.rexx "Now is the time" "can't ou see - -is a command with the two arguments strings "Now is the time" and "can't you -see"(but without the quotes.) - -STRING FILES. If the command name(the first token of the string)is quoted,it is -assumed to be a "string file" --an ARexx program in a string,rather than the -name of a disk file. This is a convenient way to run very brief programs, -although programs of any length may be stored this way. If command tokenization -has not been specified,the remainder of the string is not scanned and no quote -characters are removed. In this case the quoting convention isuseful only for -indicating "string file" programs. The entire command string can be declared as -a "string file" by setting the RXFB_STRING modifier flag of the action code. -When this flag is set,no parsing at all is applied to the command. - -RESULT STRING. Command invocations do not usually request a result string,but -can do so by setting the RXFB_RESULT modifier flag. The host application must -be prepared to recycle the returned result string once it is no longer needed. - - 94 - -FUNCTION INVOCATIONS - -In a function invocation the host application supplies a function name string -and from 0 to 15 argument strings. The name string is used to locate an -external program file and may include directory specifiers and a file -extension. The actual argument count(not including the name string)must be -placed in the low-order byte of the command code. - -This mode of invocation is normally used when a result string is expected and -the argument strings are conveniently available. Note that a result does not -have to be requested,however. - -RESULT STRINGS. Function invocations request a result string by setting the -RXFB_RESULT modifier flag bit. If no errors occurred and a result string was -requested,the secondary result field in the returned packet will be a pointer -to the result string. However,if the program exited without supplying a result, -the secondary field will be zero. - -STRING FILES. The function name argument may specify a "string file" rather -than the name of a filing system object. This is indicated by setting the -RXFB_STRING modifier flag. - -SEARCH ORDER - -The search for a program file matching a command or function name is normaly a -two-step process. For each directory to be checked,a search is made first with -the current file extension appended to the name string. If this search fails, -the second search uses the unmodified name string. The first step is skipped if -the command or function name includes an explicit file extension. - -The default file extension is ".rexx,"but this can be changed by supplying a -file extension string in an extended message packet. Host applications will -usually specify a file extension,since it provides a convenient way to -distinguish the macro programs that are specific to that application. Refer to -the section on Extension Fields for further details. - -The search path for a program depends on the way the program name was -specified. If an explicit device or directory specification precedes the -program name,only that directory will be searched. For example,the command- -level invocation of "rx df0:s/test" will search only the df0:s directory for a -file named test.rexx or test. If the program name does not include a path,the -search path begins with the current directory and proceeds to the system REXX: -directory. To further the above example,invoking the program as "rx test 1 2 3" -would search for the files test.rexx,test,REXX:test.rexx,and REXX:test,in that -order. - -If an ARexx program cannot be found,one alternative action may be taken. If the -rm_PassPort field of an extended packet was supplied,the message packet is -passed along to that port,which might be the next process in a search chain. -Otherwise the message is returned with a "Program not found"error indication -(error code 1.) - - 95 - -EXTENSION FIELDS - -The RexxMsg structure includes several "extension fields" that can be used to -override various defaults when a program is invoked. These extension fields can -be filled in selectively,and only the non-zero values will override the -corresponding default. ARexx never modifies the extension area. - -Host applications should supply values for the file extension and host address -fields of the message packet. The file extension affects which program files -will match a given command name,and allows macro programs specific to the host -to be given distinctive names. The host address must refer to a public message -port,and will usually indicate the host's own port. Any appropriate(but usually -short)strings can be chosen for these values. Oftern,the name of the -applications program itself can be used as its host address and file extension. - -PASSPORT. The rm_PassPort field allows the search for a program to be "passed -along" to another messsage port after checking for an ARexx program. If the -command or function name doesn't resolve to an ARexx program,the message packet -is forwarded to the message port specified as the PassPort. This allows -applications to maintain control over the search order for external program -files. - -Note that the rm_PassPort field must be the actual address of a message port, -rather than a name string. The PassPort therefore does not have a public port, -but the port should be a secured resource,since the message is sent directly to -this address without checking to see whether it is a valid message port. - -HOST ADDRESS. The rm_ComAddr field overrides the default initial host address, -which is "REXX." The host address is the name of the messsage port to which -commands will be directed,and is supplied as a pointer to a null-terminated -string. Applications that support multiple instances of user data will usually -create a separate message port for each instance. The name of this port would -then be supplied as the host address for any commands issued from that -instance. - -FILE EXTENSION. The rm_FileExt field is used to override the default file -extension for ARexx programs,which is "REXX". Host applications can use the -file extension to distinguish the names of the macro programs specific to that -application. It is supplied as a pointer to a null-terminated string. - -INPUT AND OUTPUT STREAMS. The default input and output steams for an ARexx -program are inherited from the host application's process structure,if the host -is a process rather than just a task. One or both of these streams may be -overridden by supplying an appropriate value in the rm-Stdin or rm_stdout -fields. The values supplied must be valid DOS filehandles,and must not be -closed while the program is executing. The steams are installed directly into -the program's process structure,replacing the prior values. - -The output stream is also used as the default tracing stream for the program. -If interactive tracing is to be used in a program,the output stream should -refer to a console device,since it will be used for input as well. - - 96 - -In the event than an ARexx program is invoked by an EXEC task,rather than by an -DOS process,the extension field streams are the only way that the launched -program can be given default I/O streams. - -INTERPRETING THE RESULT FIELDS - -The message packet that invoked an ARexx program is returned to the client when -the program finishes. The two result fields will contain error codes or -possibly a result string. The interpretation of the result fields depends -partly on the mode of invocation. If the primary result field rm_Result1 is -zero,the program executed normally and the secondary field rm_Result2 will -contain a pointer to a result string,assuming that one was requested(and -available.) - -If the primary result is non-zero,it represents either an error severity level -or else the return code from a command invocation. The two cases can be -distinguished by examining the secondary result. If the secondary field is also -non-zero,an error occurred and the secondary field is an ARexx error code. If -the secondary result is zero,then the primary result is the return code passed -by an "EXIT rc" or "RETURN rc" instruction in the program. The application -program can use this return code either as an error indication or to initiate -some particular processing action. - -Result strings are always returned as an argstring and become the property(that -is,responsibility)of the host. When the string is no longer needed,it can be -released using the DelArgstring() function. - -Errors occurring in macro programs should usually be reported to the user. -Explanatory messages are available for all ARexx error codes,and can be -obtained by calling the ARexx Systems Library function ErrorMsg(). - -10-4 COMMUNICATING WITH THE RESIDENT PROCESS - -All communications with the resident process are handled by passing message -packets,which were previously diagrammed in Table 10.2. The packet has a -command field that describes the action to be performed and parameter fields -that are specific to the command. Message packets are processed as they are -received,and are then either returned to the sender or passed along to another -process(in the case of a program invocation.) The packet includes two result -fields that are used to return error codes or result strings. The parameter -fields of the message packet may contain either(long)integer values or pointers -to argument strings. String arguments are assumed to be argstring pointers -unless otherwise specified. - -COMMAND(ACTION)CODES - -The command codes that are currently implemented in the resident process are -described below. Commands are listed by their mnemonic codes,followed by the -valid modifier flags. The final code value is always the logical OR of the code -value and all of the modifier flags selected. The command code is installed in -the rm_Action field of the message packet. - -USAGE: RXADDCON [RXFB_NONRET] -This code specifies an entry to be added to the Clip List. Parameter slot ARGO -points to the name string,slot ARG1 points to the value string,and slot ARG2 -contains the length of the value string. - - 97 - -The name and value arguments do not need to be argstrings,but can be just -pointers to storage areas. The name should be a null-terminated string,but the -value can contain arbitrary data including nulls. - -USAGE: RXADDFH [RSFB_NONRET] -This action code specifies a function host to be added to the Library List. -Parameter slot ARGO points to the(null-terminated)host name string,and slot -ARG1 holds the search priority for the node. The search priority should be an -integer between 100 and -100 inclusive;the remaining priority ranges are -reserved for future extensions. If a none already exists with the same name,the -packet is returned with a warning level error code. Note that no test is made -at this time as to whether the host port exists. - -USAGE:RXADDLIB [RXFB_NONRET] -This code specifies an entry to be added to the Library List. Parameter slot -ARGO points to a null-terminated name string referring either to a function -library or a function host. Slot ARG1 is the priority for the node and should -be an integer between 100 and -100 inclusive;the remaining priority ranges are -reserved for future extensions. Slot ARG2 contains the entry oint offset and -slot ARG3 is the library version number. If a node already exists with the same -name,the packet is returned with a warning level error code. Otherwise,a new -entry is added and the library or host becomes available to ARexx programs. -Note that no test is made at this time as to whether the library exists and can -be opened. - -USAGE:RXCOMM [RXFB_TOKEN] [RXFB_STRING] [RXFB_RESULT] [RXFB_NOIO] -Specifies a command-mode invocation of an ARexx program. Parameter slot ARGO -must contain an argstring ointer to the command string. The RXFB_TOKEN flag -specifies that the command line is to be tokenized before being passed to the -invoked program. The RXFB_STRING flag bit indicates that the command string is -a "string file." Command invocations do not normally return result strings,but -the RXFB_RESULT flag can be set if the caller is prepared to handle the cleanup -associated with a returned string. The RXFB_NOIO modifier suppresses the -inheritance of the host's input and output streams. - -USAGE:RXFUNC [RXFB_RESULT] [RXFB_STRING] [RXFB_NOIO] argcount -This command code specifies a function invoction. Parameter slot ARGO contains -a pointer to the function name string,and slots ARG1 through ARG15 point to the -argument strings,all of which must be passed as argstrings. The lower byte of -the command code is the argument count;this count excludes the function name -string itself. Function calls normally set the RXFB_RESULT flag,but this is not -mandatory. The RXFB_STRING modifier indicates that the function name string is -actually a "string file". The RXFB_NOIO modifier suppresses the inheritance of -the host's input and output streams. - -USAGE:RXREMCON [RXFB_NONRET] -This code requests that an entry be removed from the Clip List. Parameter slot -ARGO points to the null-terminated name to be removed. The Clip List is -searched for a node matching the supplied name,and if a match is found the list -node is removed and recycled. If no match is found the packet is returned with -a warning error code. - -USAGE:RXREMLIB [RXFB_NONRET] -This command removes a Library List entry. Parameter slot ARGO points to the -null terminated string specifying the library to be removed. The Library List -is searched for a node matching the library name,and if a match is found the - - 98 - -node is removed and released. If no match is found the packet is returned with -a warning error code. The libary node will not be removed if the library is -currently being used by an ARexx program. - -USAGE:RXTCCLS [RXFB_NONRET] -This code requests that the global tracing console be closed. The console -window will be closed immediately unless one or more ARexx programs are waiting -for input from the console. In this event,the window will be closed as soon as -the active programs are no longer using it. - -USAGE:RXTCOPN [RXFB_NONRET] -This command requests that the global tracing console be opened. Once the -console is open,all active ARexx programs will divert their tracing output to -the console. Tracing input(for interactive debugging)will also be diverted to -the new console. Only one console can be opened;subsequent RXTCOPN requests -will be returned with a warning error message. - -MODIFIER FLAGS - -Command codes may include modifier flags to select various processing options. -Modifier flags are specific to certain commands,and are ignored otherwise. - -RXFB_NOIO. This modifier is used with the RXCOMM and RXFUNC command codes to -suppress the automatic inheritance of the host's input and output streams. - -RXFB_NONRET. Specifies that the message packet is to be recycled by the -resident process rather than being returned to the sender. This implies that -the sender doesn't care about whether the requested action succeeded,since the -returned packet provides the only means of acknowledgement. Messge packets are -released using the library function DeleteRexxMsg(). - -RXFB_RESULT. This modifer is valid with the RXCOMM and RXFUNC commands,and -requests that the called program return a result string. If the program -EXITs(or RETURNs)with an expression,the expression result is returned to the -caller as an argstring. It is then the caller's responsibility to release the -argstring when it is no longer needed;this can be done using the library -function DeleteArgstring(). - -RXFB_STRING. This modifer is valid with the RXCOMM and RXFUNC command codes. It -indicates that the command or function argument(in slot ARGO)is a "string file" -rahter than a file name. - -RXFB_TOKEN. This flag is used with the RXCOMM code to request that the command -string be completely tokenized before being passed to the invoked program. -Programs invoked as commands normally have only a single argument string. The -tokenization process uses "white space" to separate the tokens,except within -quoted strings. Quoted strings can use either single or double quotes,and the -end of the command string(a null character)is considered as an implicit closing -quote. - - 99 - -RESULT FIELDS - -The resident process uses the standard command-level conventions for the -primary return code installed in rm_Result1. Minor or warning errors are -indicated by a value of 5,and more serious errors are returned as values of 10 -or 20. The secondary result field rm-Result2 will either be zero or an ARexx -error code if applicable. - -Note that RXCOMM and RXFUNC messages are returned directly by the invoked macro -program,rathe than by the residen process. - -10-5 EXTERNAL FUNCTION LIBRARIES - -ARexx supports external function libraries as a mechanism for user-defined -extensions to the language. Function libraries may be written and maintained by -users or applications developers. - -DESIGN CONSIDERATIONS - -There are several different purposes for which a function library might be -designed. In the simplest case,a library could be used to extend the string -manipulation or mathematical capabilities of the language by defining new -functions. Such a library could be entirely self-contained or might call other -system libraries to perform specific operations. - -Another alternative would be to build a library that interacts closely with an -external applications program. This could allow specific operations in the host -application to be performed as function calls rather than as commands. There -are several advantages to this approach,as it avoids the need to parse command -strings and does not require the multiple task context changes associated with -message-passing. The library might include entry points for specific operaions -as well as functions to support processing required by the applications -program. - -Function libraries can also serve as bridges to other system or applications -libraries. For example,if a program needed to call the functions in a graphics -library,a bridge library could be built to match the function names in the -program with the appropriate entry point in the graphics library. A related -possibility would be to use ARexx as a test driver for a program under -development. Once the query table and parameter passing mechanisms for the -function library have been built,new routines under development could be tested -by just adding a table entry. Since building test programs is ofter very time- -consuming,the flexibility and interactive debugging capabilities of ARexx make -it an attractive alternative to compiled languages like "C." - -Regardless of the intended application,all function libraries share a common -structure. The initial design follows that of the standard EXEC shared library, -with the three required entry points Open,Close,and Expunge,plus a reserved -slot. The library must also have a "query" entry point,which serves to match -the name supplied by ARexx with the intended function. Typically,this will -consist of a table of function names and a routine to search for the specified -one. - -REENTRANCY. Functions libraries should be designed to be fully reentrant,since -any number of ARexx programs may be running at any time. If this is not -feasible due to other design constraints,the query function should include a -lockout mechanism to prevent multiple calls to the library routines. - - 100 - -CALLING CONVENTION - -The library's query function will be called from the interpreter's context with -the address of a message packet in register A0 and the library base in A6. The -structure of the message packet is the same as that in Table 10.2,but note that -although a message packet is used to carry the arguments,it is not queued at a -message port and does not need to be unlinked. The name of the function to be -called is carried in the ARGO parameter slot. The query function must search -for this function name and,if the name cannot be found,must return an error -code of 1("Program not found")in register D0. The library will then be closed -and the search continued in the next function library. The query function -should not modify any fields within the message packet,as it must be passed -along to the next library until the function is located. - -PARAMETER CONVERSION - -Once the requested function has been found,the query funcion may need to -transform the parameters passed by ARexx into the form expected by the -function. Whether the parameter strings need to be converted depends on how -they are to be used. In some cases it may be sufficient just to foward a -pointer to the message packet to the called function,while in other cases the -query function may need to load parameters into registers or to perform -conversion operations. The parameters in ARG1-ARG15 are always passed as -argstrings,and may be treated like a pointer to a null-terminated string. -Further attributes are stored at negative offsets from the argstring pointer, -and may be helpful in working with the string. - -Numeric quantities are passed as strings of ASCII characters and will need to -be converted to integer or floating-point format if arithmetic calculations are -to be performed. The ARexx System Library includes a limited set of functions -to do parameter conversions. - -The actual parameter count can be obtained from the low-order byte of the -rm_Action field in the message packet. The count never includes the function -name itself(in ARGO),but does include arguments specified as "defaults." Such -arguments will have a zero value in the corresponding parameter slot. - -Note that the parameter block of the message packet,containing the fields -ARG0-ARG15,is structured like the argument array expected by the main(argc, -argv)function of a "C" program. This suggests a simple way that a function -library could provide a bridge to a series of "C" programs. The query function -would need only to determine the address of the called function,and then push -the parameter block address and argument count onto the program stack. - -RETURNED VALUES - -Each library function must return an error code and a value string. The error -code is returned in register D0,and should be 0 if no errors occurred. The -value string must be returned as an argstring pointer in register A1,unless D0 -indicates that an error occurred during the call. The mechanisms for creating -the proper return values can be made part of the query function,so that all -functions in the library share a common return path. - - 101 - -10-6 DIRECT MANIPULATION OF DATA STRUCTURES - -All of the data structures maintained by the resident process are built into -the ARexx Systems Library base and are therefore accessible to external -programs. The Task List in the RexxBase structure links the global data -structures for all currently active ARexx programs. This linkage uses the node -contained in the message port of the RexxTask structure,rather than at the head -of the structure. The RexxTask structure is the global data structure and -initial storage environment for the ARexx program,and all descendant storage -environments are linked into the Environment List. The linkage of internal data -structures is such that the complete internal state of all ARexx programs can -be reached starting from the library base pointer. - -Two library functions,LockRexxBase() and UnlockRexxBase(),are provided to -mediate access to the global structures. The structure base should be locked -before reading any of the data items or traversing any of the lists. The -present version of these functions provides only a global lock,but future -extensions will allow individual resources to be locked. - -In general it should not be necessary to manipulate directly any of these data -structures. Functions have been provided in the ARexx Systems Library to -perform all of the operations required to interface external program to the -ARexx system. It is therefore recommended that applictions developers avoid -using any of the internal structures except as provided through the library -functions. - - 102 - - APPENDIX A ERROR MESSAGES - -When the ARexx interpeter detects an error in a program,it returns an error -code to indicate the nature of the problem. Errors are normally handled by -displaying the error code,the source line number where the error occurred,and a -brief message explaining the error condition. Unless the SYNTAX interrupt has -been previously enabled(using the SIGNAL instruction),the program then -terminates and control returns to the caller. Most syntax and execution errors -can be trapped by the SYNTAX interrupt,allowing the user to retain control and -perform whatever special error processing is required. Certain errors are -generated outside of the context of an ARexx program,and therefore cannot be -trapped by this mechanism. Refer to chapter 7 for further information on error -trapping and processing. - -Associated with each error code is a severity level that is reported to the -calling program as the primary result code. The error code itself is returned -as the secondary result. The subsequent propagation or reporting of these codes -is of course dependent on the external(calling)program. - -The following pages list all of the currently-defined error codes,along with -the associated severity level and message string. - -ERROR: 1 SEVERITY: 5 MESSGE: PROGRAM NOT FOUND -The named program could not be found,or was not an ARexx program. ARexx -programs are expected to start with a "/*" sequence. This error is detected by -the external interface and cannot be trapped by the SYNTAX interrupt. - -ERROR: 2 SEVERITY: 10 MESSAGE: EXECUTION HALTED -A control-C break or an external half request was received and the program -terminated. This error will be trapped if the HALT interrupt has been enabled. - -ERROR: 3 SEVERITY: 20 MESSAGE: INSUFFICIENT MEMORY -The interpreter was unable to allocate enough memory for an operation. Since -memory space is required for all parsing and execution operations,this error -cannot usually be trapped by the SYNTAX interrupt. - -ERROR: 4 SEVERITY: 10 MESSAGE: INVALID CHARACTER -A non-ASCII character was found in the program. Control codes and other non- -ASCII characters may be used in a program by defining them as hex or binary -strings. This is a scan phase error and cannot be trapped by the SYNTAX -interrupt. - -ERROR: 5 SEVERITY: 10 MESSAGE: UNMATCHED QUOTE -A closing single or double quote was missing. Check that each string is -properly delimited. This is a scan phase error and cannot be trapped by the -SYNTAX interrupt. - - 103 - -ERROR: 6 SEVERITY: 10 MESSAGE: UNTERMINATED COMMENT -The closing "*/" for a comment field was not found. Remember that comments may -be nested,so each "/*" must be matched by a "*/." This is a scan phase error -and cannot be trapped by the SYNTAX interrupt. - -ERROR: 7 SEVERITY: 10 MESSAGE: CLAUSE TOO LONG -A clause was too long for the internal buffer used as temporary storage. The -source line in question should be broken into smaller parts. This is a scan -phase error and cannot be trapped by the SYNTAX interrupt. - -ERROR: 8 SEVERITY: 10 MESSAGE: INVALID TOKEN -An unrecognized lexical token was found,or a clause could not be properly -classified. This is a scan phase error and cannot be trapped by the SYNTAX -interrupt. - -ERROR: 9 SEVERITY: 10 MESSAGE: SYMBOL OR STRING TOO LONG -An attempt was made to create a string longer than the maximum supported by the -interpreter. The implementation limits for internal structure are given in -Appendix B. - -ERROR: 10 SEVERITY: 10 MESSAGE: INVALID MESSAGE PACKET -An invalid action code was found in a message packet sent to the ARexx resident -process. The packet was returned without being processed. This error is -detected by the external interface and cannot be trapped by the SYNTAX -interrupt. - -ERROR: 11 SEVERITY: 10 MESSAGE: COMMAND STRING ERROR -A command string could not be processed. This error is detected by the external -interface and cannot be trapped by the SYNTAX interrupt. - -ERROR: 12 SEVERITY: 10 MESSAGE: ERROR RETURN FROM FUNCTION -An external function returned a non-zero error code. Check that the correct -parameters were supplied to the function. - -ERROR: 13 SEVERITY: 10 MESSAGE: HOST ENVIRONMENT NOT FOUND -The message port corresponding to a host address string could not be found. -Check that the required external host is active. - -ERROR: 14 SEVERITY: 10 MESSAGE: REQUESTED LIBRARY NOT FOUND -An attempt was made to open a function library included in the Library List,but -the library could not be opened. Check that the correct name and version of the -library were specified when the library was added to the resource list. - -ERROR: 15 SEVERITY: 10 MESSGE: FUNCTION NOT FOUND -A function was called that could not be found in any of the currently -accessible libraries,and could not be located as an external program. Check -that the appropriate function libraries have been added to the Libraries List. - - 104 - -ERROR: 16 SEVERITY: 10 MESSAGE: FUNCTION DID NOT RETURN VALUE -A function was called which failed to return a result string,but did not -otherwise report an error. Check that the function was programmed correctly,or -invoke it using the CALL instruction. - -ERROR: 17 SEVERITY: 10 MESSAGE: WRONG NUMBER OF ARGUMENTS -A call was made to a function which expected more(or fewer)arguments. This -error will be generated if a Built-In or external function is called with more -arguments than can be accomodated in the message packet used for external -communications. - -ERROR: 18 SEVERITY: 10 MESSAGE: INVALID ARGUMENT TO FUNCTION -An inappropriate argument was supplied to a function,or a required argument was -missing. Check the parameter requirements specified for the function. - -ERROR: 19 SEVERITY: 10 MESSAGE: INVALID PROCEDURE -A PROCEDURE instruction was issued in an invalid context. Either no internal -functions were active,or a PROCEDURE had already been issued in the current -storage environment. - -ERROR: 20 SEVERITY: 10 MESSAGE: UNEXPECTED THEN OR WHEN -A WHEN or THEN instruction was executed outside of a valid context. The WHEN -instruction is valid only within a SELECT range,and THEN must be the next -instruciton following an IF or WHEN. - -ERROR: 21 SEVERITY: 10 MESSAGE: UNEXPECTED ELSE OR OTHERWISE -An ELSE or OTHERWISE was found outside of a valid context. The OTHERWISE -instruction is valid only within a SELECT range. ELSE is valid only following -the THEN branch of an IF range. - -ERROR: 22 SEVERITY: 10 MESSAGE: UNEXPECTED BREAK,LEAVE,or ITERATE -The BREAK instruction is valid only within a DO range or inside an INTERPRETed -string. The LEAVE and ITERATE instuctions are valid only within an iterative DO -range. - -ERROR: 23 SEVERITY: 10 MESSAGE: INVALID STATEMENT IN SELECT -A invalid statement was encountered within a SELECT range. Only WHEN,THEN,and -OTHERWISE statements are valid within a SELECT range,except for the conditional -statements following THEN or OTHERWISE clauses. - -ERROR: 24 SEVERITY: 10 MESSAGE: MISSING OR MULTIPLE THEN -An expected THEN clause was not found,or another THEN was found after one had -already been executed. - -ERROR: 25 SEVERITY: 10 MESSAGE: MISSING OTHERWISE -None of the WHEN clauses in a SELECT succeeded,but no OTHERWISE clause was -supplied. - -ERROR: 26 SEVERITY: 10 MESSAGE: MISSING OR UNEXPECTED END -The program source ended before an END was found for a DO or SELECT instruction -or an END was encountered outside of a DO or SELECT range. - - 105 - -ERROR: 27 SEVERITY: 10 MESSAGE: SYMBOL MISMATCH -The symbol specified on an END,ITERATE,or LEAVE instruction did not match the -index variable for the associated DO range. Check that the active loops have -been nested properly. - -ERROR: 28 SEVERITY: 10 MESSAGE: INVALID DO SYNTAX -An invalid DO instruction was executed. An initializer expression must be given -if a TO or BY expression is specified,and a FOR expression must yield a non- -negative integer result. - -ERROR: 29 SEVERITY: 10 MESSAGE: INCOMPLETE IF OR SELECT -An IF or SELECT range ended before all of the required statement were found. -Check whether the conditional statement following a THEN,ELSE,or OTHERWISE -clause was omitted. - -ERROR: 30 SEVERITY: 10 MESSAGE: LABEL NOT FOUND -A label specified by a SIGNAL instruction,or implicitly referenced by an -enabled interrupt,could not be found in the program source. Labels defined -dynamically by an INTERPRET instruction or by interactive input are not -included in the search. - -ERROR: 31 SEVERITY: 10 MESSAGE: SYMBOL EXPECTED -A non-symbol token was found where only a symbol token is valid. The DROP,END, -LEAVE,ITERATE,and UPPER instructions may only be followed by a symbol token,and -will generate this error if anything else is supplied. This message will also -be issued if a required symbol is missing. - -ERROR: 32 SEVERITY: 10 MESSAGE: SYMBOL OR STRING EXPECTED -An invalid token was found in a context where only a symbol or string is valid. - -ERROR: 33 SEVERITY: 10 MESSAGE: INVALID KEYWORD -A symbol token in an instruction clause was identified as a keyword,but was -invalid in the specific context. - -ERROR: 34 SEVERITY: 10 MESSAGE: REQUIRED KEYWORD MISSING -An instuction clause required a specific keyword token to be present,but it was -not supplied. For example,this messge will be issued if a SIGNAL ON instruction -is not followed by one of the interrupt keywords(e.g.SYNTAX.) - -ERROR: 35 SEVERITY: 10 MESSAGE: EXTRANEOUS CHARACTERS -A seemingly valid statement was executed,but extra characters were found at the -end of the clause. - -ERROR: 36 SEVERITY: 10 MESSAGE: KEYWORD CONFLICT -Two mutually exclusive keywords were included in an instruction clause,or a -keyword was included twice in the same instruction. - -ERROR: 37 SEVERITY: 10 MESSAGE INVALID TEMPLATE -The template provided with an ARG,PARSE,or PULL instruction was not properly -constructed. Refer to Chapter 8 for a description of template structure and -processing. - - 106 - -ERROR: 38 SEVERITY: 10 MESSAGE: INVALID TRACE REQUEST -The alphabetic keyword supplied with a TRACE instruction or as the argument to -the TRACE()Built-In function was not valid. Refer to Chapter 7 for the valid -TRACE options. - -ERROR: 39 SEVERITY: 10 MESSAGE: UNINITIALIZED VARIABLE -An attempt was made to use an uninitialized variable while the NOVALUE -interrupt was enabled. - -ERROR: 40 SEVERITY: 10 MESSAGE: INVALID VARIABLE NAME -An attempt was made to assign a value to a fixed symbol. - -ERROR: 41 SEVERITY: 10 MESSAGE: INVALID EXPRESSION -An error was detected during the evaluation an expression. Check that each -operator has the correct number of operands,and that no extraneous tokens -appear in the expression. This error will be detected only in expressions that -are actually evaluated. No checking is performed on expressions in clauses that -are being skipped. - -ERROR: 42 SEVERITY: 10 MESSAGE: UNBALANCED PARENTHESE -An expression was found with an unequal number of opening and closing -parentheses. - -ERROR: 43 SEVERITY: 43 MESSAGE: NESTING LIMIT EXCEEDED -The number of subexpressions in an expression was greater than the maximum -allowed. The expression should be simplified by breaking it into two or more -intermediate expressions. - -ERROR: 44 SEVERITY: 10 MESSAGE: INVALID EXPRESSION RESULT -The result of an expression was not valid within its context. For example,this -messge will be issued if an increment or limit expression in a DO instruction -yields a non-numeric result. - -ERROR: 45 SEVERITY: 10 MESSAGE: EXPRESSION REQUIRED -An expression was omitted in a context where one is required. For example,the -SIGNAL instruction,if not followed by the keywords ON or OFF,must be followed -by an expression. - -ERROR: 46 SEVERITY: 10 MESSAGE: BOOLEAN VALUE NOT 0 OR 1 -An expression result was expected to yield a boolean result,but evaluated to -something other than 0 or 1. - -ERROR: 47 SEVERITY: 10 MESSAGE: ARITHMETIC CONVERSION ERROR -A non-numeric operand was used in a operation requiring numeric operands. This -message will also be generated by an invalid hex or binary string. - -ERROR: 48 SEVERITY: 10 MESSAGE: INVALID OPERAND -An operand was not valid for the intended operation. This message will be -generated if an attempt is made to divide by 0,or if a fractional exponent is -used in an exponentiation operation. - - 107 - - APPENDIX B LIMITS AND COMPATIBILITY - -ARexx was designed to adhere closely to the REXX language standard. This -appendix discusses those areas where ARexx departs from the standard. - -B-1 LIMITS - -Language definitions seldom include predefined limits to the program structures -that can be created. Only a few such restrictions were imposed in implementing -ARexx,and most of the internal structure are limited only by the total amount -of memory available. The current implementation limits are listed below. - -LENGTH OF STRINGS. Strings,symbol names,and value strings are limited to a -maximum length of 65,535 bytes. - -LENGTH OF CLAUSES. Clauses are limited to a maximum of 800 characters after -removing comments and multiple blanks. - -NODES IN COMPOUND NAMES. Compound symbol names may include a maximum of 50 -nodes,including the stem. - -ARGUMENTS TO FUNCTIONS. Built-In and external functions are limited to a -maximum of 15 arguments. There is no limit to the number of arguments that may -be passed to an internal function. - -SUBEXPRESSION NESTING. The maximum nesting level for subexpressions is 32. - -B-2 COMPATIBILITY - -ARexx departs in a few ways from the language definition. The differences can -be classified as omissions or extensions,and are described below. - -OMISSIONS. The only significant specification of the language standard omitted -from this implementation is the arbitrary-precision arithmetic facility. -Arithmetic operations are limited to about 14 digits of precision,and the FUZZ -option is not implemented at all. Only the SCIENTIFIC format is used for -exponential notation. The full numeric capabilities will be provided in a later -release. - -EXTENSIONS. The following extensions to the language standard have been -included in this implementation: - -BREAK INSTRUCTION. A new instruction called BREAK has been implemented. It is -used to exit from the scope of any DO or INTERPRET instruction. - -ECHO INSTRUCTION. The ECHO instruction has been included as a synonym for SAY. - -SHELL INSTRUCTION. The SHELL instructiion has been included as a synonym for -ADDRESS. - - 109 - -SIGNAL OPTIONS. Several additional SIGNAL keywords have been implemented. -BREAK_C,BREAK_D,BREAK_E,and BREAK_F will detect and trap the control-C through -control-F signals passed by AmigaDOS. The IOERR keyword traps errors detected -by the I/O system. - -STEM SYMBOLS. A stem symbol is valid anywhere that a simple symbol could be -employed. - -TEMPLATE PROCESSING. Templates have been generalized in several ways. Variable -symbols may be used as positional tokens if preceded by an operator;the "=" -operator is used to denote an absolute position. Multiple templates can be used -with all source forms of the PARSE instruction. - - 110 - - APPENDIX C THE AREXX SYSTEMS LIBRARY - -The ARexx interpreter is supplied as a shared library named rexxsyslib.library -and should reside in the system LIBS:directory. While many of the library -routines are highly specific to the interpreter,some of the functions will be -useful to applications that use ARexx. The library is opened when the ARexx -resident process is first loaded and will always be available while it remains -active. - -The system library routines were designed to be called from assembly-language -programs and,unless otherwise noted,save all registers except for A0/A1 and -D0/D1. Many routines return values in more than one register to help reduce -code size. In addition,the routines will set the condition-code register(CCR) -wherever appropriate. In mode cases the CCR reflects the value returned in D0. - -The library offsets are defined in the file rxslib.i,which should be INDLUDEd -in the program source code. Calls may be made from "C" programs if suitable -binding routines are provided when the program is linked. The definitions for -the constants and data structures used in ARexx are provided as INCLUDE files -on the program distribution disk. These should be reviewed carefully before -attempting to use the library functions. - -C-1 FUNCTION GROUPS -The library functions can be frouped into Conversion,Input/Output,Resource -Management,and String Manipulation functions. - -DATA CONVERSION. These functions provide many of the common data-conversion -requirements. - -INPUT/0UTPUT. Two levels of I/O support are provided. The low level functions -use DOS filehandles directly,while the higher-level functions use linked lists -of IoBuff structures and support logical file names. - -RESOURCE. These functions allocate,release,or otherwise manage the data -structures used with ARexx. - -STRING FUNCTIONS. All data in ARexx are managed as strings. These functions -provide some of the more common string-manipulation operations. - - 111 - - TABLE C.1 AREXX SYSTEMS LIBRARY FUNCTIONS - -NAME FUNCTIONAL GROUP DESCRIPTION -AddClipNode Resource Allocate a Clip node -ClearMem Resource Clear a block of memory -ClearRexxMsg Resource Release argstrings from message -CloseF Input/Output Close a file buffer -ClosePublicPort Resource Close a port resource node -CmpString String Compare string structures for equality -CreateArgstring Resource Create an argstring structure -CreateDOSPkt Input/Output Creata a DOS Standard Packet -CreateRexxMsg Resource Create a message packet -CurrentEnv Resource Get current storage environment -CVa2i Conversion ASCII to integer -CVc2x Conversion Character to Hex or Binary digits -CVi2a Conversion Integer to ASCII -CVi2arg Conversion Integer to ASCII argstring -CVi2az Conversion Integer to ASCII,leading zeroes -CVs2i Conversion String structure to integer -CVx2c Conversion Hex or binary digits to binary -DeleteArgstring Resource Release an argstring structure -DeleteDOSPkt Input/Output Release a DOS Standard Packet -DeleteRexxMsg Resource Release a message packet -DOSRead Input/Output Read from a DOS filehandle -DOSWrite Input/Output Write to a DOS filehandle -ErrorMsg Conversion Get error message from error code -ExistF Input/Output Check whether a DOS file exists -FillRexxMsg Resource Convert and install argstrings -FindDevice Input/Output Locate a DOS device node -FindRsrcNode Resource Locate a resource node -FreePort Resource Close a message port -FreeSpace Resource Release internal memory -GetSpace Resource Allocate internal memory -InitList Resource Initialize a list header -InitPort Resource Initialize a message port -IsRexxMsg Resource Test a message packet -LengthArgstring Resource Get length of argstring -ListNames Resource Copy node names to an argstring -OpenF Input/Output Open a file buffer -OpenPublicPort Resource Allocate and open a port resource node -QueueF Input/Output Queue a line in a file buffer -ReadF Input/Output Read from a file buffer -ReadStr Input/Output Read a string from a file buffer -RemClipNode Resource Release a Clip node -RemRsrcList Resource Release a resource list -RemRsrcNode Resource Release a resource node - - 112 - - TABLE C.1 LIBRARY FUNCTIONS (cont) - -NAME FUNCTIONAL GROUP DESCRIPTION -SeekF Input/Output Reposition a file buffer -StackF Input/Output Stack a line in a file buffer -StcToken String Break out a token -StrcmpN String Compare strings -StrcpyA String Copy a string,converting to ASCII -StrcpyN String Copy a string -StrCpyU String Copy a string,converting to uppercase -StrflipN String Reverse characters in a string -Strlen String Find length of a string -ToUpper Conversion ASCII to uppercase -WriteF Input/Output Write to a file buffer - -C-2 LIBRARY FUNCTIONS -The following descriptions of the ARexx Systems Library functions are listed -alphabetically. The required arguments and register assignments are shown in -parentheses after the function name. Multiple returns are shown in parentheses -on the left-hand side of the call. - -AddClipNode()-allocate and link a Clip node -Usage:node=AddClipNode(list,name,length,value) - D0 A0 A1 D0 D1 - A0 - (CCR) - -Allocates and links a Clip node into the specified list. Clip nodes are -resource nodes containing a name and value string,and include an "auto-delete" -function for simple maintenance. The list argument must point to a properly- -initialized EXEC list header. The name argument points to a null-terminated -name string,the value argument is a pointer to a storage area,and the length -argument is its length in bytes. The returned value is a pointer to the -allocated node,or 0 if the allocation failed. - -The RemClipNode()function is installed as the "auto-delete" function for each -node. Clip nodes can be intermixed with other resource nodes in a list and then -released with a single call to RemRsrcList(). -See Also:RemClipNode(),RemRsrcList(),RemRsrcNode() - -AddRsrcNode()-allocate and link a resource node -Usage:node=AddRsrcNode(list,name,length) - D0 A0 A1 D0 - A0 - (CCR) - -Allocates and links a resource node(a RexxRsrc structure)to the specified list. -The name argument is a pointer to a null-terminated string,a copy of which is -installed in the node structure. The length argument is the total length for -the node;this length is saved within the node so that it may be released later. - - 113 - -The returned value is a pointer to the allocated node,or 0 if the allocation -failed. -See Also:RemRsrcList(),RemRsrcNode() - -ClearMem()-clear a block of memory -Usage:ClearMem(address,length) - A0 D0 - -Clears a block of memory beginning at the given address for the specified -length in bytes. The address must be word-aligned and the length must be a -multiple of 4 bytes;all structures allocated by ARexx meet these restrictions. -Register A0 is preserved. - -ClearRexxMsg()-release argument strings -Usage:ClearRexxMsg(msgptr,count) - A0 D0 - -Releases one or more argstrings from a message packet and clears the -corresponding slots. The count argument specifies the number of argument slots -to clear,and can be set to less than 16 to reserve some to the slots for -private use. No action is taken if the slot already contains a zero value. -See Also:FillRexxMsg() - -CloseF()-close a file buffer -Usage:boolean=CloseF(IoBuff) - D0 A0 - -Release the IoBuff structure and closes the associated DOS file. CloseF()is the -"auto-delete" function for the IoBuff structure,so an entire list of file -buffers can be closed with a single call to RemRsrcList(). - -ClosePublicPort()-close a port resource node -Usage:ClosePublicPort(node) - A0 - -Unlinks and closes the message port and releases the resource node structure. -The node must have been allocated by the OpenPublicPort()function. -See Also:OpenPublicPort() - -CmpString()-compare string structures for equality -Usage:test=CmpString(ss1,ss2) - D0 A0 A1 - (CCR) - -The arguments ss1 and ss2 must be pointers to ARexx string structures and are -compared for equality. String structures include the length and hash code of -the string,so the actual strings are not compared unless the lengths and hash -codes match. The return value sets the CCR and will be -1(True)if the strings -match and 0(False)otherwise. - - 114 - -CreateArgstring()-create an argument string structure -Usage:argstring=CreateArgstring(string,length) - D0 A0 D0 - A0 - (CCR) - -Allocates a RexxArg structure and copies the supplied string into it. The -argstring return is a pointer to the string buffer of the structure,and can be -treated like an ordinary string pointer. The RexxArg structure stores the -structure size and string length at negative offsets to the string pointer. The -string pointer can be set to NULL if only an uninitialized structure is -required. -See Also:DeleteArgstring() - -CreateDOSPkt()-allocate and initialize a DOS standard Packet. -Usage:packet = CreateDOSPkt() - D0 - A0 - (CCR) - -Allocates a DOS StandardPacket structure and initializes it by interlinking the -EXEC message and the DOS packet substructures. No replyport is installed in -either the message or the packet,as these fields are generally filled in just -before the message is sent. -See Also:DeleteDOSPkt() - -CreateRexxMsg()-allocate an ARexx message packet -Usage: msgptr=CreateRexxMsg(replyport,extension,host) - D0 A0 A1 D0 - A0 - (CCR) - -This function allocates an ARexx message packet from the system free memory -list. The message packet consists of a standard EXEC message structure extended -to include space for function arguments,returned results,and internal defaults. -The replyport argument points to a public or private message port and must be -supplied,as it is required to return the message packet to the sender. The -extension and host arguments are pointers to null-terminated strings that -provide values for the default file extension and the initial host address, -respectively. Additional override fields in the extended packet except for the -primary and secondary result fields rm_Result1 and rm_Result2. -See Also: DeleteRexxMsg() - -CVa2i()-convert from ASCII to integer -Usage: (digits,value) = CVa2i(buffer) - D0 D1 A0 - -Converts the buffer of ASCII characters to a signed long integer value. The -scan proceeds until a non-digit character is found or until an overflow is -detected. The function returns both the number of digits scanned and the -converted value. - - 115 - -CVc2x()-convert(unpack)from character string to hex or binary digits. -Usage: error = CVc2x(outbuff,string,length,mode) - D0 A0 A1 D0 D1 - -Converts the signed integer value argument to ASCII characters using the -supplied buffer pointer. The digits argument specifies the maximum number of -characters that will be copied to the buffer. The returned length is the actual -number of characters copied. The pointer return is the new buffer pointer. -See Also: CVi2az() - -CVi2arg()-convert from integer to argstring -Usage: argstring=CVi2arg(value,digits) - D0 D0 D1 - A0 - (CCR) - -Converts the signed long integer value argument to ASCII characters,and -installs them in an argstring(a RexxArg structure). The returned value is an -argstring pointer or 0 if the allocation failed. The allocated structure can be -released using DeleteArgstring(). - -CVi2az()-convert from integer to ASCII with leading zeroes -Usage: (length,pointer)=CVi2az(buffer,value,digits) - D0 A0 A0 D0 D1 - -Converts the signed long integer value argument to ASCII characters in the -supplied buffer,with leading zeroes to fill out the requested number of digits. -This function is identical to CVi2a except that leading zeroes are supplied. -See Also:CVi2a() - -CVs2i()-convert from string structure to integer -Usage: (error,value)=CVs2i(ss) - D0 D1 A0 - -The ss argument must be a pointer to a string structure. It is converted to a -signed long integer value return. The error return code is 47("Arithmetic -conversion error")if the string is not a valid number. - - 116 - -CVx2c()-convert from hex or binary digits to(packed)string -Usage:error=CVx2c(outbuff,string,length,mode) - D0 A0 A1 D0 D1 - -Converts the string argument of hex(0-9,A-F)or binary(0,1)digits to the packed -binary representation. The mode argument specifies the(hex or binary)conversion -mode,and must be set to -1 for hex strings or 0 for binary strings. Blank -characters may be embedded in the string for readability,but only at byte -boundaries. The error return code is 47 if the string is not a valid hex or -binary string. - -CurrentEnv()-return the current storage environment -Usage:envptr=CurrentEnv(rxtptr) - D0 A0 - -Returns a pointer to the current storage environment associated with an -executing ARexx program. The rxptr argument is a pointer to the RexxTask -structure,and may be obtained from the message packet sent to an external -application. - -DeleteArgstring()-delete(release)an argstring structure -Usage:DeleteArgstring(argstring) - A0 - -Releases an argstring (RexxArg) structure. The RexxArg structure contains the -total allocated length at a negative offset from the argstring pointer. -See Also:CreateArgstring() - -DeleteDOSPkt()-release a DOS Standard Packet structure. -Usage:DeleteDOSPkt(message) - A0 - -Releases a DOS StandardPacket structure,typically obtained by a prior call to -CreateDOSPkt(). -See Also:CreateDOSPkt() - -DeleteRexxMsg()-delete(release)an ARexx message packet. -Usage:DeleteRexxMsg(packet) - A0 - -Release an ARexx message packet to the system free-memory list. The internal -MN-LENGTH field is used as the total size of the memory block to be released,so -this function can be used to release any message packet that contains the total -length in this field. Any embedded argument strings must be released before -calling DeleteRexxMsg(). -See Also:CreateRexxMsg() - - 117 - -DOSREAD()-read from a DOS file -Usage:count=DOSRead(filehandle,buffer,length) - D0 A0 A1 D0 - (CCR) - -Reads one or more characters from a DOS filehandle into the supplied buffer. -The length argument specifies the maximum number of characters that will be -read. The returned count is the actual number of bytes transferred,or -1 if an -error occurred. - -DOSWrite()-write to a DOS file -Usage:count=DOSWrite(filehandle,buffer,length) - D0 A0 A1 D0 - (CCR) - -Writes a buffer of the specified length to a DOS filehandle. The retuned count -is the actual number of bytes written,or -1 if an error occurred. - -ErrorMsg()-find the message associated with an error code -Usage:(boolean,ss)=ErrorMsg(code) - D0 A0 D0 - -Returns the error message(as a pointer to a string structure)associated with -the specified ARexx error code. The boolean return will be -1 if the supplied -code was a valid ARexx error code,and 0 otherwise. - -ExistF()-check whether an external file exists -Usage:boolean=ExistF(filename) - D0 A0 - (CCR) - -Tests whether an external file currently exists by attempting to obtain a read -lock on the file. The boolean return indicates whether the operation succeeded, -and the lock is released. - -FillRexxMsg()-convert and install arguments in message packet. -Usage:boolean=FillRexxMsg(msgptr,count,mask) - D0 A0 D0 D1 - -This function can be used to convert and install up to 16 argument strings in a -RexxMsg structure. The message packet must be allocated and the argument fields -of interest set to either a pointer to a null-terminated string or an integer -value. The count argument specifies the number of fields,beginning with ARGO,to -be converted into argstrings and installed into the argument slot. Bits 0-15 of -the mask argument specify whether the corresponding argument is a string -pointer(bit clear)or an integer value(bit set). - - 118 - -The count argument is normally set to the exact number of strings to be passed. -By setting this count to less than 16,a number of the slots can be reserved for -private uses. - -The returned value is -1(True)if all of the arguments were successfully -converted. In the event of an allocation failure,all of the partial results are -released and a value of 0 is returned. -See Also:ClearRexxMsg() - -FindDevice()-check whether a DOS device exists. -Usage:device=FindDevice(devicename,type) - D0 A0 D0 - A0 - (CCR) - -Scans the DOS DeviceList for a device node of the specified type matching the -null-terminated name string. The acceptable values for the type argument are -the constants DLT_DEVICE,DLT_DIRECTORY,or DLT_VOLUME define in the DOS INCLUDE -files. Device names are conveted to uppercase before checking for a match. The -returned value is a pointer to the matched device node,or 0 if the device was -not found. - -FindRsrcNode()-locate a resource node with the given name. -Usage:node=FindRsrcNode(list,name,type) - D0 A0 A1 D0 - A0 - (CCR) - -Searchs the specified list for the first node of the selected type with the -given name. The list argument must be a pointer to a properly-initialized EXEC -list header. The name argument is a pointer to a null-terminated string. If the -type argument is 0,all nodes are selected;otherwise,the supplied type must -match the LN_TYPE field of the node. The returned value is a pointer to the -node or 0 if no matching node was found. - -FreePort()-release resources associated with a message port -Usage:FreePort(port) - A0 - -This function deallocates the signal bit associated with a message port and -marks the port as "closed." The task calling FreePort()must be the same one -that initialized the port,since signal bit allocations are specific to a task. -The memory space associated with the port is not released. -See Also:InitPort() - -FreeSpace()-releases space to the internal memory allocator. -Usage:FreeSpace(envptr,block,length) - A0 A1 D0 - -Returns a block of memory to the internal allocator,which must have been -obtained from a call to GetSpace(). The envptr argument is a pointer to the -base or current storage environment. -See Also:CurrentEnv(),GetSpace() - - 119 - -GetSpace()-allocate memory using the internal allocator. -Usage:block=GetSpace(envptr,length) - D0 A0 D0 - A0 - (CCR) - -Allocates a block of memory using the internal allocator. The memory is -obtained from an internal pool managed by the interpreter and is returned to -the operating system when the ARexx program terminates. The envptr argument is -a pointer to the base or current storage environment for the program. - -The internal allocator must be used to allocate strings for use as values for -symbols,and is convenient for obtaining small blocks of memory whose lifetime -will not exceed that of the ARexx program. -See Also:CurrentEnv(),FreeSpace() - -InitList()-initialize a list header -Usage:InitList(list) - A0 - -Initializes an EXEC list header structure. - -InitPort()-initialize a previously-allocated message port. -Usage:(signal,port)=InitPort(port,name) - D0 A1 A0 A1 - -Initializes a message port structure for which memory space has been previously -allocated,typically as part of a larger structure or as static storage in a -program. It installs the task ID(of the task calling the function)into the -MP_SIGTASK field and allocates a signal bit. The name parameter must be a -pointer to a null-terminated string. The signal return is the signal bit that -was allocated for the port. In the event that a signal could not be assigned,a -value of -1 is returned. - -Note that the port is not linked into the system Ports List. If the port is to -be made public,this can be done after the function returns. The port address is -returned in the correct register(A1)for a subsequent call to the EXEC function -AddPort(). -See Also:FreePort() - -IsRexxMsg()-check whether a message came from ARexx. -Usage:boolean=IsRexxMsg(msgptr) - D0 A0 - -Tests whether the message packet specified by the msgptr argument came from an -ARexx program. ARexx marks its messages with a pointer to a static string -"REXX" in the LN_NAME field. The returned value is either -1(True)if the -message came from ARexx or 0(False)otherwise. - - 120 - -IsSymbol()-check whether a string is a valid symbol. -Usage:(code,length)=IsSymbol(string) - D0 D1 A0 - -Scans the supplied string pointer for ARexx symbol characters. The code return -is the symbol type if a symbol was found,or 0 if the string did not start with -a symbol character. The length return is the total length of the symbol. - -ListNames()-build a string of names from a list. -Usage:argstring=ListNames(list,separator) - D0 A0 D0[0:7] - A0 - (CCR) - -Scans the specified list and copies the name strings into an argstring. The -list argument must be a pointer to an initialized EXEC list header. The -separator argument is the character,possibly a null,to be placed as a delimiter -between the node names. - -The list is traversed inside a Forbid()exclusion and so may be used with shared -or system lists. The returned argstring can be released using DeleteArgstring() -after the names are no longer needed. -See Also:DeleteArgstring() - -LockRexxBase()-lock a shared resource. -Usage:LockRexxBase(resource) - D0 - -Secures the specified resource in the ARexx Systems Library base for read -access. The resource argument is a manifest constant for the required resource, -or zero to lock the entire structure. - -Note that write access to shared resources is normally mediated by the ARexx -resident process,which operates at an elevated priority to gain exclusive -access. Locking a resource should not be attempted from a process operating at -a priority higher than the resident process. -See Also:UnlockRexxBase() - -OpenF()-open a file buffer -Usage:IoBuff=OpenF(list,filename,mode,logical) - D0 A0 A1 D0 D1 - A0 - (CCR) - -Attempts to open an external file in the specified mode,which should be one of -the constants RXIO_READ,RXIO_WRITE,or RXIO_APPEND defined in the ARexx INCLUDE -files. - - 121 - -If successful,an IoBuff structure is allocated and linked into the specified -list. The list argument must be a pointer to a properly-initialized EXEC list -header. - -The optional logical argument is the logical name for the file,and must be -either a pointer to a null-terminated string or zero(NULL)if a name is not -required. -See Also:CloseF() - -OpenPublicPort()-open a public message port -Usage:node=OpenPublicPort(list,name) - D0 A0 A1 - A0 - (CCR) - -Allocates a message port as an "auto-delete" resource node and links it into -the specified list. The list argument must point to a properly initialized EXEC -list header. The message port is initialized with the given name and linked -into the system Ports List. -See Also:ClosePublicPort() - -QueueF()-queue a line to a file buffer. -Usage:count-=QueueF(IoBuff,buffer,length) - D0 A0 A1 D0 - -Queues a buffer of characters in the stream associated with the IoBuff -structure. The stream must be managed by a DOS handler that supports the -ACTION_QUEUE packet. - -Queued lines are placed in "first-in,first-out" order and are immediately -available to be read from the stream. The buffer argument is a pointer to a -string of characters,and the length specifies the number of characters to be -queued. The return value is the actual count of characters or -1 if an error -occurred. -See Also:StackF() - -ReadF()-read characters from a file buffer -Usage:count=ReadF(IoBuff,buffer,length) - D0 A0 A1 D0 - (CCR) - -Reads one or more characters from the file specified by the IoBuff pointer. The -buffer argument is a pointer to a storage area,and the length argument -specifies the maximum number of characters to be read. The return value is the -actual number of characters read,or -1 if an error occurred. - -ReadStr()-read a string from a file -Usage:(count,pointer)=ReadStr(IoBuff,buffer,length) - D0 A1 A0 A1 D0 - -Reads characters from the file specified by the IoBuff pointer until a -"newline" character is found. The "newline" is not included in the returned -string. The return value is the actual number of characters read,or -1 if an -error occurred. - - 122 - -See Also:ReadF() - -RemClipNode()-unlink and deallocate a list Clip node. -Usage:RemClipNode(node) - A0 - -Unlinks and releases the specified Clip node. The function is the "auto-delete" -function for Clip nodes,and will be called automatically by RemRsrcNode() or -RemRsrcList(). -See Also:AddClipNode(),RemRsrcList(),RemRsrcNode() - -RemRsrcList()-unlink and deallocate a list of resource nodes -Usage:RemRsrcList(list) - A0 - -Scans the supplied list and releases any nodes found. The list must consist of -resource nodes(RexxRsrc structures),which contain information to allow -automatic cleanup and deletion. -See Also:RemRsrcNode() - -RemRsrcNode()-unlink and deallocate a resource node -Usage:RemRsrcNode(node) - A0 - -Unlinks and releases the specified resource node,including the name string if -one is present. If an "auto-delete" function has been specified in the node,it -is called to perform any required resource deallocation before the node is -released. -See Also:RemRsrcList() - -SeekF()-seek to the specified position in a file. -Usage:position=SeekF(IoBuff,offset,anchor) - D0 A0 D0 D1 - -Seeks to a new position in the file is specified by the IoBuff pointer. The -position is given by the offset argument,a byte offset relative to the supplied -anchor argument. The anchor may specify the beginning(-1),the current position -(0),or the end of the file(1). The return value is the new position relative to -the beginning of the file. - -StackF()-stack a line to a file buffer. -Usage:count=StackF(IoBuff,buffer,length) - D0 A0 A1 D0 - -Stacks a buffer of characters in the stream associated with the IoBuff -structure. The buffer argument is a pointer to a string of characters,and the -length specifies the number of characters to be stacked. The return value is -the actual count of characters to be stacked. The return value is the actual -count of characters or -1 if an error occurred. - - 123 - -Stacked lines are placed in "last-in,first-out" order and are immediately -available to be read from the stream. The stream must be managed by a DOS -handler that supports the ACTION_STACK packet. -See Also:QueueF() - -StcToken()-break out the next token from a string -Usage:(quote,length,scan,token)=StcToken(string) - D0 D1 A0 A1 A0 - -Scans a null-terminated string to select the next token delimited by "white -space,"and returns a pointer to the start of the token. The quote return will -be an ASCII single or double quote if the token was quoted and 0 otherwise; -white space characters are ignored within quoted strings. The length return is -the total length of the token,including any quote characters. The scan return -is advanced beyond the current token to prepare for the next call. - -StrcpyA()-copy a string,converting to ASCII -Usage:hash=StrcpyA(destination,source,length) - D0 A0 A1 D0 - -Copies the source string to the destination area,converting the characters to -ASCII by clearing the high-order bit of each byte. The length of the string -(which may include embedded nulls)is considered as a 2-byte usingned integer. -So the string is limited in length to 65,535 bytes. The hash return is the -internal hash byte for the copied string. -See Also:StrcpyN(),StrcpyU - -StrcpyN()-copy a string -Usage:hash=StrcpyN(destination,source,length) - D0 A0 A1 D0 - -Copies the source string to the destination area. The length of the string -(which may include embedded nulls)is considered as a 2-byte unsigned integer. -The hash return is the internal hash byte for the copied string. -See Also:StrcpyA(),StrcpyU - -StrcpyU()-copy a string,converting to uppercase -Usage:hash=StrcpyU(destination,source,length) - D0 A0 A1 D0 - -Copies the source string to the destination area,converting to uppercase -alphabetics. The length of the string(which may include embedded nulls)is -considered as a 2-byte unsigned integer. The has return is the internal hash -byte for the copied string. -See Also:StrcpyA(),StrcpyN - - 124 - -StrflipN()-reverse the characters in a string -Usage:StrflipN(string,length) - A0 D0 - -Reverses the sequence of characters in a string. The conversion is performed in -place. - -Strlen()-find the length of a null-terminated string -Usage:length=Strlen(string) - D0 A0 - (CCR) - -Returns the number of characters in a null-terminated string. Register A0 is -preserved,and the CCR is set for the returned length. - -StrcmpN()-compare the values of strings -Usage:test=StrcmpN(string1,string2,length) - D0 A0 A1 D0 - (CCR) - -The string1 and string2 arguments are compared for the specified number of -characters. The comparison proceeds character-by-character until a difference -is found or the maximum number of characters have been examined. The returned -value is -1 if the first string was less,1 if the first string was greater,and -0 if the strings match exactly. The CCR register is set for the returned value. - -ToUpper()-translate an ASCII character to uppercase -Usage:upper=ToUpper(character) - D0 D0 - -Converts an ASCII character to uppercase. Only register D0 is affected. - -UnlockRexxBase()-unlock a shared resource. -Usage:UnlockRexxBase(resource) - D0 - -Releases the specified resource,or all resources if the argument is zero. Every -call to LockRexxBase()should be followed eventually by a call to UnlockRexxBase -()for the same resource. -See Also:LockRexxBaseF() - -WriteF()-write characters to a file buffer -Usage:count=WriteF(IoBuff,buffer,length) - D0 A0 A1 D0 - (CCR) - -Writes a buffer of characters of the specified length to the file associated -with the IoBuff pointer. The buffer argument is a pointer to a storage area, - - 125 - -and the length argument specifies the number of characters to be written. The -returned value is the actual number of characters written or -1 if an error -occurred. -See Also:CloseF(),OpenF(),ReadF() - - 126 - - APPENDIX D THE AREXX SUPPORT LIBRARY - -The ARexx language system is distributed with an external function library that -provides a number of Amiga-specific functions. It is a standard Amiga shared -library named rexxsupport.library and should reside in the system -LIBS:directory. Unlike the Systems Library described in the previous -Appendix,the support library functions are callable from with ARexx programs. - -The support library was designed to supplement the generic Built-In functions -with functions specific to the Amiga. This library will be expanded in future -releases,and users are encouraged to submit suggestions for additional -functions. - -The Support Library must be added to the global Library List before it can be -accessed by ARexx programs. This can be done using the Built-In function -ADDLIB() or by direct communication with the resident process. The library name -must be specified as rexxsupport.library,the query function offset is -30,and -the version number is 0. The search priority can be set to 0 or whatever value -is appropriate. - -ALLOCMEM() -Usage:ALLOCMEM(length,[attribute]) -Allocates a block of memory of the specified length from the system free- -memory pool and returns its address as a 4-byte string. The optional attribute -parameter must be a standard EXEC memory allocation flag,supplied as a 4-byte -string. The default attribute is for "PUBLIC" memory(not cleared). - -This function should be used whenever memory is allocated for use by external -programs. It is the user's responsibility to release the memory space when it -is no longer needed. -See Also:FREEMEM() -Example: - say c2x(allocmem(1000)) ==>00050000 - -CLOSEPORT() -Usage:CLOSEPORT(name) -Closes the message port specified by the name argument,which must have been -allocated by a call to OPENPORT()within the current ARexx program. Any messages -received but not yet REPLYed are automatically returned with the return code -set to 10. -See Also:OPENPORT() -Example: - call closeport myport - - 127 - -FREEMEM() -Usage:FREEMEM(address,length) -Releases a block of memory of the given length to the system freelist. The -address parameter is a four-byte string,typically obtained by a prior call to -ALLOCMEM(). FREEMEM()cannot be used to release memory allocated using -GETSPACE(),the ARexx internal memory allocator. The returned value is a boolean -success flag. -See Also:ALLOCMEM() -Example: - say freemem('00042000'x,32) ==>1 - -GETARG() -Usage:GETARG(packet,[n]) -Extracts a command,function name,or argument string from a message packet. The -packet argument must be a 4-byte address obtained from a prior call to -GETPKT(). The optional n argument specifies the slot containing the string to -be extracted,and must be less than or equal to the actual argument count for -the packet. Commands and functions names are always in slot 0;function packets -may have argument strings in slots 1-15. -Examples: - command = getarg(packet) - function= getarg(packet,0) /* name string */ - arg1 = getarg(packet,1) /* 1st argumeent*/ - -GETPKT() -Usage:GETPKT(name) -Checks the message port specified by the name argument to see whether any -messages are available. The named message port must have been opened by a prior -call to OPENPORT() within the current ARexx program. The returned value is the -4-byte address of the first message packet,or '0000 0000'x if no packets were -available. - -The function returns immediately whether or not a packet is enqueued at the -message port. Programs should never be designed to "busy-loop" on a message -port. If there is no useful work to be done until the next message packet -arrives,the program should call WAITPKT()and allow other tasks to proceed. -See Also:WAITPKT() -Example: - packet = getpkt('MyPort') - -OPENPORT() -Usage:OPENPORT(name) -Creates a public message port with the given name. The returned value is the -4-byte address of the Port Resource strcture or '0000 000'xif the port could -not be opened or initialized. An initialization failure will occur if another -port of the same name already exists,or if a signal bit couldn't be allocated. - - 128 - -The message port is allocated as a Port Resource node and is linked into the -program's global data structure. Ports are automatically closed when the -program exits,and any pending messages are returned to the sender. -See Also:CLOSEPORT() -Example: - myport = openport("MyPort") - -REPLY() -Usage:REPLY(packet,rc) -Returns a message packet to the sender,with the primary result field set to the -value given by the rc argument. The secondary result is cleared. The packet -argument must be supplied as a 4-byte address,and the rc argument must be a -whole number. -Example: - call reply packet,10 /* error return*/ - -SHOWDIR() -Usage:SHOWDIR(directory,['All' | 'File' | 'Dir']) -Returns the contents of the specified directory as a string of names separated -by blanks. The second parameter is an option keyword that selects whether all -entries,only files,or only subdirectories will be included. -Example: - say showdir("df1:c") ==>rx ts te hi tco tcc - -SHOWLIST() -Usage:SHOWLIST[{'D' | 'L' | 'P' | 'R' | 'W' },[name]) -The first argument is an option keyword to select a system list;the options -currently supported are Devices,Libraries,Ports,Ready,and Waiting. If only the -first parameter is supplied,the function scans the selected list and returns -the node names in a string separated by blanks. If the name parameter is -supplied,the boolean return indicates whether the specified list contains a -node of that name. The name matching is case-sensitive. - -The list is scanned with task switching forbidden so as to provide an accurate -snapshot of the list at that time. -Example: - say showlist('P') ==>REXX MyCon - say showlist('P','REXX') ==>1 - - 129 - -STATEF() -Usage:STATEF(filename) -Returns a string containing information about an external file. The string is -formatted as "{DIR | FILE} length blocks protection comment." -The length token gives the file length in bytes,and the block token specifies -the file length in blocks. -Example: - say statef("libs:rexxsupport.library") - /* would give "FILE 1880 4 RWED " */ - -WAITPKT() -Usage:WAITPKT(name) -Waits for a message to be received at the specified(named)port,which must have -been opened by a call to OPENPORT() within the current ARexx program. The -returned boolean value indicates whether a message packet is available at the -port. Normally the returned value will be 1(True),since the function waits -until an event occurs at the message port. - -The packet must then be removed by a call to GETPKT(),and should be returned -eventually using the REPLY()function. Any message packets received but not -returned when an ARexx program exits are automatically REPLYed with the return -code set to 10. -Example: - call waitpkt 'MyPort' /* wait awhile */ - - 130 - - APPENDIX E DISTRIBUTION FILES - -This appendix lists the directores of the standard ARexx distribution disk. The -contents of some of the directories may change from time to time,so your disk -may not show exactly the same files. Most notably,the :rexx directory will -expand as more program examples are included in it. - -The second section of the Appendix lists the HEADER files that define the -constants and data structures used with ARexx. All of these files are available -in the :INCLUDE directory,but are listed here for convenience in studying the -structures. - -E-1 DIRECTORIES - -The files are listed below as they would be using the system dir command. For -example,"dir df1:c opt a" would list the contents of the :c directory on disk -drive 1. - -THE :C DIRECTORY - -This directory contains the command utilities used with ARexx. These files -should be copied to your system C: directory when you install the program. - - c(dir) - hi loadlib - rexxmast rx - rxc rxset - tcc tco - te ts - -THE :INCLUDE DIRECTORY - -This directory has the INCLUDE and HEADER files used for assembly language and -"C" programming,respectively. These files contain the structure definitions -necessary to build an interface to ARexx. - - include(dir) - errors.h rexxio.h - rxslib.h storage.h - errors.i rexxio.i - rxslib.i storage.i - - 131 - -THE :LIBS DIRECTORY - -These are the library files for the language interpreter and the Support -Library functions. Both files should be copied to your system LIBS:directory -when you install ARexx. - - libs(dir) - rexxsupport.library rexxsyslib.library - -THE :REXX DIRECTORY - -The :rexx directory contains example programs to illustrate various features of -the language. New files will be added from time to time,and users are welcome -to contribute files to be distributed in this way. - - rexx(dir) - bigif.rexx break.rexx - builtin.rexx calc.rexx - cmdtest.rexx fact.rexx - factw.rexx haltme.rexx - hosttest.rexx iftest.rexx - marquis.rexx nesttest.rexx - paver.rexx potpourii.rexx - rslib.rexx select.rexx - sigtest.rexx support.rexx - test1.rexx timer.rexx - -THE :TOOLS DIRECTORY - -These files are intended for software developers,and include examples of -interfacing to ARexx. The file rexxtest is of particular interest;it calls the -ARexx interpreter directly,and can be run under a debugger to aid with -developing new function libraries. - - tools(dir) - hosttest hosttest.asm - loadlib.asm rexxtest - rexxtest.asm rxoffsets.o - -Miscellaneous Files - - .info Install-ARexx - README Start-Aexx - - 132 - -E-2 LISTINGS OF HEADER FILES - -This section of the chapter consists of listings of the header files contained -in the :include directory. - -storage.h - -This is the main header file and contains definitions for all of the important -data structures used by ARexx. - -/*===rexx/storage.h================================================= -* -* Copyright (c) 1986,1987 by William S. Hawes (All Rights Reserved) -* -*================================================================== -* Header file to define ARexx data structures. -*/ - -#ifndef REXX_STORAGE_H -#define REXX_STORAGE_H - -#ifndef EXEC_TYPES_H -#include "exec/types.h" -#endif -#ifndef EXEC_NODES_H -#include "exec/nodes.h" -#endif -#ifndef EXEC_LISTS_H -#include "exec/lists.h" -#endif -#ifndef EXEC_PORTS_H -#include "exec/ports.h" -#endif -#ifndef EXEC_LIBRARIES_H -#include "exec/libraries.h" -#endif - -/* The NexxStr structue is used to maintain the internal strings in REXX. - * It includes the buffer area for the string and associated attributes. - * This is actually a variable-length structure;it is allocated for a - * specific length string,and the length is never modified thereafter - * (since it's used for recycling). - */ - - 133 - -storage.h(cont.) - -struct NexxStr{ - LONG ns_Ivalue; /* integer value */ - UWORD ns_Length; /* length in bytes(excl null) */ - UBYTE ns_Flags; /* attribute flags */ - UBYTE ns_Hash; /* hash code */ - BYTE ns_Buff[8]; /* buffer area for strings */ - }; /* size: 16 bytes (minimum) */ - -#define NXADDLEN 9 /* offset plus null byte */ -#define IVALUE(nsPtr) (nsPtr->ns_Ivalue) - -/* String attribute flag bit definitions */ -#define NSB_KEEP 0 /* permanent string? */ -#define NSB_STRING 1 /* string form valid? */ -#define NSB_NOTNUM 2 /* non-numeric? */ -#define NSB_NUMBER 3 /* a valid number? */ -#define NSB_BINARY 4 /* integer value saved? */ -#define NSB_FLOAT 5 /* floating point format? */ -#define NSB_EXT 6 /* an external string? */ -#define NSB_SOURCE 7 /* part of the program source? */ - -/* The flag form of the string attributes */ -#define NSF_KEEP (1<< NSB_KEEP ) */ -#define NSF_STRING (1<< NSB_STRING) -#define NSF_NOTNUM (1<< NSB_NOTNUM) -#define NSF_NUMBER (1<< NSB_NUMBER) -#define NSF_BINARY (1<< NSB_BINARY) -#define NSF_FLOAT (1<< NSB_FLOAT ) -#define NSF_EXT (1<< NSB_EXT ) -#define NSF_SOURCE (1<< NSB_SOURCE) - -* Combinations of flags -#define NSF_INTNUM (NSF_NUMBER | NSF_BINARY | NSF_STRING) -#define NSF_DPNUM (NSF_NUMBER | NSF_FLOAT) -#define NSF_ALPHA (NSF_NOTNUM | NSF_STRING) -#define NSF_OWNED (NSF_SOURCE | NSF_EXT | NSF_KEEP -#define KEEPSTR (NSF_STRING | NSF_SOURCE | NSF_NOTNUM) -#define KEEPNUM (NSF_STRING | NSF_SOURCE | NSF_NUMBER | NSF_BINARY) - - 134 - -storage.h (cont.) - -/* The RexxArg structure is identical to the NexxStr structure,but - * is allocated from system memory rather than from internal storage. - * This structure is used for passing arguments to external programs. - * It is usually passed as an "argstring",a pointer to the string buffer. - */ - -struct RexxArg { - LONG ra_Size; /* total allocated length */ - UWORD ra_Length; /* length of string */ - UBYTE ra_Flags; /* attribute flags */ - UBYTE ra_Hash; /* hash code */ - BYTE ra_Buff[8]; /* buffer area */ - }; /* size: 16 bytes (minimum) */ - -/* The RexxMsg structure is used for all communications with Rexx programs. - * It is an EXEC message with a parameter block appended. - */ -struct RexxMsg{ - struct Message rm_Node; /* EXEC message structure */ - APTR rm_TaskBlock; /* pointer to global structure */ - APTR rm_LibBase; /* library base */ - LONG rm_Action; /* command (action) code */ - LONG rm_Result1; /* primary result (return code) */ - LONG rm_Result2; /* secondary result */ - STRPTR rm_Args[16]; /* argument block(ARGO-ARG15) */ - struct MsgPort *rm_PassPort; /* forwarding port */ - STRPTR rm_CommAddr; /* host address (port name) */ - STRPTR rm_FileExt; /* file extension */ - LONG rm_Stdin; /* input stream(filehandle) */ - LONG rm_Stdout; /* output steam(filehandle) */ - LONG rm_avail; /* future expension */ - }; /* size: 128 bytes */ -/* Field definitions -#define ARGO(rmp) (rmp->rm_Args[0] /* start of argblock */ -#define ARG1(rmp) (rmp->rm_Args[1] /* first argument */ -#define ARG2(rmp) (rmp->rm_Args[2] /* second argument */ - -#define MAXRMARG 15 /* maximum arguments */ - -/* Command (action) codes for message packets */ -#define RXCOMM $01000000 /* a command-level invocation */ -#define RXFUNC $02000000 /* a function call */ -#define RXCLOSE $03000000 /* close the port */ -#define RXQUERY $04000000 /* query for information */ -#define RXADDFH $07000000 /* add a function host */ - - 135 - -storage.h (cont.) - -#define RXADDLIB $08000000 /* add a function library */ -#define RXREMLIB $09000000 /* remove a function library */ -#define RXADDCON $0A000000 /* add/update a ClipList string */ -#define RXREMCON $0B000000 /* remove a ClipList string */ -#define RXTCOPN $0C000000 /* open the trace console */ -#define RXTCCLS $0D000000 /* close the trace console */ - -/* Command modifier flag bits */ -#define RXFB_NOIO 16 /* suppress I/O inheritance? */ -#define RXFB_RESULT 17 /* result string expected? */ -#define RXFB_STRING 18 /* program is a "string file"? */ -#define RXFB_TOKEN 19 /* tokenize the command line? */ -#define RXFB_NONRET 20 /* a "no-return" message? */ - -/* Modifier flags */ -#define RXFF_RESULT (1<< RSFB_RESULT) -#define RXFF_STRING (1<< RXFB_STRING) -#define RXFF_TOKEN (1<< RXFB_TOKEN ) -#define RXFF_NONRET (1<< RXFB_NONRET) -#define RXCODEMASK $FF000000 -#define RXARGMASK $0000000F - -/* The RexxRsrc structure is used to manage global resources. - * The name string for each node is created as a RexxArg structure, - * and the total size of the node is saved in the "rr_Size" field. - * Functions are provided to allocate and release resource nodes. - * If special deletion operations are required,an offset and base can - * be provided in "rr_Func" and "rr_Base",respectively. This function - * will be called with the base in register A6 and the node in A0. -*/ -struct RexxRsrc { - struct Node rr_Node; - WORD rr_Func; /* a "auto-delete" offset */ - APTR rr_Base; /* "auto-delete" base */ - LONG rr_Size; /* total size of node */ - LONG rr_Arg1; /* available ... */ - LONG rr_Arg2; /* available ... */ - }; /* size: 32 bytes */ -/* Resource node types */ -#define RRT_ANY 0 /* any node type ... */ -#define RRT_LIB 1 /* a function library */ -#define RRT_PORT 2 /* a public port */ -#define RRT_FILE 3 /* a file IoBuff */ -#define RRT_HOST 4 /* a function host */ -#define RRT_CLIP 5 /* a Clip List node */ - - 136 - -storage.h (cont.) - -/* The RexxTask structure holds the fields used by REXX to communicate with - * external processes,including the client task. It includes the global - * data structure(and the base environment). The structure is passed to - * the newly-created task in its "wake-up" message. -*/ - -#define GLOBALSZ 200 /* total size of GlobalData */ -struct RexxTask { -BYTE rt_Global[GLOBALSZ]; /* global data structure */ -struct MsgPort rt_MsgPort; /* global message port */ -UBYTE rt_Flags; /* task flag bits */ -BYTE rt_SigBit; /* signal bit */ - -APTR rt_ClientID; /* the client's task ID -APTR rt_MsgPkt; /* the packet being processed -APTR rt_TaskID; /* our task ID -APTR rt_RexxPort; /* the REXX public port - -APTR rt_ErrTrap; /* Error trap address -APTR rt_StackPtr; /* stack pointer for traps - -struct List rt_Header1; /* Environment list */ -struct List rt_Header2; /* Memory freelist */ -struct List rt_Header3; /* Memory allocation list */ -struct List rt_Header4; /* Files list */ -struct List rt_Header5; /* Message Ports List */ -}; - -/* Definitions for RexxTask flag bits -#define RTFB_TRACE 0 /* external trace flag */ -#define RTFB_HALT 1 /* external halt flag */ -#define RTFB_SUSP 2 /* suspend task? */ -#define RTFB_TCUSE 3 /* trace console in use? */ -#define RTFB_WAIT 6 /* waiting for reply? */ -#define RTFB_CLOSE 7 /* task completed? */ - -/* Definitions for memory allocation constants */ -#define MEMQUANT 16 /* quantum of memory space */ -#define MEMMASK $FFFFFFF0 /* mask for rounding the size */ - -#define MEMQUICK (1 << 0 ) /* EXEC flags: MEMF_PUBLIC */ -#define MEMCLEAR (1 << 16) /* EXEC flags: MEMF_CLEAR */ - - 137 - -storage.h (cont.) - -/* The SrcNode is a temporary structure used to hold values destined for a - * segment array. It is also used to maintain the memory freelist. -*/ - -struct SrcNode { -struct SrcNode *sn_Succ; /* next node */ -struct SrcNode *sn_Pred; -APTR sn_Ptr; /* pointer value */ -LONG sn_Size; /* size of object */ -}; /* size: 16 bytes */ -#endif - - 138 - -rxslip.h - -This file defines the library base for the ARexx Systems Library. - -/* === rexx/rxslib.h======================================================== -* -* Copyright (c) 1986,1987 by William S. Hawes (All Rights Reserved) -* -*=========================================================================== -* The header file for the REXX Systems Library -*/ - -#ifndef REXX_RXSLIB_H -#define REXX_RXSLIB_H - -#ifndef REXX_STORAGE_H -#include "rexx/storage.h" -#endif - -/* Some macro definitions */ - -#define RXSNAME "rexxsyslib.library" -#define RXSID "rexxsyslib 1.0 (23 AUG 87)" -#define RXSDIR "REXX" -#define RXSTNAME "ARexx" - -/* The REXX systems library structure. This should be considered */ -/* semi-private and read-only,except for documented exceptions */ - -struct RxsLib { -struct Library rl_Node; /* EXEC library node */ -UBYTE rl_Flags; /* global flags */ -UBYTE rl_pad; -APTR rl_SysBase; /* EXEC library base */ -APTR rl_DOSBase; /* DOS library base */ -APTR rl_IeeeDPBase; /* IEEE DP match library base */ -LONG rl_SegList; /* library seglist */ -LONG rl_MaxAlloc; /* maximum expression allocation*/ -LONG rl_Chunk; /* allocation quantum */ -LONG rl_MaxNest; /* maximum expression nesting */ -struct NexxStr *rl_NULL; /* static string: NULL */ -struct NexxStr *rl_FALSE; /* static string: FALSE */ -struct NexxStr *rl_TRUE; /* static string: TRUE */ -struct NexxStr *rl_REXX; /* static string: REXX */ -struct NexxStr *rl_COMMAND; /* static string: COMMAND -struct NexxStr *rl_STDIN; /* static string: STDIN -struct NexxStr *rl_STDOUT; /* static string: STDOUT -struct NexxStr *rl_STDERR; /* static string: STDERR - - 139 - -rxslib.h (cont.) - -STRPTR rl_Version; /* version/configuration string */ -STRPTR rl_TaskName; /* name string for tasks */ -LONG rl_TaskPri; /* starting prioity */ -LONG rl_TaskSeg; /* startup seglist */ -LONG rl_StackSize; /* stack size */ -STRPTR rl_RexxDir; /* REXX directory */ -STRPTR rl_CTABLE; /* character attribute table */ -struct NexxStr *rl_Notice; /* copyright notice */ - -struct MsgPort rl_RexxPort; /* REXX public port */ -UWORD rl_ReadLock; /* lock count */ -LONG rl_TraceFH; /* global trace console */ -struct List rl_TaskList; /* REXX task list */ -WORD rl_NumTask; /* task count */ -struct List rl_TaskList; /* Library List header */ -WORD rl_NumLib; /* library count */ -struct List rl_ClipList; /* ClipList header */ -WORD rl_NumClip; /* clip node count */ -struct List rl_MsgList; /* pending messages */ -WORD rl_NumMsg; /* pending count */ -}; - -/* Global flag bit definitions for RexxMaster */ -#define RLFB_TRACE RTFB_TRACE /* interactive tracing? */ -#define RLFB_HALT RTFB_HALT /* halt execution? */ -#define RLFB_SUSP RTFB_SUSP /* suspend execution? */ -#define RLFB_TCUSE RTFB_TCUSE /* trace console in use? */ -#define RLFB_TCOPN 4 /* trace console open? */ -#define RLFB_STOP 6 /* deny further invocations */ -#define RLFB_CLOSE 7 /* close the master */ - -#define RLFMASK 0x07 /* passed flags */ - - ; Initialization constants - -#define RXSVERS 2 /* main version */ -#define RXSREV 1 /* revision */ -#define RXSALLOC 0x800000 /* maximum allocation */ -#define RXSCHUNK 1024 /* allocation quantum */ -#define RXSNEST 32 /* expression nesting limit */ -#define RXSTPRI 0 /* task priority */ -#define RXSSTACK 4096 /* stack size */ -#define RXSLISTH 4 /* number of list headers */ - - 140 - -rxslib.h (cont.) - -/* Character attribute flag bits used in REXX. Defined only for */ -/* ASCII characters (range 0-127) */ - -#define CTB_SPACE 0 /* white space characters */ -#define CTB_DIGIT 1 /* decimal digits 0-9 */ -#define CTB_ALPHA 2 /* alphabetic characters */ -#define CTB_REXXSYM 3 /* REXX symbol characters */ -#define CTB_REXXOPR 4 /* REXX operator characters */ -#define CTB_REXXSPC 5 /* REXX special symbols */ -#define CTB_UPPER 6 /* UPPERCASE alphabetic */ -#define CTB_LOWER 7 /* lowercase alphabetic */ - -/* Attribute flags */ -#define CTF_SPACE (1 << CTB_SPACE) -#define CTF_DIGIT (1 << CTB_DIGIT) -#define CTF_ALPHA (1 << CTB_ALPHA) -#define CTF_REXXASYM (1 << CTB_REXXSYM) -#define CTF_REXXOPR (1 << CTB_REXXOPR) -#define CTF_REXXSPC (1 << CTB_REXXSPC) -#define CTF_UPPER (1 << CTB_UPPER) -#define CTF_LOWER (1 << CTB_LOWER) - -#endif - - 141 - -rexxio.h - -This file defines the data structures used for buffered I/O. ARexx uses linked -lists of IoBuff structures to keep track of the files it opens. Each IoBuff -node is allocated as an "auto-delete" structure and can be closed and released -by a call to either CloseF() or RemRsrcNode(). An entire list of files can be -closed with a call to RemRsrcList(). - -/* ===rexx/rexxio.h======================================================== - * - * Copyright (c) 1986,1987 by William S. Hawes (All Rights Reserved) - * - *========================================================================= - * Header file for ARexx Input/Output related structures -*/ - -#ifndef REXX_REXXIO_H -#define REXX_REXXIO_H - -#ifndef REXX_STORAGE_H -#include "rexx/storage.h" -#endif - -#define RXBUFFSZ 204 /* buffeg length */ - -/* The IoBuff is a resource node used to maintain the File List. Nodes are - * allocated and linked into the list whenever a file is opened. -*/ - -struct IoBuff{ -struct RexxRsrc iobNode; /* structure for files/strings */ -APTR iobRpt; /* read/write pointer */ -LONG iobRct; /* character count */ -LONG iobDFH; /* DOS filehandle */ -APTR iobLock; /* DOS lock */ -LONG iobBct; /* buffer length */ -BYTE iobArea[RXBUFFSZ]; /* buffer area */ -}; /* size: 256 bytes */ - -/* Access mode definitions */ -#define RXIO_EXIST -1 /* an external filehandle */ -#define RXIO_STRF 0 /* a "string file" */ -#define RXIO_READ 1 /* read-only access */ -#define RXIO_WRITE 2 /* write mode */ -#define RXIO_APPEND 3 /* append mode (existing file) */ - - 142 - -rxxio.h (cont.) - -/* Offset anchors for SeekF() */ -#define RXIO_BEGIN -1 /* relative to start */ -#define RXIO_CURR 0 /* relative to current position */ -#define RXIO_END 1 /* relative to end */ - -/* The Library List contains just plain resource nodes */ - -#define LLOFFSET(rrp) (rrp>rr_Arg1) /* "Query" offset */ -#define LLVERS(rrp) (rrp->Arg2) /* library version */ - -/* The RexxClipNode structure is used to maintain the Clip List. The - * The ReplyList holds packets that have been received but haven't been -* replied. -*/ - -struct RexxMsgPort{ -struct RexxRsrc rmp_Node; /* linkage node */ -struct MsgPort rmp_Port; /* the message port */ -struct List rmp_ReplyList; /* messages awaiting reply */ -}; - -/* DOS Device types */ -#define DT_DEV 0 /* a device */ -#define DT_DIR 1 /* an ASSIGNed directory */ -#define DT_VOL 2 /* a volume */ - -/* Private DOS packet types */ -#define ACTION_STACK 2002 /* stack a line */ -#define ACTION_QUEUE 2003 /* queue a line */ -#endif - - 143 - -errors. h - -This file contains the definitions for all of the error messages issued by the -ARexx interpreter. - -/* == errors.h================================================================ - * - * Copyright (c) 1987 by Williams S. Hawes (All Rights Reserved) - * - * =========================================================================== - * Definitions for ARexx error codes -*/ - -#define EERC_MSG 0 /* error code offset */ -#define ERR10_001 (ERRC_MSG+1) /* program not found */ -#define ERR10_002 (ERRC_MSG+2) /* execution halted */ -#define ERR10_003 (ERRC_MSG+3) /* no memory available */ -#define ERR10_004 (ERRC_MSG+4) /* invalid character in program */ -#define ERR10_005 (ERRC_MSG+5) /* unmatched quote */ -#define ERR10_006 (ERRC_MSG+6) /* unterminated comment */ -#define ERR10_007 (ERRC_MSG+7) /* clause too long */ -#define ERR10_008 (ERRC_MSG+8) /* unrecognized token */ -#define ERR10_009 (ERRC_MSG+9) /* symbol or string too long */ - -#define ERR10_010 (ERRC_MSG+10) /* invalid message packet */ -#define ERR10_011 (ERRC_MSG+11) /* command string error */ -#define ERR10_012 (ERRC_MSG+12) /* error return from function */ -#define ERR10_013 (ERRC_MSG+13) /* host environment not found */ -#define ERR10_014 (ERRC_MSG+14) /* required library not found */ -#define ERR10_015 (ERRC_MSG+15) /* function not found */ -#define ERR10_016 (ERRC_MSG+16) /* no return value */ -#define ERR10_017 (ERRC_MSG+17) /* wrong number of arguments */ -#define ERR10_018 (ERRC_MSG+18) /* invalid argument to function */ -#define ERR10_019 (ERRC_MSG+19) /* invalid PROCEDURE */ - -#define ERR10_020 (ERRC_MSG+20) /* unexpected THEN/ELSE */ -#define ERR10_021 (ERRC_MSG+21) /* unexpected WHEN/OTHERWISE */ -#define ERR10_022 (ERRC_MSG+22) /* unexpected LEAVE or ITERATE */ -#define ERR10_023 (ERRC_MSG+23) /* invalid statement in SELECT */ -#define ERR10_024 (ERRC_MSG+24) /* missing THEN clauses */ -#define ERR10_025 (ERRC_MSG+25) /* missing OTHERWISE */ -#define ERR10_026 (ERRC_MSG+26) /* missing or unexpected END */ -#define ERR10_027 (ERRC_MSG+27) /* symbol mismatch on END */ -#define ERR10_028 (ERRC_MSG+28) /* invalid DO syntax */ -#define ERR10_029 (ERRC_MSG+29) /* incomplete DO/IF/SELECT */ - - 144 - -errors.h (cont.) - -#define ERR10_030 (ERRC_MSG+30) /* label not found */ -#define ERR10_031 (ERRC_MSG+31) /* symbol expected */ -#define ERR10_032 (ERRC_MSG+32) /* string or symbol expected */ -#define ERR10_033 (ERRC_MSG+33) /* invalid sub-keyword */ -#define ERR10_034 (ERRC_MSG+34) /* required keyword missing */ -#define ERR10_035 (ERRC_MSG+35) /* extraneous characters */ -#define ERR10_036 (ERRC_MSG+36) /* sub-keyword conflict */ -#define ERR10_037 (ERRC_MSG+37) /* invalid template */ -#define ERR10_038 (ERRC_MSG+38) /* invalid TRACE request */ -#define ERR10_039 (ERRC_MSG+39) /* uninitialized variable */ - -#define ERR10_040 (ERRC_MSG+40) /* invalid variable name */ -#define ERR10_041 (ERRC_MSG+41) /* invalid expression */ -#define ERR10_042 (ERRC_MSG+42) /* unbalanced parentheses */ -#define ERR10_043 (ERRC_MSG+43) /* nesting level exceeded */ -#define ERR10_044 (ERRC_MSG+44) /* invalid expression result */ -#define ERR10_045 (ERRC_MSG+45) /* expression required */ -#define ERR10_046 (ERRC_MSG+46) /* boolean value not 0 or 1 */ -#define ERR10_047 (ERRC_MSG+47) /* arithmetic conversion error */ -#define ERR10_048 (ERRC_MSG+48) /* invalid operand */ - -/* Return Codes for general use ... */ -#define RC_FAIL -1 /* something's wrong */ -#define RC_OK 0 /* success */ -#define RC_WARN 5 /* warning only */ -#define RC_ERROR 10 /* something's wrong */ -#define RC_FATAL 20 /* complete or severe failure */ - - 145 - - GLOSSARY - -ALLOCATION. A grant of a system resource,such as memory space. Programs -designed to run in a multitasking environment generally use dynamic allocation -to avoid tying up system resources. - -AMIGADOS. The higher-level part of the Amiga operating system that supports the -filing system and input/output operations. - -ARGSTRING. An "argument string" structure used to pass data to an ARexx -program. The structure is passed as a pointer to the buffer area containing the -string data,and can be treated as a pointer to a null-terminated string. - -ARGUMENT. A data item passed to a function,sometimes called a parameter. - -CLAUSE. A group of one or more tokens forming a "sentence" in a language. The -clause is the smallest executable language fragment. - -COMMAND LINE INTERFACE (CLI). A program that accepts input from the user and -runs programs based on the entered command. The CLI generally refers to the -command interpreter supplied with the Amiga,but other command "shells" may be -used instead. - -CONCATENATION. An operation in which two strings are joined or "chained -together." ARexx provides two concatenation operators,one of which joins -strings directly and the other of which embeds a blank between the operands. - -EXEC. The multitasking kernel of the Amiga's operating system. EXEC provides -the task scheduling,interrupt handlin,and message-passing primitives used to -support ARexx. - -FUNCTION HOST. A program that manages a public message port for receiving -function invocation messages. The message port may be the same one used for -command messages. - -FUNCTION LIBRARY. A collection of functions callable from ARexx and managed as -an Amiga shared library. Each function library includes an entry point to -associate a function name with the code to be called. - -HOST ADDRESS. The name of the public message port associated with a host -application. The host address is used as the unique identifier for the host,and -should be unique within the system message ports list. Within an ARexx program -the host address identifies the external host to which commands will be sent. - - 147 - -HOST APPLICATION. An executable program that program that provides a suitable -command interface to receive ARexx commands. Most host applications will also -provide a means to invoke macro programs from within the application. - -INTERRUPT. An event that alters the normal flow of control in a program. -Interrupts in ARexx refer to events within the program execution and are -distinct from the hardware-level interrupts managed by the Amiga EXEC system. - -MACRO PROGRAM. A program that implements a complex "macro" operation from a -series of "micro" commands. - -MESSAGE PACKET. A data structure used to pass information between tasks. A -message packet is allocated and initialized by one task and then sent to -another task's message port. After the recipient has processed the message,it -"replies" the message to the replyport associated with the message. - -MESSAGE PORT. A data structure used as the rendezvous point for message -passing. A message port provides the anchor for a list of message packets and -identifies the task to be signalled when a message arrives. - -MULTITASKING. The ability to run more than one program at a time. More -precisely, multitasking permits the resources of the computer to be shared -among many tasks without forcing any task to be aware of the others. - -PROCESS. An extension to an EXEC task structure that provides the data fields -required to use AmigaDOS functions. All ARexx programs run as AmigaDOS -processes. - -REPLYPORT. A message port designated to receive a returning message packet. -Each message packet includes a field that specifies its reply port. - -RESIDENT PROCESS. The program responsible for launching ARexx programs and for -managing various resources used by ARexx. It is structured as a host -application and opens a public message port named "REXX." - -SHARED LIBRARY. A collection of executable code and data managed as a resource -by the EXEC operating system. As the name "shared" implies, the code and data -in a library can be used by more than one task. - -STORAGE ENVIRONMENT. The collection of data values forming the current state -of an ARexx program. Storage environments are strictly nested and only one -environment is current at any time. - -TASK. An entity consisting of executable code and a data structure managed by -the EXEC operating system. The task is the smallest program unit that can be -scheduled and run separately. - - 148 - -TOKEN. The elementary words or atoms of a language. A token can be considered -as a string of one or more characters forming the smallest unit of the -language. - -TYPELESS. Data items having no assumed structure or usage. ARexx treats all -data as typeless character strings and checks for specific characteristics only -when required by an operation. - - 149 - -AREXX DOCS BROUGHT TO USE BY THE SOUTHERN STAR WILL ASSISTANCE BY RAP.....