Document revision date: 19 July 1999 | |
Order Number: AA-QSBJC-TE
This manual explains the features of the OpenVMS Debugger for programmers in high-level languages and assembly language.
Revision/Update Information: This manual supersedes the OpenVMS Debugger Manual, Version 7.1.
Software Version: OpenVMS Alpha Version 7.2 OpenVMS VAX Version 7.2
Compaq Computer Corporation
Houston, Texas
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ZK4538
The OpenVMS documentation set is available on CD-ROM.
This document was prepared using VAX DOCUMENT, Version V3.2n.
Contents | Index |
This manual is for programmers at all levels of experience. It covers all user interfaces of the OpenVMS Debugger:
On VAX processors, you can use the debugger with programs written in the following VAX languages:
Ada | BASIC | BLISS | C |
C++ | COBOL | DIBOL | Fortran |
MACRO-32 | Pascal | PL/I | RPG II |
SCAN |
On Alpha processors, you can use the debugger with programs written in the following DEC languages:
Ada | BASIC | BLISS | C |
C++ | COBOL | Fortran | MACRO-32 1 |
MACRO-64 | Pascal | PL/I |
The OpenVMS Debugger on OpenVMS Alpha systems can access all the extended memory made available by the 64-bit processing of the OpenVMS Alpha operating system. Hence, you can examine and manipulate data in the complete 64-bit address space.
The OpenVMS Debugger has been internationalized. For Asian users, the debugger's DECwindows Motif, command line, and screen mode interfaces can be used with multibyte characters.
You can use the debugger to debug code only in user mode. You cannot debug code in supervisor, executive, or kernel modes.
This manual is organized as follows:
The following documents may also be helpful when using the debugger.
This manual emphasizes debugger usage that is common to all or most supported languages. For more information specific to a particular language, see:
For information about the linking of programs or shareable images, see the OpenVMS Linker Utility Manual.
For information about debugging code in supervisor, executive, or kernel modes (that is, in other than user mode), see the OpenVMS Delta/XDelta Debugger Manual in the OpenVMS documentation set. This manual contains information about debugging programs that run in privileged processor mode or at an elevated interrupt priority level.
OpenVMS Alpha System-Code Debugger (Alpha Only)
On Alpha processors, see the OpenVMS Alpha Device Support: Developer's Guide for information on debugging Alpha operating system code. This manual describes how to create an Alpha device driver, activate the OpenVMS Alpha System-Code Debugger through the OpenVMS Debugger, and debug within the OpenVMS Alpha System-Code Debugger environment.
For information on the OpenVMS Alpha System-Code Debugger-specific commands, see the CONNECT and REBOOT commands in Part 6.
For general information about the DECwindows Motif interface, see the VMS DECwindows User's Guide.
For additional information on the Open Systems Software Group (OSSG) products and services, access the following OpenVMS World Wide Web address:
http://www.openvms.digital.com |
Compaq welcomes your comments on this manual.
Print or edit the online form SYS$HELP:OPENVMSDOC_COMMENTS.TXT and send us your comments by:
Internet | openvmsdoc@zko.mts.dec.com |
Fax | 603 884-0120, Attention: OSSG Documentation, ZKO3-4/U08 |
Compaq Computer Corporation
OSSG Documentation Group, ZKO3-4/U08 110 Spit Brook Rd. Nashua, NH 03062-2698 |
Use the following World Wide Web address to order additional documentation:
http://www.openvms.digital.com:81/ |
If you need help deciding which documentation best meets your needs, call 800-DIGITAL (800-344-4825).
VMScluster systems are now referred to as OpenVMS Cluster systems. Unless otherwise specified, references to OpenVMS Clusters or clusters in this document are synonymous with VMSclusters.
In this manual, every use of DECwindows and DECwindows Motif refers to DECwindows Motif for OpenVMS software.
This manual contains many figures showing the DECwindows Motif interface to the debugger. Because the display configuration of this interface is customizable, these figures may not exactly picture the appearance of debugger displays on your system.
The examples in this manual have not been updated to reflect the fact that the OpenVMS Debugger on OpenVMS Alpha systems can access all the extended memory made available by the 64-bit processing of the OpenVMS Alpha operating system. You should note that hexadecimal addresses are 16-digit numbers on Alpha and 8-digit numbers on VAX. For example,
DBG> EVALUATE/ADDRESS/HEX %hex 000004A0 00000000000004A0 DBG> |
The following conventions are also used in this manual:
Ctrl/ x | A sequence such as Ctrl/ x indicates that you must hold down the key labeled Ctrl while you press another key or a pointing device button. |
PF1
x or
GOLD x |
A sequence such as PF1
x or GOLD
x indicates that you must first press and release the key
labeled PF1 or GOLD and then press and release another key or a
pointing device button.
GOLD key sequences can also have a slash (/), (-), or underscore (_) as a delimiter in EVE commands. |
[Return] |
In examples, a key name enclosed in a box indicates that you press a
key on the keyboard. (In text, a key name is not enclosed in a box.)
In the HTML version of this document, this convention appears as brackets, rather than a box. |
... |
A horizontal ellipsis in examples indicates one of the following
possibilities:
|
.
. . |
A vertical ellipsis indicates the omission of items from a code example or command format; the items are omitted because they are not important to the topic being discussed. |
( ) | In command format descriptions, parentheses indicate that you must enclose the options in parentheses if you choose more than one. |
[ ] | In command format descriptions, brackets indicate optional elements. You can choose one, none, or all of the options. (Brackets are not optional, however, in the syntax of a directory name in an OpenVMS file specification or in the syntax of a substring specification in an assignment statement.) |
[|] | In command format descriptions, vertical bars separating items inside brackets indicate that you choose one, none, or more than one of the options. |
{ } | In command format descriptions, braces indicate required elements; you must choose one of the options listed. |
bold text | This text style represents the introduction of a new term or the name of an argument, an attribute, or a reason. |
italic text | Italic text indicates important information, complete titles of manuals, or variables. Variables include information that varies in system output (Internal error number), in command lines (/PRODUCER= name), and in command parameters in text (where dd represents the predefined code for the device type). |
UPPERCASE TEXT | Uppercase text indicates a command, the name of a routine, the name of a file, or the abbreviation for a system privilege. |
Monospace text |
Monospace type indicates code examples and interactive screen displays.
In the C programming language, monospace type in text identifies the following elements: keywords, the names of independently compiled external functions and files, syntax summaries, and references to variables or identifiers introduced in an example. |
- | A hyphen at the end of a command format description, command line, or code line indicates that the command or statement continues on the following line. |
numbers | All numbers in text are assumed to be decimal unless otherwise noted. Nondecimal radixes---binary, octal, or hexadecimal---are explicitly indicated. |
This chapter briefly describes the command interface of the OpenVMS Debugger, and provides the following information:
For a tutorial introduction to basic debugging tasks, see Chapter 2.
1.1 Overview of the Debugger
The OpenVMS Debugger is a tool to locate run-time programming or logic errors, also known as bugs, in a program that has been compiled and linked successfully but does not run correctly. For example, the program might give incorrect output, go into an infinite loop, or terminate prematurely.
By using the OpenVMS Debugger, you can locate program bugs by observing and manipulating the program interactively as it executes. Debugger commands enable you to:
These are basic debugging techniques. After locating program errors, you can edit the source code and compile, link, execute, and test the corrected version.
As you use the debugger and its documentation, you will discover and develop variations on the basic techniques. You can also customize the debugger for your own needs. Section 1.1.1 summarizes the features of the OpenVMS Debugger.
On VAX processors, you can use the debugger with programs written in the following VAX languages:
Ada | BASIC | BLISS | C |
C++ | COBOL | DIBOL | Fortran |
MACRO-32 | Pascal | PL/I | RPG II |
SCAN |
On Alpha processors, you can use the debugger with programs written in the following DEC languages:
Ada | BASIC | BLISS | C |
C++ | COBOL | Fortran | MACRO-32 1 |
MACRO-64 | Pascal | PL/I |
The debugger recognizes the syntax, data types, operators, expressions, scoping rules, and other constructs of a supported language. You can change the debugging context from one language to another (with the SET LANGUAGE command) during a debugging session.
The debugger is a symbolic debugger. You can refer to program locations by the symbols used in your program---the names of variables, routines, labels, and so on. You can also specify explicit memory addresses or machine registers if you choose.
The debugger recognizes the data types generated by the compilers of all supported languages, such as integer, floating-point, enumeration, record, array, and so on, and displays the values of each program variable according to its declared type.
With the debugger, you can enter and display a variety of data forms and data types. The source language of the program determines the default format for the entry and display of data. However, you can select other formats as needed.
Starting or Resuming Program Execution
Once the program is under control of the debugger, you can start or resume program execution with the GO or STEP commands. The GO command causes the program to execute until specified events occur (the PC points to a designated line of code, a variable is modified, an exception is signaled, or the program terminates). You can use the STEP command to execute a specified number instructions or lines of source code, or until the program reaches the next instruction of a specified class.
You can set a breakpoint with the SET BREAK command, to suspend program execution at a specified location in order to check the current status of the program. You can also direct the debugger to suspend execution when the program is about to execute an instruction of a specific class. You can also suspend execution when certain events occur, such as exceptions and tasking (multithread) events.
You can set a tracepoint with the SET TRACE command, to cause the debugger to report each time that program execution reaches a specified location (that is, each time the program counter (PC) references that location). As with the SET BREAK command, you can also trace the occurrence of classes of instructions and monitor the occurrence of certain events, such as exceptions and tasking (multithread) events.
You can set a watchpoint with the SET WATCH command to cause the debugger to suspend program execution whenever a particular variable (or other specified memory location) has been modified, at which point the debugger reports the old and new values of the variable.
Manipulation of Variables and Program Locations
You can use the EXAMINE command to determine the value of a variable or memory location. You can use the DEPOSIT command to change that value. You can then continue execution of the program to determine the effect of the change without having to recompile, relink, and rerun the program.
You can use the EVALUATE command to compute the value of a source-language expression or an address expression in the syntax of the language to which the debugger is currently set.
You can use logical control structures (FOR, IF, REPEAT, WHILE) in commands to control the execution of other commands.
You can debug shareable images (images that are not directly executable). The SET IMAGE command enables you to access the symbols declared in a shareable image (that was compiled and linked with the /DEBUG qualifiers).
You can debug multiprocess programs (programs that run in more than one process). The SHOW PROCESS and SET PROCESS commands enable you to display process information and to control the execution of images in individual processes.
You can debug tasking programs (also known as multithread programs). These programs use DECthreads or POSIX 1003.1b services, or use language-specific tasking services (for example, Ada tasking programs). The SHOW TASK and SET TASK commands enable you to display task information and to control the execution of individual tasks.
On VAX processors, you can debug vectorized programs, that is, programs that use VAX vector instructions. You can control and monitor execution at the vector instruction level, examine and deposit vector instructions, manipulate the contents of vector registers, use a mask to display specific vector elements, and control synchronization between the scalar and vector processors.
Terminal and Workstation Support
The debugger supports all VT-series terminals and MicroVAX workstations.
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