878 lines
30 KiB
Text
878 lines
30 KiB
Text
\input texinfo @c -*-texinfo-*-
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@c %**start of header
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@setfilename libgdb.info
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@settitle Libgdb
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@setchapternewpage off
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@c %**end of header
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@ifinfo
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This file documents libgdb, the GNU symbolic debugger in a library.
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This is Edition 0.3, Oct 1993, of @cite{Libgdb}.
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Copyright 1993 Cygnus Support
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Permission is granted to make and distribute verbatim copies of
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this manual provided the copyright notice and this permission notice
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are preserved on all copies.
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@ignore
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Permission is granted to process this file through TeX and print the
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results, provided the printed document carries copying permission
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notice identical to this one except for the removal of this paragraph
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(this paragraph not being relevant to the printed manual).
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@end ignore
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Permission is granted to copy and distribute modified versions of this
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manual under the conditions for verbatim copying, provided also that the
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entire resulting derived work is distributed under the terms of a
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permission notice identical to this one.
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Permission is granted to copy and distribute translations of this manual
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into another language, under the above conditions for modified versions.
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@end ifinfo
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@c This title page illustrates only one of the
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@c two methods of forming a title page.
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@titlepage
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@title Libgdb
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@subtitle Version 0.3
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@subtitle Oct 1993
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@author Thomas Lord
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@c The following two commands
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@c start the copyright page.
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@page
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@vskip 0pt plus 1filll
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Permission is granted to make and distribute verbatim copies of
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this manual provided the copyright notice and this permission notice
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are preserved on all copies.
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Copyright @copyright{} 1993 Cygnus Support
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@end titlepage
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@ifinfo
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@node Top, Overview, (dir), (dir)
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This info file documents libgdb: an API for GDB, the GNU symbolic debugger.
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@menu
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* Overview:: The basics of libgdb and this document.
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* Interpreter:: Libgdb is an Interpreter-Based Server.
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* Top Level:: You Provide the Top Level for the Libgdb
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Command Interpreter .
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* I/O:: How the Server's I/O Can be Used.
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* Invoking:: Invoking the Interpreter, Executing
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Commands.
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* Defining Commands:: How New Commands are Created.
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* Variables:: How Builtin Variables are Defined.
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* Asynchronous:: Scheduling Asynchronous Computations.
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* Commands:: Debugger Commands for Libgdb Applications
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@end menu
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@end ifinfo
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@node Overview, Interpreter, top, top
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@comment node-name, next, previous, up
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@chapter Overview
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@cindex overview
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@cindex definitions
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@heading Function and Purpose
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Libgdb is a package which provides an API to the functionality of GDB,
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the GNU symbolic debugger. It is specifically intended to support the
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development of a symbolic debugger with a graphic interface.
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@heading This Document
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This document is a specification of the libgdb API. It is written in
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the form of a programmer's manual. So the goal of this document is to
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explain what functions make up the API, and how they can be used in a
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running application.
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@heading Terminology
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In this document, @dfn{libgdb} refers to a library containing the
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functions defined herein, @dfn{application} refers to any program built
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with that library.
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@heading Dependencies
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Programs which are linked with libgdb must be linked with libbfd,
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libopcodes, libiberty, and libmmalloc.
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@heading Acknowledgments
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Essential contributions to this design were made by Stu Grossman, Jim
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Kingdon, and Rich Pixley.
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@node Interpreter, Top Level, Overview, Top
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@comment node-name, next, previous, up
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@chapter Libgdb is an Interpreter Based Server
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@cindex interpreter
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@cindex server
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To understand libgdb, it is necessary to understand how the library is
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structured. Historically, GDB is written as a small interpreter for a
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simple command language. The commands of the language perform useful
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debugging functions.
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Libgdb is built from GDB by turning the interpreter into a debugging
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server. The server reads debugging commands from any source and
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interprets them, directing the output arbitrarily.
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In addition to changing GDB from a tty-based program to a server, a
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number of new GDB commands have been added to make the server more
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useful for a program with a graphic interface.
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Finally, libgdb includes provisions for asynchronous processing within
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the application.
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Most operations that can be carried out with libgdb involve the GDB
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command interpreter. The usual mode of operation is that the operation
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is expressed as a string of GDB commands, which the interpreter is then
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invoked to carry out. The output from commands executed in this manner
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can be redirected in a variety of useful ways for further processing by
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the application.
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The command interpreter provides an extensive system of hooks so an
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application can monitor any aspect of the debugging library's state. An
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application can set its own breakpoints and attach commands and
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conditions to those. It is possible to attach hooks to any debugger
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command; the hooks are invoked whenever that command is about to be
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invoked. By means of these, the displays of a graphical interface can
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be kept fully up to date at all times.
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We show you how to define new primitives in the command language. By
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defining new primitives and using them in breakpoint scripts and command
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hooks, an application can schedule the execution of arbitrary C-code at
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almost any point of interest in the operation of libgdb.
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We show you how to define new GDB convenience variables for which your
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code computes a value on demand. Referring to such variables in a
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breakpoint condition is a convenient way to conditionalize breakpoints
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in novel ways.
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To summarize: in libgdb, the gdb command language is turned into a
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debugging server. The server takes commands as input, and the server's
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output is redirectable. An application uses libgdb by formatting
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debugging commands and invoking the interpreter. The application might
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maintain breakpoints, watchpoints and many kinds of hooks. An application
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can define new primitives for the interpreter.
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@node Top Level, I/O, Interpreter, Top
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@chapter You Provide the Top Level for the Libgdb Command Interpreter
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@cindex {top level}
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When you use libgdb, your code is providing a @dfn{top level} for the
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command language interpreter. The top level is significant because it
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provides commands for the the interpreter to execute. In addition, the
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top level is responsible for handling some kinds of errors, and
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performing certain cleanup operations on behalf of the interpreter.
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@heading Initialization
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Before calling any other libgdb functions, call this:
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@deftypefun void gdb_init (void)
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Perform one-time initialization for libgdb.
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@end deftypefun
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An application may wish to evaluate specific gdb commands as part of its
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own initialization. The details of how this can be accomplished are
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explained below.
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@heading The Top-Level Loop
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There is a strong presumption in libgdb that the application has
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the form of a loop. Here is what such a loop might look like:
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@example
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while (gdb_still_going ())
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@{
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if (!GDB_TOP_LEVEL ())
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@{
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char * command;
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gdb_start_top_loop ();
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command = process_events ();
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gdb_execute_command (command);
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gdb_finish_top_loop ();
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@}
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@}
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@end example
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The function @code{gdb_still_going} returns 1 until the gdb command
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`quit' is run.
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The macro @code{GDB_TOP_LEVEL} invokes setjmp to set the top level error
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handler. When a command results in an error, the interpreter exits with
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a longjmp. There is nothing special libgdb requires of the top level
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error handler other than it be present and that it restart the top level
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loop. Errors are explained in detail in a later chapter.
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Each time through the top level loop two important things happen: a
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debugger command is constructed on the basis of user input, and the
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interpreter is invoked to execute that command. In the sample code, the
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call to the imaginary function @code{process_events} represents the
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point at which a graphical interface should read input events until
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ready to execute a debugger command. The call to
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@code{gdb_execute_command} invokes the command interpreter (what happens
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to the output from the command will be explained later).
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Libgdb manages some resources using the top-level loop. The primary
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reason for this is error-handling: even if a command terminates with an
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error, it may already have allocated resources which need to be freed.
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The freeing of such resources takes place at the top-level, regardless
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of how the the command exits. The calls to @code{gdb_start_top_loop}
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and @code{gdb_finish_top_loop} let libgdb know when it is safe to
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perform operations associated with these resources.
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@heading Breakpoint Commands
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Breakpoint commands are scripts of GDB operations associated with
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particular breakpoints. When a breakpoint is reached, its associated
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commands are executed.
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Breakpoint commands are invoked by the libgdb function
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@code{gdb_finish_top_loop}.
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Notice that if control returns to the top-level error handler, the
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execution of breakpoint commands is bypassed. This can happen as a
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result of errors during either @code{gdb_execute_command} or
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@code{gdb_finish_top_loop}.
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@heading Application Initialization
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Sometimes it is inconvenient to execute commands via a command loop for
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example, the commands an application uses to initialize itself. An
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alternative to @code{execute_command} is @code{execute_catching_errors}.
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When @code{execute_catching_errors} is used, no top level error handler
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need be in effect, and it is not necessary to call
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@code{gdb_start_top_loop} or @code{gdb_finish_top_loop}.
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@heading Cleanup
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The debugger command ``quit'' performs all necessary cleanup for libgdb.
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After it has done so, it changes the return value of
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@code{gdb_still_going} to 0 and returns to the top level error handler.
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@node I/O, Invoking, Top Level, Top
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@comment node-name, next, previous, up
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@chapter How the Server's I/O Can be Used
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@cindex I/O
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In the last chapter it was pointed out that a libgdb application is
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responsible for providing commands for the interpreter to execute.
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However some commands require further input (for example, the ``quit''
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command might ask for confirmation). Almost all commands produce output
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of some kind. The purpose of this section is to explain how libgdb
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performs its I/O, and how an application can take advantage of
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this.
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@heading I/O Vectors
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Libgdb has no fixed strategy for I/O. Instead, all operations are
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performed by functions called via structures of function pointers.
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Applications supply theses structures and can change them at any
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time.
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@deftp Type {struct gdb_input_vector}
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@deftpx Type {struct gdb_output_vector}
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These structures contain a set of function pointers. Each function
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determines how a particular type of i/o is performed. The details of
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these strucutres are explained below.
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The application allocates these structures, initializes them to all bits
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zero, fills in the function pointers, and then registers names for them
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them with libgdb.
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@end deftp
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@deftypefun void gdb_name_input_vector (@var{name}, @var{vec})
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@deftypefunx void gdb_remove_input_vector (@var{name}, @var{vec})
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@deftypefunx void gdb_name_output_vector (@var{name}, @var{vec})
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@deftypefunx void gdb_remove_input_vector (@var{name}, @var{vec})
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@example
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char * @var{name};
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struct gdb_output_vector * @var{vec};
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@end example
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These functions are used to give and remove names to i/o vectors. Note
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that if a name is used twice, the most recent definition applies.
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@end deftypefun
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@subheading Output
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An output vector is a structure with at least these fields:
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@example
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struct gdb_output_vector
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@{
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/* output */
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void (*put_string) (struct gdb_output_vector *, char * str);
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@}
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@end example
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Use the function @code{memset} or something equivalent to initialize an
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output vector to all bits zero. Then fill in the function pointer with
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your function.
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A debugger command can produce three kinds of output: error messages
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(such as when trying to delete a non-existent breakpoint), informational
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messages (such as the notification printed when a breakpoint is hit),
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and the output specifically requested by a command (for example, the
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value printed by the ``print'' command). At any given time, then,
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libgdb has three output vectors. These are called the @dfn{error},
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@dfn{info}, @dfn{value} vector respectively.
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@subheading Input
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@example
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struct gdb_input_vector
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@{
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int (*query) (struct gdb_input_vector *,
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char * prompt,
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int quit_allowed);
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int * (*selection) (struct gdb_input_vector *,
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char * prompt,
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char ** choices);
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char * (*read_string) (struct gdb_input_vector *,
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char * prompt);
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char ** (*read_strings) (struct gdb_input_vector *,
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char * prompt);
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@}
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@end example
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Use the function @code{memset} or something equivalent to initialize an
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input vector to all bits zero. Then fill in the function pointers with
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your functions.
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There are four kinds of input requests explicitly made by libgdb.
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A @dfn{query} is a yes or no question. The user can respond to a query
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with an affirmative or negative answer, or by telling gdb to abort the
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command (in some cases an abort is not permitted). Query should return
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'y' or 'n' or 0 to abort.
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A @dfn{selection} is a list of options from which the user selects a subset.
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Selections should return a NULL terminated array of integers, which are
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indexes into the array of choices. It can return NULL instead to abort
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the command. The array returned by this function will be passed to
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@code{free} by libgdb.
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A @dfn{read_string} asks the user to supply an arbitrary string. It may
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return NULL to abort the command. The string returned by @code{read_string}
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should be allocated by @code{malloc}; it will be freed by libgdb.
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A @dfn{read_strings} asks the user to supply multiple lines of input
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(for example, the body of a command created using `define'). It, too,
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may return NULL to abort. The array and the strings returned by this
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function will be freed by libgdb.
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@heading I/O Redirection from the Application Top-Level
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@deftypefun struct gdb_io_vecs gdb_set_io (struct gdb_io_vecs *)
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@example
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struct gdb_io_vecs
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@{
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struct gdb_input_vector * input;
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struct gdb_output_vector * error;
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struct gdb_output_vector * info;
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struct gdb_output_vector * value;
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@}
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@end example
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This establishes a new set of i/o vectors, and returns the old setting.
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Any of the pointers in this structure may be NULL, indicating that the
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current value should be used.
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This function is useful for setting up i/o vectors before any libgdb
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commands have been invoked (hence before any input or output has taken
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place).
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@end deftypefun
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It is explained in a later chapter how to redirect output temporarily.
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(@xref{Invoking}.)
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@heading I/O Redirection in Debugger Commands
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A libgdb application creates input and output vectors and assigns them names.
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Which input and output vectors are used by libgdb is established by
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executing these debugger commands:
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@defun {set input-vector} name
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@defunx {set error-output-vector} name
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@defunx {set info-output-vector} name
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@defunx {set value-output-vector} name
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Choose an I/O vector by name.
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@end defun
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A few debugger commands are for use only within commands defined using
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the debugger command `define' (they have no effect at other times).
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These commands exist so that an application can maintain hooks which
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redirect output without affecting the global I/O vectors.
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@defun with-input-vector name
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@defunx with-error-output-vector name
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@defunx with-info-output-vector name
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@defunx with-value-output-vector name
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Set an I/O vector, but only temporarily. The setting has effect only
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within the command definition in which it occurs.
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@end defun
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@heading Initial Conditions
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When libgdb is initialized, a set of default I/O vectors is put in
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place. The default vectors are called @code{default-input-vector},
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@code{default-output-vector}, &c.
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The default query function always returns `y'. Other input functions
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always abort. The default output functions discard output silently.
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@node Invoking, Defining Commands, I/O, Top
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@chapter Invoking the Interpreter, Executing Commands
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@cindex {executing commands}
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@cindex {invoking the interpreter}
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This section introduces the libgdb functions which invoke the command
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interpreter.
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@deftypefun void gdb_execute_command (@var{command})
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@example
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char * @var{command};
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@end example
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Interpret the argument debugger command. An error handler must be set
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when this function is called. (@xref{Top Level}.)
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@end deftypefun
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It is possible to override the current I/O vectors for the duration of a
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single command:
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@deftypefun void gdb_execute_with_io (@var{command}, @var{vecs})
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@example
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char * @var{command};
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struct gdb_io_vecs * @var{vecs};
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struct gdb_io_vecs
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@{
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struct gdb_input_vector * input;
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struct gdb_output_vector * error;
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struct gdb_output_vector * info;
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struct gdb_output_vector * value;
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@}
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@end example
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Execute @var{command}, temporarily using the i/o vectors in @var{vecs}.
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Any of the vectors may be NULL, indicating that the current value should
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be used. An error handler must be in place when this function is used.
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@end deftypefun
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@deftypefun {struct gdb_str_output} gdb_execute_for_strings (@var{cmd})
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@example
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char * cmd;
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@end example
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@deftypefunx {struct gdb_str_output} gdb_execute_for_strings2 (@var{cmd}, @var{input})
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@example
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char * cmd;
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struct gdb_input_vector * input;
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@end example
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@page
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@example
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struct gdb_str_output
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@{
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char * error;
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char * info;
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char * value;
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@};
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@end example
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Execute @var{cmd}, collecting its output as strings. If no error
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occurs, all three strings will be present in the structure, the
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empty-string rather than NULL standing for no output of a particular
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kind.
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If the command aborts with an error, then the @code{value} field will be
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NULL, though the other two strings will be present.
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In all cases, the strings returned are allocated by malloc and should be
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freed by the caller.
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The first form listed uses the current input vector, but overrides the
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current output vector. The second form additionally allows the input
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vector to be overridden.
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This function does not require that an error handler be installed.
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@end deftypefun
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@deftypefun void execute_catching_errors (@var{command})
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@example
|
|
char * @var{command};
|
|
@end example
|
|
Like @code{execute_command} except that no error handler is required.
|
|
@end deftypefun
|
|
|
|
@deftypefun void execute_with_text (@var{command}, @var{text})
|
|
@example
|
|
char * @var{command};
|
|
char ** @var{text};
|
|
@end example
|
|
Like @code{execute_catching_errors}, except that the input vector is
|
|
overridden. The new input vector handles only calls to @code{query} (by
|
|
returning 'y') and calls to @code{read_strings} by returning a copy of
|
|
@var{text} and the strings it points to.
|
|
|
|
This form of execute_command is useful for commands like @code{define},
|
|
@code{document}, and @code{commands}.
|
|
@end deftypefun
|
|
|
|
|
|
|
|
@node Defining Commands, Variables, Invoking, Top
|
|
@comment node-name, next, previous, up
|
|
@chapter How New Commands are Created
|
|
@cindex {commands, defining}
|
|
|
|
Applications are, of course, free to take advantage of the existing GDB
|
|
macro definition capability (the @code{define} and @code{document}
|
|
functions).
|
|
|
|
In addition, an application can add new primitives to the GDB command
|
|
language.
|
|
|
|
@deftypefun void gdb_define_app_command (@var{name}, @var{fn}, @var{doc})
|
|
@example
|
|
char * @var{name};
|
|
gdb_cmd_fn @var{fn};
|
|
char * @var{doc};
|
|
|
|
typedef void (*gdb_cmd_fn) (char * args);
|
|
@end example
|
|
|
|
Create a new command call @var{name}. The new command is in the
|
|
@code{application} help class. When invoked, the command-line arguments
|
|
to the command are passed as a single string.
|
|
|
|
Calling this function twice with the same name replaces an earlier
|
|
definition, but application commands can not replace builtin commands of
|
|
the same name.
|
|
|
|
The documentation string of the command is set to a copy the string
|
|
@var{doc}.
|
|
@end deftypefun
|
|
|
|
@node Variables, Asynchronous, Defining Commands, Top
|
|
@comment node-name, next, previous, up
|
|
@chapter How Builtin Variables are Defined
|
|
@cindex {variables, defining}
|
|
|
|
Convenience variables provide a way for values maintained by libgdb to
|
|
be referenced in expressions (e.g. @code{$bpnum}). Libgdb includes a
|
|
means by which the application can define new, integer valued
|
|
convenience variables:
|
|
@page
|
|
@deftypefun void gdb_define_int_var (@var{name}, @var{fn}, @var{fn_arg})
|
|
@example
|
|
char * @var{name};
|
|
int (*@var{fn}) (void *);
|
|
void * @var{fn_arg};
|
|
@end example
|
|
This function defines (or undefines) a convenience variable called @var{name}.
|
|
If @var{fn} is NULL, the variable becomes undefined. Otherwise,
|
|
@var{fn} is a function which, when passed @var{fn_arg} returns the value
|
|
of the newly defined variable.
|
|
|
|
No libgdb functions should be called by @var{fn}.
|
|
@end deftypefun
|
|
|
|
One use for this function is to create breakpoint conditions computed in
|
|
novel ways. This is done by defining a convenience variable and
|
|
referring to that variable in a breakpoint condition expression.
|
|
|
|
|
|
@node Asynchronous, Commands, Variables, Top
|
|
@chapter Scheduling Asynchronous Computations
|
|
@cindex asynchronous
|
|
|
|
|
|
A running libgdb function can take a long time. Libgdb includes a hook
|
|
so that an application can run intermittently during long debugger
|
|
operations.
|
|
|
|
@deftypefun void gdb_set_poll_fn (@var{fn}, @var{fn_arg})
|
|
@example
|
|
void (*@var{fn})(void * fn_arg, int (*gdb_poll)());
|
|
void * @var{fn_arg};
|
|
@end example
|
|
Arrange to call @var{fn} periodically during lengthy debugger operations.
|
|
If @var{fn} is NULL, polling is turned off. @var{fn} should take two
|
|
arguments: an opaque pointer passed as @var{fn_arg} to
|
|
@code{gdb_set_poll_fn}, and a function pointer. The function pointer
|
|
passed to @var{fn} is provided by libgdb and points to a function that
|
|
returns 0 when the poll function should return. That is, when
|
|
@code{(*gdb_poll)()} returns 0, libgdb is ready to continue @var{fn}
|
|
should return quickly.
|
|
|
|
It is possible that @code{(*gdb_poll)()} will return 0 the first time it
|
|
is called, so it is reasonable for an application to do minimal processing
|
|
before checking whether to return.
|
|
|
|
No libgdb functions should be called from an application's poll function,
|
|
with one exception: @code{gdb_request_quit}.
|
|
@end deftypefun
|
|
|
|
|
|
@deftypefun void gdb_request_quit (void)
|
|
This function, if called from a poll function, requests that the
|
|
currently executing libgdb command be interrupted as soon as possible,
|
|
and that control be returned to the top-level via an error.
|
|
|
|
The quit is not immediate. It will not occur until at least after the
|
|
application's poll function returns.
|
|
@end deftypefun
|
|
|
|
@node Commands, Top, Asynchronous, Top
|
|
@comment node-name, next, previous, up
|
|
@chapter Debugger Commands for Libgdb Applications
|
|
|
|
The debugger commands available to libgdb applications are the same commands
|
|
available interactively via GDB. This section is an overview of the
|
|
commands newly created as part of libgdb.
|
|
|
|
This section is not by any means a complete reference to the GDB command
|
|
language. See the GDB manual for such a reference.
|
|
|
|
@menu
|
|
* Command Hooks:: Setting Hooks to Execute With Debugger Commands.
|
|
* View Commands:: View Commands Mirror Show Commands
|
|
* Breakpoints:: The Application Can Have Its Own Breakpoints
|
|
@end menu
|
|
|
|
@node Command Hooks, View Commands, Commands, Commands
|
|
@comment node-name, next, previous, up
|
|
@section Setting Hooks to Execute With Debugger Commands.
|
|
|
|
Debugger commands support hooks. A command hook is executed just before
|
|
the interpreter invokes the hooked command.
|
|
|
|
There are two hooks allowed for every command. By convention, one hook
|
|
is for use by users, the other is for use by the application.
|
|
|
|
A user hook is created for a command XYZZY by using
|
|
@code{define-command} to create a command called @code{hook-XYZZY}.
|
|
|
|
An application hook is created for a command XYZZY by using
|
|
@code{define-command} to create a command called @code{apphook-XYZZY}.
|
|
|
|
Application hooks are useful for interfaces which wish to continuously
|
|
monitor certain aspects of debugger state. The application can set a
|
|
hook on all commands that might modify the watched state. When the hook
|
|
is executed, it can use i/o redirection to notify parts of the
|
|
application that previous data may be out of date. After the top-level loop
|
|
resumes, the application can recompute any values that may have changed.
|
|
(@xref{I/O}.)
|
|
|
|
@node View Commands, Breakpoints, Command Hooks, Commands
|
|
@comment node-name, next, previous, up
|
|
@section View Commands Mirror Show Commands
|
|
|
|
The GDB command language contains many @code{set} and @code{show}
|
|
commands. These commands are used to modify or examine parameters to
|
|
the debugger.
|
|
|
|
It is difficult to get the current state of a parameter from the
|
|
@code{show} command because @code{show} is very verbose.
|
|
|
|
@example
|
|
(gdb) show check type
|
|
Type checking is "auto; currently off".
|
|
(gdb) show width
|
|
Number of characters gdb thinks are in a line is 80.
|
|
@end example
|
|
|
|
For every @code{show} command, libgdb includes a @code{view} command.
|
|
@code{view} is like @code{show} without the verbose commentary:
|
|
|
|
@example
|
|
(gdb) view check type
|
|
auto; currently off
|
|
(gdb) view width
|
|
80
|
|
@end example
|
|
|
|
(The precise format of the ouput from @code{view} is subject to change.
|
|
In particular, @code{view} may one-day print values which can be used as
|
|
arguments to the corresponding @code{set} command.)
|
|
|
|
@node Breakpoints, Structured Output, View Commands, Commands
|
|
@comment node-name, next, previous, up
|
|
@section The Application Can Have Its Own Breakpoints
|
|
|
|
The GDB breakpoint commands were written with a strong presumption that
|
|
all breakpoints are managed by a human user. Therefore, the command
|
|
language contains commands like `delete' which affect all breakpoints
|
|
without discrimination.
|
|
|
|
In libgdb, there is added support for breakpoints and watchpoints which
|
|
are set by the application and which should not be affected by ordinary,
|
|
indiscriminate commands. These are called @dfn{protected} breakpoints.
|
|
|
|
@deffn {Debugger Command} break-protected ...
|
|
@deffnx {Debugger Command} watch-protected ...
|
|
These work like @code{break} and @code{watch} except that the resulting
|
|
breakpoint is given a negative number. Negative numbered breakpoints do
|
|
not appear in the output of @code{info breakpoints} but do in that of
|
|
@code{info all-breakpoints}. Negative numbered breakpoints are not
|
|
affected by commands which ordinarily affect `all' breakpoints (e.g.
|
|
@code{delete} with no arguments).
|
|
|
|
Note that libgdb itself creates protected breakpoints, so programs
|
|
should not rely on being able to allocate particular protected
|
|
breakpoint numbers for themselves.
|
|
@end deffn
|
|
|
|
More than one breakpoint may be set at a given location. Libgdb adds
|
|
the concept of @dfn{priority} to breakpoints. A priority is an integer,
|
|
assigned to each breakpoint. When a breakpoint is reached, the
|
|
conditions of all breakpoints at the same location are evaluated in
|
|
order of ascending priority. When breakpoint commands are executed,
|
|
they are also executed in ascending priority (until all have been
|
|
executed, an error occurs, or one set of commands continues the
|
|
target).
|
|
|
|
@deffn {Debugger Command} priority n bplist
|
|
Set the priority for breakpoints @var{bplist} to @var{n}.
|
|
By default, breakpoints are assigned a priority of zero.
|
|
@end deffn
|
|
|
|
@node Structured Output, Commands, Breakpoints, Commands
|
|
@comment node-name, next, previous, up
|
|
@section Structured Output, The @code{Explain} Command
|
|
|
|
(This section may be subject to considerable revision.)
|
|
|
|
When GDB prints a the value of an expression, the printed representation
|
|
contains information that can be usefully fed back into future commands
|
|
and expressions. For example,
|
|
|
|
@example
|
|
(gdb) print foo
|
|
$16 = @{v = 0x38ae0, v_length = 40@}
|
|
@end example
|
|
|
|
On the basis of this output, a user knows, for example, that
|
|
@code{$16.v} refers to a pointer valued @code{0x38ae0}
|
|
|
|
A new output command helps to make information like this available to
|
|
the application.
|
|
|
|
@deffn {Debugger Command} explain expression
|
|
@deffnx {Debugger Command} explain /format expression
|
|
Print the value of @var{expression} in the manner of the @code{print}
|
|
command, but embed that output in a list syntax containing information
|
|
about the structure of the output.
|
|
@end deffn
|
|
|
|
As an example, @code{explain argv} might produce this output:
|
|
|
|
@example
|
|
(exp-attribute
|
|
((expression "$19")
|
|
(type "char **")
|
|
(address "48560")
|
|
(deref-expression "*$19"))
|
|
"$19 = 0x3800\n")
|
|
@end example
|
|
|
|
The syntax of output from @code{explain} is:
|
|
|
|
@example
|
|
<explanation> := <quoted-string>
|
|
| (exp-concat <explanation> <explanation>*)
|
|
| (exp-attribute <property-list> <explanation>)
|
|
|
|
<property-list> := ( <property-pair>* )
|
|
|
|
<property-pair> := ( <property-name> <quoted-string> )
|
|
@end example
|
|
|
|
The string-concatenation of all of the @code{<quoted-string>} (except
|
|
those in property lists) yields the output generated by the equivalent
|
|
@code{print} command. Quoted strings may contain quotes and backslashes
|
|
if they are escaped by backslash. "\n" in a quoted string stands for
|
|
newline; unescaped newlines do not occur within the strings output by
|
|
@code{explain}.
|
|
|
|
Property names are made up of alphabetic characters, dashes, and
|
|
underscores.
|
|
|
|
The set of properties is open-ended. As GDB acquires support for new
|
|
source languages and other new capabilities, new property types may be
|
|
added to the output of this command. Future commands may offer
|
|
applications some selectivity concerning which properties are reported.
|
|
|
|
The initial set of properties defined includes:
|
|
|
|
@itemize @bullet
|
|
@item @code{expression}
|
|
|
|
This is an expression, such as @code{$42} or @code{$42.x}. The
|
|
expression can be used to refer to the value printed in the attributed
|
|
part of the string.
|
|
|
|
@item @code{type}
|
|
|
|
This is a user-readable name for the type of the attributed value.
|
|
|
|
@item @code{address}
|
|
|
|
If the value is stored in a target register, this is a register number.
|
|
If the value is stored in a GDB convenience variable, this is an integer
|
|
that is unique among all the convenience variables. Otherwise, this is
|
|
the address in the target where the value is stored.
|
|
|
|
@item @code{deref-expression}
|
|
|
|
If the attributed value is a pointer type, this is an expression that
|
|
refers to the dereferenced value.
|
|
@end itemize
|
|
|
|
Here is a larger example, using the same object passed to @code{print}
|
|
in an earlier example of this section.
|
|
|
|
@example
|
|
(gdb) explain foo
|
|
(exp-attribute
|
|
( (expression "$16")
|
|
(type "struct bytecode_vector")
|
|
(address 14336) )
|
|
(exp-concat
|
|
"$16 = @{"
|
|
(exp-attribute
|
|
( (expression "$16.v")
|
|
(type "char *")
|
|
(address 14336)
|
|
(deref-expression "*$16.v") )
|
|
"v = 0x38ae0")
|
|
(exp-attribute
|
|
( (expression "$16.v_length")
|
|
(type "int")
|
|
(address 14340) )
|
|
", v_length = 40")
|
|
"@}\n"))
|
|
@end example
|
|
|
|
It is undefined how libgdb will indent these lines of output or
|
|
where newlines will be included.
|
|
|
|
@bye
|