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This is gdbint.info, produced by makeinfo version 4.0 from
./gdbint.texinfo.

INFO-DIR-SECTION Programming & development tools.
START-INFO-DIR-ENTRY
START-INFO-DIR-ENTRY
* Gdb-Internals: (gdbint).      The GNU debugger's internals.
END-INFO-DIR-ENTRY
END-INFO-DIR-ENTRY

   This file documents the internals of the GNU debugger GDB.
Copyright 1990,1991,1992,1993,1994,1996,1998,1999,2000,2001    Free
Software Foundation, Inc.  Contributed by Cygnus Solutions.  Written by
John Gilmore.  Second Edition by Stan Shebs.

   Permission is granted to copy, distribute and/or modify this document
under the terms of the GNU Free Documentation License, Version 1.1 or
any later version published by the Free Software Foundation; with the
Invariant Sections being "Algorithms" and "Porting GDB", with the
Front-Cover texts being "A GNU Manual," and with the Back-Cover Texts
as in (a) below.

   (a) The FSF's Back-Cover Text is: "You have freedom to copy and
modify this GNU Manual, like GNU software.  Copies published by the Free
Software Foundation raise funds for GNU development."


File: gdbint.info,  Node: Target Vector Definition,  Next: Native Debugging,  Prev: Target Architecture Definition,  Up: Top

Target Vector Definition
************************

   The target vector defines the interface between GDB's abstract
handling of target systems, and the nitty-gritty code that actually
exercises control over a process or a serial port.  GDB includes some
30-40 different target vectors; however, each configuration of GDB
includes only a few of them.

File Targets
============

   Both executables and core files have target vectors.

Standard Protocol and Remote Stubs
==================================

   GDB's file `remote.c' talks a serial protocol to code that runs in
the target system.  GDB provides several sample "stubs" that can be
integrated into target programs or operating systems for this purpose;
they are named `*-stub.c'.

   The GDB user's manual describes how to put such a stub into your
target code.  What follows is a discussion of integrating the SPARC
stub into a complicated operating system (rather than a simple
program), by Stu Grossman, the author of this stub.

   The trap handling code in the stub assumes the following upon entry
to `trap_low':

  1. %l1 and %l2 contain pc and npc respectively at the time of the
     trap;

  2. traps are disabled;

  3. you are in the correct trap window.

   As long as your trap handler can guarantee those conditions, then
there is no reason why you shouldn't be able to "share" traps with the
stub.  The stub has no requirement that it be jumped to directly from
the hardware trap vector.  That is why it calls `exceptionHandler()',
which is provided by the external environment.  For instance, this could
set up the hardware traps to actually execute code which calls the stub
first, and then transfers to its own trap handler.

   For the most point, there probably won't be much of an issue with
"sharing" traps, as the traps we use are usually not used by the kernel,
and often indicate unrecoverable error conditions.  Anyway, this is all
controlled by a table, and is trivial to modify.  The most important
trap for us is for `ta 1'.  Without that, we can't single step or do
breakpoints.  Everything else is unnecessary for the proper operation
of the debugger/stub.

   From reading the stub, it's probably not obvious how breakpoints
work.  They are simply done by deposit/examine operations from GDB.

ROM Monitor Interface
=====================

Custom Protocols
================

Transport Layer
===============

Builtin Simulator
=================


File: gdbint.info,  Node: Native Debugging,  Next: Support Libraries,  Prev: Target Vector Definition,  Up: Top

Native Debugging
****************

   Several files control GDB's configuration for native support:

`gdb/config/ARCH/XYZ.mh'
     Specifies Makefile fragments needed when hosting _or native_ on
     machine XYZ.  In particular, this lists the required
     native-dependent object files, by defining `NATDEPFILES=...'.
     Also specifies the header file which describes native support on
     XYZ, by defining `NAT_FILE= nm-XYZ.h'.  You can also define
     `NAT_CFLAGS', `NAT_ADD_FILES', `NAT_CLIBS', `NAT_CDEPS', etc.; see
     `Makefile.in'.

`gdb/config/ARCH/nm-XYZ.h'
     (`nm.h' is a link to this file, created by `configure').  Contains
     C macro definitions describing the native system environment, such
     as child process control and core file support.

`gdb/XYZ-nat.c'
     Contains any miscellaneous C code required for this native support
     of this machine.  On some machines it doesn't exist at all.

   There are some "generic" versions of routines that can be used by
various systems.  These can be customized in various ways by macros
defined in your `nm-XYZ.h' file.  If these routines work for the XYZ
host, you can just include the generic file's name (with `.o', not
`.c') in `NATDEPFILES'.

   Otherwise, if your machine needs custom support routines, you will
need to write routines that perform the same functions as the generic
file.  Put them into `XYZ-nat.c', and put `XYZ-nat.o' into
`NATDEPFILES'.

`inftarg.c'
     This contains the _target_ops vector_ that supports Unix child
     processes on systems which use ptrace and wait to control the
     child.

`procfs.c'
     This contains the _target_ops vector_ that supports Unix child
     processes on systems which use /proc to control the child.

`fork-child.c'
     This does the low-level grunge that uses Unix system calls to do a
     "fork and exec" to start up a child process.

`infptrace.c'
     This is the low level interface to inferior processes for systems
     using the Unix `ptrace' call in a vanilla way.

Native core file Support
========================

`core-aout.c::fetch_core_registers()'
     Support for reading registers out of a core file.  This routine
     calls `register_addr()', see below.  Now that BFD is used to read
     core files, virtually all machines should use `core-aout.c', and
     should just provide `fetch_core_registers' in `XYZ-nat.c' (or
     `REGISTER_U_ADDR' in `nm-XYZ.h').

`core-aout.c::register_addr()'
     If your `nm-XYZ.h' file defines the macro `REGISTER_U_ADDR(addr,
     blockend, regno)', it should be defined to set `addr' to the
     offset within the `user' struct of GDB register number `regno'.
     `blockend' is the offset within the "upage" of `u.u_ar0'.  If
     `REGISTER_U_ADDR' is defined, `core-aout.c' will define the
     `register_addr()' function and use the macro in it.  If you do not
     define `REGISTER_U_ADDR', but you are using the standard
     `fetch_core_registers()', you will need to define your own version
     of `register_addr()', put it into your `XYZ-nat.c' file, and be
     sure `XYZ-nat.o' is in the `NATDEPFILES' list.  If you have your
     own `fetch_core_registers()', you may not need a separate
     `register_addr()'.  Many custom `fetch_core_registers()'
     implementations simply locate the registers themselves.

   When making GDB run native on a new operating system, to make it
possible to debug core files, you will need to either write specific
code for parsing your OS's core files, or customize `bfd/trad-core.c'.
First, use whatever `#include' files your machine uses to define the
struct of registers that is accessible (possibly in the u-area) in a
core file (rather than `machine/reg.h'), and an include file that
defines whatever header exists on a core file (e.g. the u-area or a
`struct core').  Then modify `trad_unix_core_file_p' to use these
values to set up the section information for the data segment, stack
segment, any other segments in the core file (perhaps shared library
contents or control information), "registers" segment, and if there are
two discontiguous sets of registers (e.g.  integer and float), the
"reg2" segment.  This section information basically delimits areas in
the core file in a standard way, which the section-reading routines in
BFD know how to seek around in.

   Then back in GDB, you need a matching routine called
`fetch_core_registers'.  If you can use the generic one, it's in
`core-aout.c'; if not, it's in your `XYZ-nat.c' file.  It will be
passed a char pointer to the entire "registers" segment, its length,
and a zero; or a char pointer to the entire "regs2" segment, its
length, and a 2.  The routine should suck out the supplied register
values and install them into GDB's "registers" array.

   If your system uses `/proc' to control processes, and uses ELF
format core files, then you may be able to use the same routines for
reading the registers out of processes and out of core files.

ptrace
======

/proc
=====

win32
=====

shared libraries
================

Native Conditionals
===================

   When GDB is configured and compiled, various macros are defined or
left undefined, to control compilation when the host and target systems
are the same.  These macros should be defined (or left undefined) in
`nm-SYSTEM.h'.

`ATTACH_DETACH'
     If defined, then GDB will include support for the `attach' and
     `detach' commands.

`CHILD_PREPARE_TO_STORE'
     If the machine stores all registers at once in the child process,
     then define this to ensure that all values are correct.  This
     usually entails a read from the child.

     [Note that this is incorrectly defined in `xm-SYSTEM.h' files
     currently.]

`FETCH_INFERIOR_REGISTERS'
     Define this if the native-dependent code will provide its own
     routines `fetch_inferior_registers' and `store_inferior_registers'
     in `HOST-nat.c'.  If this symbol is _not_ defined, and
     `infptrace.c' is included in this configuration, the default
     routines in `infptrace.c' are used for these functions.

`FILES_INFO_HOOK'
     (Only defined for Convex.)

`FP0_REGNUM'
     This macro is normally defined to be the number of the first
     floating point register, if the machine has such registers.  As
     such, it would appear only in target-specific code.  However,
     `/proc' support uses this to decide whether floats are in use on
     this target.

`GET_LONGJMP_TARGET'
     For most machines, this is a target-dependent parameter.  On the
     DECstation and the Iris, this is a native-dependent parameter,
     since `setjmp.h' is needed to define it.

     This macro determines the target PC address that `longjmp' will
     jump to, assuming that we have just stopped at a longjmp
     breakpoint.  It takes a `CORE_ADDR *' as argument, and stores the
     target PC value through this pointer.  It examines the current
     state of the machine as needed.

`I386_USE_GENERIC_WATCHPOINTS'
     An x86-based machine can define this to use the generic x86
     watchpoint support; see *Note I386_USE_GENERIC_WATCHPOINTS:
     Algorithms.

`KERNEL_U_ADDR'
     Define this to the address of the `u' structure (the "user
     struct", also known as the "u-page") in kernel virtual memory.
     GDB needs to know this so that it can subtract this address from
     absolute addresses in the upage, that are obtained via ptrace or
     from core files.  On systems that don't need this value, set it to
     zero.

`KERNEL_U_ADDR_BSD'
     Define this to cause GDB to determine the address of `u' at
     runtime, by using Berkeley-style `nlist' on the kernel's image in
     the root directory.

`KERNEL_U_ADDR_HPUX'
     Define this to cause GDB to determine the address of `u' at
     runtime, by using HP-style `nlist' on the kernel's image in the
     root directory.

`ONE_PROCESS_WRITETEXT'
     Define this to be able to, when a breakpoint insertion fails, warn
     the user that another process may be running with the same
     executable.

`PREPARE_TO_PROCEED (SELECT_IT)'
     This (ugly) macro allows a native configuration to customize the
     way the `proceed' function in `infrun.c' deals with switching
     between threads.

     In a multi-threaded task we may select another thread and then
     continue or step.  But if the old thread was stopped at a
     breakpoint, it will immediately cause another breakpoint stop
     without any execution (i.e. it will report a breakpoint hit
     incorrectly).  So GDB must step over it first.

     If defined, `PREPARE_TO_PROCEED' should check the current thread
     against the thread that reported the most recent event.  If a
     step-over is required, it returns TRUE.  If SELECT_IT is non-zero,
     it should reselect the old thread.

`PROC_NAME_FMT'
     Defines the format for the name of a `/proc' device.  Should be
     defined in `nm.h' _only_ in order to override the default
     definition in `procfs.c'.

`PTRACE_FP_BUG'
     See `mach386-xdep.c'.

`PTRACE_ARG3_TYPE'
     The type of the third argument to the `ptrace' system call, if it
     exists and is different from `int'.

`REGISTER_U_ADDR'
     Defines the offset of the registers in the "u area".

`SHELL_COMMAND_CONCAT'
     If defined, is a string to prefix on the shell command used to
     start the inferior.

`SHELL_FILE'
     If defined, this is the name of the shell to use to run the
     inferior.  Defaults to `"/bin/sh"'.

`SOLIB_ADD (FILENAME, FROM_TTY, TARG)'
     Define this to expand into an expression that will cause the
     symbols in FILENAME to be added to GDB's symbol table.

`SOLIB_CREATE_INFERIOR_HOOK'
     Define this to expand into any shared-library-relocation code that
     you want to be run just after the child process has been forked.

`START_INFERIOR_TRAPS_EXPECTED'
     When starting an inferior, GDB normally expects to trap twice;
     once when the shell execs, and once when the program itself execs.
     If the actual number of traps is something other than 2, then
     define this macro to expand into the number expected.

`SVR4_SHARED_LIBS'
     Define this to indicate that SVR4-style shared libraries are in
     use.

`USE_PROC_FS'
     This determines whether small routines in `*-tdep.c', which
     translate register values between GDB's internal representation
     and the `/proc' representation, are compiled.

`U_REGS_OFFSET'
     This is the offset of the registers in the upage.  It need only be
     defined if the generic ptrace register access routines in
     `infptrace.c' are being used (that is, `infptrace.c' is configured
     in, and `FETCH_INFERIOR_REGISTERS' is not defined).  If the
     default value from `infptrace.c' is good enough, leave it
     undefined.

     The default value means that u.u_ar0 _points to_ the location of
     the registers.  I'm guessing that `#define U_REGS_OFFSET 0' means
     that `u.u_ar0' _is_ the location of the registers.

`CLEAR_SOLIB'
     See `objfiles.c'.

`DEBUG_PTRACE'
     Define this to debug `ptrace' calls.


File: gdbint.info,  Node: Support Libraries,  Next: Coding,  Prev: Native Debugging,  Up: Top

Support Libraries
*****************

BFD
===

   BFD provides support for GDB in several ways:

_identifying executable and core files_
     BFD will identify a variety of file types, including a.out, coff,
     and several variants thereof, as well as several kinds of core
     files.

_access to sections of files_
     BFD parses the file headers to determine the names, virtual
     addresses, sizes, and file locations of all the various named
     sections in files (such as the text section or the data section).
     GDB simply calls BFD to read or write section X at byte offset Y
     for length Z.

_specialized core file support_
     BFD provides routines to determine the failing command name stored
     in a core file, the signal with which the program failed, and
     whether a core file matches (i.e. could be a core dump of) a
     particular executable file.

_locating the symbol information_
     GDB uses an internal interface of BFD to determine where to find
     the symbol information in an executable file or symbol-file.  GDB
     itself handles the reading of symbols, since BFD does not
     "understand" debug symbols, but GDB uses BFD's cached information
     to find the symbols, string table, etc.

opcodes
=======

   The opcodes library provides GDB's disassembler.  (It's a separate
library because it's also used in binutils, for `objdump').

readline
========

mmalloc
=======

libiberty
=========

gnu-regex
=========

   Regex conditionals.

`C_ALLOCA'

`NFAILURES'

`RE_NREGS'

`SIGN_EXTEND_CHAR'

`SWITCH_ENUM_BUG'

`SYNTAX_TABLE'

`Sword'

`sparc'
include
=======


File: gdbint.info,  Node: Coding,  Next: Porting GDB,  Prev: Support Libraries,  Up: Top

Coding
******

   This chapter covers topics that are lower-level than the major
algorithms of GDB.

Cleanups
========

   Cleanups are a structured way to deal with things that need to be
done later.  When your code does something (like `malloc' some memory,
or open a file) that needs to be undone later (e.g., free the memory or
close the file), it can make a cleanup.  The cleanup will be done at
some future point: when the command is finished, when an error occurs,
or when your code decides it's time to do cleanups.

   You can also discard cleanups, that is, throw them away without doing
what they say.  This is only done if you ask that it be done.

   Syntax:

`struct cleanup *OLD_CHAIN;'
     Declare a variable which will hold a cleanup chain handle.

`OLD_CHAIN = make_cleanup (FUNCTION, ARG);'
     Make a cleanup which will cause FUNCTION to be called with ARG (a
     `char *') later.  The result, OLD_CHAIN, is a handle that can be
     passed to `do_cleanups' or `discard_cleanups' later.  Unless you
     are going to call `do_cleanups' or `discard_cleanups' yourself,
     you can ignore the result from `make_cleanup'.

`do_cleanups (OLD_CHAIN);'
     Perform all cleanups done since `make_cleanup' returned OLD_CHAIN.
     E.g.:

          make_cleanup (a, 0);
          old = make_cleanup (b, 0);
          do_cleanups (old);

     will call `b()' but will not call `a()'.  The cleanup that calls
     `a()' will remain in the cleanup chain, and will be done later
     unless otherwise discarded.

`discard_cleanups (OLD_CHAIN);'
     Same as `do_cleanups' except that it just removes the cleanups from
     the chain and does not call the specified functions.

   Some functions, e.g. `fputs_filtered()' or `error()', specify that
they "should not be called when cleanups are not in place".  This means
that any actions you need to reverse in the case of an error or
interruption must be on the cleanup chain before you call these
functions, since they might never return to your code (they `longjmp'
instead).

Wrapping Output Lines
=====================

   Output that goes through `printf_filtered' or `fputs_filtered' or
`fputs_demangled' needs only to have calls to `wrap_here' added in
places that would be good breaking points.  The utility routines will
take care of actually wrapping if the line width is exceeded.

   The argument to `wrap_here' is an indentation string which is
printed _only_ if the line breaks there.  This argument is saved away
and used later.  It must remain valid until the next call to
`wrap_here' or until a newline has been printed through the
`*_filtered' functions.  Don't pass in a local variable and then return!

   It is usually best to call `wrap_here' after printing a comma or
space.  If you call it before printing a space, make sure that your
indentation properly accounts for the leading space that will print if
the line wraps there.

   Any function or set of functions that produce filtered output must
finish by printing a newline, to flush the wrap buffer, before switching
to unfiltered (`printf') output.  Symbol reading routines that print
warnings are a good example.

GDB Coding Standards
====================

   GDB follows the GNU coding standards, as described in
`etc/standards.texi'.  This file is also available for anonymous FTP
from GNU archive sites.  GDB takes a strict interpretation of the
standard; in general, when the GNU standard recommends a practice but
does not require it, GDB requires it.

   GDB follows an additional set of coding standards specific to GDB,
as described in the following sections.

ISO-C
-----

   GDB assumes an ISO-C compliant compiler.

   GDB does not assume an ISO-C or POSIX compliant C library.

Memory Management
-----------------

   GDB does not use the functions `malloc', `realloc', `calloc', `free'
and `asprintf'.

   GDB uses the functions `xmalloc', `xrealloc' and `xcalloc' when
allocating memory.  Unlike `malloc' et.al.  these functions do not
return when the memory pool is empty.  Instead, they unwind the stack
using cleanups.  These functions return `NULL' when requested to
allocate a chunk of memory of size zero.

   _Pragmatics: By using these functions, the need to check every
memory allocation is removed.  These functions provide portable
behavior._

   GDB does not use the function `free'.

   GDB uses the function `xfree' to return memory to the memory pool.
Consistent with ISO-C, this function ignores a request to free a `NULL'
pointer.

   _Pragmatics: On some systems `free' fails when passed a `NULL'
pointer._

   GDB can use the non-portable function `alloca' for the allocation of
small temporary values (such as strings).

   _Pragmatics: This function is very non-portable.  Some systems
restrict the memory being allocated to no more than a few kilobytes._

   GDB uses the string function `xstrdup' and the print function
`xasprintf'.

   _Pragmatics: `asprintf' and `strdup' can fail.  Print functions such
as `sprintf' are very prone to buffer overflow errors._

Compiler Warnings
-----------------

   With few exceptions, developers should include the configuration
option `--enable-gdb-build-warnings=,-Werror' when building GDB.  The
exceptions are listed in the file `gdb/MAINTAINERS'.

   This option causes GDB (when built using GCC) to be compiled with a
carefully selected list of compiler warning flags.  Any warnings from
those flags being treated as errors.

   The current list of warning flags includes:

`-Wimplicit'
     Since GDB coding standard requires all functions to be declared
     using a prototype, the flag has the side effect of ensuring that
     prototyped functions are always visible with out resorting to
     `-Wstrict-prototypes'.

`-Wreturn-type'
     Such code often appears to work except on instruction set
     architectures that use register windows.

`-Wcomment'

`-Wtrigraphs'

`-Wformat'
     Since GDB uses the `format printf' attribute on all `printf' like
     functions this checks not just `printf' calls but also calls to
     functions such as `fprintf_unfiltered'.

`-Wparentheses'
     This warning includes uses of the assignment operator within an
     `if' statement.

`-Wpointer-arith'

`-Wuninitialized'
   _Pragmatics: Due to the way that GDB is implemented most functions
have unused parameters.  Consequently the warning `-Wunused-parameter'
is precluded from the list.  The macro `ATTRIBUTE_UNUSED' is not used
as it leads to false negatives -- it is not an error to have
`ATTRIBUTE_UNUSED' on a parameter that is being used.  The options
`-Wall' and `-Wunused' are also precluded because they both include
`-Wunused-parameter'._

   _Pragmatics: GDB has not simply accepted the warnings enabled by
`-Wall -Werror -W...'.  Instead it is selecting warnings when and where
their benefits can be demonstrated._

Formatting
----------

   The standard GNU recommendations for formatting must be followed
strictly.

   A function declaration should not have its name in column zero.  A
function definition should have its name in column zero.

     /* Declaration */
     static void foo (void);
     /* Definition */
     void
     foo (void)
     {
     }

   _Pragmatics: This simplifies scripting.  Function definitions can be
found using `^function-name'._

   There must be a space between a function or macro name and the
opening parenthesis of its argument list (except for macro definitions,
as required by C).  There must not be a space after an open
paren/bracket or before a close paren/bracket.

   While additional whitespace is generally helpful for reading, do not
use more than one blank line to separate blocks, and avoid adding
whitespace after the end of a program line (as of 1/99, some 600 lines
had whitespace after the semicolon).  Excess whitespace causes
difficulties for `diff' and `patch' utilities.

   Pointers are declared using the traditional K&R C style:

     void *foo;

and not:

     void * foo;
     void* foo;

Comments
--------

   The standard GNU requirements on comments must be followed strictly.

   Block comments must appear in the following form, with no `/*'- or
`*/'-only lines, and no leading `*':

     /* Wait for control to return from inferior to debugger.  If inferior
        gets a signal, we may decide to start it up again instead of
        returning.  That is why there is a loop in this function.  When
        this function actually returns it means the inferior should be left
        stopped and GDB should read more commands.  */

   (Note that this format is encouraged by Emacs; tabbing for a
multi-line comment works correctly, and `M-q' fills the block
consistently.)

   Put a blank line between the block comments preceding function or
variable definitions, and the definition itself.

   In general, put function-body comments on lines by themselves, rather
than trying to fit them into the 20 characters left at the end of a
line, since either the comment or the code will inevitably get longer
than will fit, and then somebody will have to move it anyhow.

C Usage
-------

   Code must not depend on the sizes of C data types, the format of the
host's floating point numbers, the alignment of anything, or the order
of evaluation of expressions.

   Use functions freely.  There are only a handful of compute-bound
areas in GDB that might be affected by the overhead of a function call,
mainly in symbol reading.  Most of GDB's performance is limited by the
target interface (whether serial line or system call).

   However, use functions with moderation.  A thousand one-line
functions are just as hard to understand as a single thousand-line
function.

   _Macros are bad, M'kay._

   Declarations like `struct foo *' should be used in preference to
declarations like `typedef struct foo { ... } *foo_ptr'.

Function Prototypes
-------------------

   Prototypes must be used when both _declaring_ and _defining_ a
function.  Prototypes for GDB functions must include both the argument
type and name, with the name matching that used in the actual function
definition.

   All external functions should have a declaration in a header file
that callers include, except for `_initialize_*' functions, which must
be external so that `init.c' construction works, but shouldn't be
visible to random source files.

   Where a source file needs a forward declaration of a static function,
that declaration must appear in a block near the top of the source file.

Internal Error Recovery
-----------------------

   During its execution, GDB can encounter two types of errors.  User
errors and internal errors.  User errors include not only a user
entering an incorrect command but also problems arising from corrupt
object files and system errors when interacting with the target.
Internal errors include situtations where GDB has detected, at run
time, a corrupt or erroneous situtation.

   When reporting an internal error, GDB uses `internal_error' and
`gdb_assert'.

   GDB must not call `abort' or `assert'.

   _Pragmatics: There is no `internal_warning' function.  Either the
code detected a user error, recovered from it and issued a `warning' or
the code failed to correctly recover from the user error and issued an
`internal_error'._

File Names
----------

   Any file used when building the core of GDB must be in lower case.
Any file used when building the core of GDB must be 8.3 unique.  These
requirements apply to both source and generated files.

   _Pragmatics: The core of GDB must be buildable on many platforms
including DJGPP and MacOS/HFS.  Every time an unfriendly file is
introduced to the build process both `Makefile.in' and `configure.in'
need to be modified accordingly.  Compare the convoluted conversion
process needed to transform `COPYING' into `copying.c' with the
conversion needed to transform `version.in' into `version.c'._

   Any file non 8.3 compliant file (that is not used when building the
core of GDB) must be added to `gdb/config/djgpp/fnchange.lst'.

   _Pragmatics: This is clearly a compromise._

   When GDB has a local version of a system header file (ex `string.h')
the file name based on the POSIX header prefixed with `gdb_'
(`gdb_string.h').

   For other files `-' is used as the separator.

Include Files
-------------

   All `.c' files should include `defs.h' first.

   All `.c' files should explicitly include the headers for any
declarations they refer to.  They should not rely on files being
included indirectly.

   With the exception of the global definitions supplied by `defs.h', a
header file should explictily include the header declaring any
`typedefs' et.al. it refers to.

   `extern' declarations should never appear in `.c' files.

   All include files should be wrapped in:

     #ifndef INCLUDE_FILE_NAME_H
     #define INCLUDE_FILE_NAME_H
     header body
     #endif

Clean Design and Portable Implementation
----------------------------------------

   In addition to getting the syntax right, there's the little question
of semantics.  Some things are done in certain ways in GDB because long
experience has shown that the more obvious ways caused various kinds of
trouble.

   You can't assume the byte order of anything that comes from a target
(including VALUEs, object files, and instructions).  Such things must
be byte-swapped using `SWAP_TARGET_AND_HOST' in GDB, or one of the swap
routines defined in `bfd.h', such as `bfd_get_32'.

   You can't assume that you know what interface is being used to talk
to the target system.  All references to the target must go through the
current `target_ops' vector.

   You can't assume that the host and target machines are the same
machine (except in the "native" support modules).  In particular, you
can't assume that the target machine's header files will be available
on the host machine.  Target code must bring along its own header files
- written from scratch or explicitly donated by their owner, to avoid
copyright problems.

   Insertion of new `#ifdef''s will be frowned upon.  It's much better
to write the code portably than to conditionalize it for various
systems.

   New `#ifdef''s which test for specific compilers or manufacturers or
operating systems are unacceptable.  All `#ifdef''s should test for
features.  The information about which configurations contain which
features should be segregated into the configuration files.  Experience
has proven far too often that a feature unique to one particular system
often creeps into other systems; and that a conditional based on some
predefined macro for your current system will become worthless over
time, as new versions of your system come out that behave differently
with regard to this feature.

   Adding code that handles specific architectures, operating systems,
target interfaces, or hosts, is not acceptable in generic code.

   One particularly notorious area where system dependencies tend to
creep in is handling of file names.  The mainline GDB code assumes
Posix semantics of file names: absolute file names begin with a forward
slash `/', slashes are used to separate leading directories,
case-sensitive file names.  These assumptions are not necessarily true
on non-Posix systems such as MS-Windows.  To avoid system-dependent
code where you need to take apart or construct a file name, use the
following portable macros:

`HAVE_DOS_BASED_FILE_SYSTEM'
     This preprocessing symbol is defined to a non-zero value on hosts
     whose filesystems belong to the MS-DOS/MS-Windows family.  Use this
     symbol to write conditional code which should only be compiled for
     such hosts.

`IS_DIR_SEPARATOR (C'
     Evaluates to a non-zero value if C is a directory separator
     character.  On Unix and GNU/Linux systems, only a slash `/' is
     such a character, but on Windows, both `/' and `\' will pass.

`IS_ABSOLUTE_PATH (FILE)'
     Evaluates to a non-zero value if FILE is an absolute file name.
     For Unix and GNU/Linux hosts, a name which begins with a slash `/'
     is absolute.  On DOS and Windows, `d:/foo' and `x:\bar' are also
     absolute file names.

`FILENAME_CMP (F1, F2)'
     Calls a function which compares file names F1 and F2 as
     appropriate for the underlying host filesystem.  For Posix systems,
     this simply calls `strcmp'; on case-insensitive filesystems it
     will call `strcasecmp' instead.

`DIRNAME_SEPARATOR'
     Evaluates to a character which separates directories in
     `PATH'-style lists, typically held in environment variables.  This
     character is `:' on Unix, `;' on DOS and Windows.

`SLASH_STRING'
     This evaluates to a constant string you should use to produce an
     absolute filename from leading directories and the file's basename.
     `SLASH_STRING' is `"/"' on most systems, but might be `"\\"' for
     some Windows-based ports.

   In addition to using these macros, be sure to use portable library
functions whenever possible.  For example, to extract a directory or a
basename part from a file name, use the `dirname' and `basename'
library functions (available in `libiberty' for platforms which don't
provide them), instead of searching for a slash with `strrchr'.

   Another way to generalize GDB along a particular interface is with an
attribute struct.  For example, GDB has been generalized to handle
multiple kinds of remote interfaces--not by `#ifdef's everywhere, but
by defining the `target_ops' structure and having a current target (as
well as a stack of targets below it, for memory references).  Whenever
something needs to be done that depends on which remote interface we are
using, a flag in the current target_ops structure is tested (e.g.,
`target_has_stack'), or a function is called through a pointer in the
current target_ops structure.  In this way, when a new remote interface
is added, only one module needs to be touched--the one that actually
implements the new remote interface.  Other examples of
attribute-structs are BFD access to multiple kinds of object file
formats, or GDB's access to multiple source languages.

   Please avoid duplicating code.  For example, in GDB 3.x all the code
interfacing between `ptrace' and the rest of GDB was duplicated in
`*-dep.c', and so changing something was very painful.  In GDB 4.x,
these have all been consolidated into `infptrace.c'.  `infptrace.c' can
deal with variations between systems the same way any system-independent
file would (hooks, `#if defined', etc.), and machines which are
radically different don't need to use `infptrace.c' at all.

   All debugging code must be controllable using the `set debug MODULE'
command.  Do not use `printf' to print trace messages.  Use
`fprintf_unfiltered(gdb_stdlog, ...'.  Do not use `#ifdef DEBUG'.


File: gdbint.info,  Node: Porting GDB,  Next: Testsuite,  Prev: Coding,  Up: Top

Porting GDB
***********

   Most of the work in making GDB compile on a new machine is in
specifying the configuration of the machine.  This is done in a
dizzying variety of header files and configuration scripts, which we
hope to make more sensible soon.  Let's say your new host is called an
XYZ (e.g.,  `sun4'), and its full three-part configuration name is
`ARCH-XVEND-XOS' (e.g., `sparc-sun-sunos4').  In particular:

   * In the top level directory, edit `config.sub' and add ARCH, XVEND,
     and XOS to the lists of supported architectures, vendors, and
     operating systems near the bottom of the file.  Also, add XYZ as
     an alias that maps to `ARCH-XVEND-XOS'.  You can test your changes
     by running

          ./config.sub XYZ

     and

          ./config.sub `ARCH-XVEND-XOS'

     which should both respond with `ARCH-XVEND-XOS' and no error
     messages.

     You need to port BFD, if that hasn't been done already.  Porting
     BFD is beyond the scope of this manual.

   * To configure GDB itself, edit `gdb/configure.host' to recognize
     your system and set `gdb_host' to XYZ, and (unless your desired
     target is already available) also edit `gdb/configure.tgt',
     setting `gdb_target' to something appropriate (for instance, XYZ).

   * Finally, you'll need to specify and define GDB's host-, native-,
     and target-dependent `.h' and `.c' files used for your
     configuration.

Configuring GDB for Release
===========================

   From the top level directory (containing `gdb', `bfd', `libiberty',
and so on):

     make -f Makefile.in gdb.tar.gz

This will properly configure, clean, rebuild any files that are
distributed pre-built (e.g. `c-exp.tab.c' or `refcard.ps'), and will
then make a tarfile.  (If the top level directory has already been
configured, you can just do `make gdb.tar.gz' instead.)

   This procedure requires:

   * symbolic links;

   * `makeinfo' (texinfo2 level);

   * TeX;

   * `dvips';

   * `yacc' or `bison'.

... and the usual slew of utilities (`sed', `tar', etc.).

TEMPORARY RELEASE PROCEDURE FOR DOCUMENTATION
---------------------------------------------

   `gdb.texinfo' is currently marked up using the texinfo-2 macros,
which are not yet a default for anything (but we have to start using
them sometime).

   For making paper, the only thing this implies is the right
generation of `texinfo.tex' needs to be included in the distribution.

   For making info files, however, rather than duplicating the texinfo2
distribution, generate `gdb-all.texinfo' locally, and include the files
`gdb.info*' in the distribution.  Note the plural; `makeinfo' will
split the document into one overall file and five or so included files.


File: gdbint.info,  Node: Testsuite,  Next: Hints,  Prev: Porting GDB,  Up: Top

Testsuite
*********

   The testsuite is an important component of the GDB package.  While
it is always worthwhile to encourage user testing, in practice this is
rarely sufficient; users typically use only a small subset of the
available commands, and it has proven all too common for a change to
cause a significant regression that went unnoticed for some time.

   The GDB testsuite uses the DejaGNU testing framework.  DejaGNU is
built using `Tcl' and `expect'.  The tests themselves are calls to
various `Tcl' procs; the framework runs all the procs and summarizes
the passes and fails.

Using the Testsuite
===================

   To run the testsuite, simply go to the GDB object directory (or to
the testsuite's objdir) and type `make check'.  This just sets up some
environment variables and invokes DejaGNU's `runtest' script.  While
the testsuite is running, you'll get mentions of which test file is in
use, and a mention of any unexpected passes or fails.  When the
testsuite is finished, you'll get a summary that looks like this:

                     === gdb Summary ===
     
     # of expected passes            6016
     # of unexpected failures        58
     # of unexpected successes       5
     # of expected failures          183
     # of unresolved testcases       3
     # of untested testcases         5

   The ideal test run consists of expected passes only; however, reality
conspires to keep us from this ideal.  Unexpected failures indicate
real problems, whether in GDB or in the testsuite.  Expected failures
are still failures, but ones which have been decided are too hard to
deal with at the time; for instance, a test case might work everywhere
except on AIX, and there is no prospect of the AIX case being fixed in
the near future.  Expected failures should not be added lightly, since
you may be masking serious bugs in GDB.  Unexpected successes are
expected fails that are passing for some reason, while unresolved and
untested cases often indicate some minor catastrophe, such as the
compiler being unable to deal with a test program.

   When making any significant change to GDB, you should run the
testsuite before and after the change, to confirm that there are no
regressions.  Note that truly complete testing would require that you
run the testsuite with all supported configurations and a variety of
compilers; however this is more than really necessary.  In many cases
testing with a single configuration is sufficient.  Other useful
options are to test one big-endian (Sparc) and one little-endian (x86)
host, a cross config with a builtin simulator (powerpc-eabi, mips-elf),
or a 64-bit host (Alpha).

   If you add new functionality to GDB, please consider adding tests
for it as well; this way future GDB hackers can detect and fix their
changes that break the functionality you added.  Similarly, if you fix
a bug that was not previously reported as a test failure, please add a
test case for it.  Some cases are extremely difficult to test, such as
code that handles host OS failures or bugs in particular versions of
compilers, and it's OK not to try to write tests for all of those.

Testsuite Organization
======================

   The testsuite is entirely contained in `gdb/testsuite'.  While the
testsuite includes some makefiles and configury, these are very minimal,
and used for little besides cleaning up, since the tests themselves
handle the compilation of the programs that GDB will run.  The file
`testsuite/lib/gdb.exp' contains common utility procs useful for all
GDB tests, while the directory `testsuite/config' contains
configuration-specific files, typically used for special-purpose
definitions of procs like `gdb_load' and `gdb_start'.

   The tests themselves are to be found in `testsuite/gdb.*' and
subdirectories of those.  The names of the test files must always end
with `.exp'.  DejaGNU collects the test files by wildcarding in the
test directories, so both subdirectories and individual files get
chosen and run in alphabetical order.

   The following table lists the main types of subdirectories and what
they are for.  Since DejaGNU finds test files no matter where they are
located, and since each test file sets up its own compilation and
execution environment, this organization is simply for convenience and
intelligibility.

`gdb.base'
     This is the base testsuite.  The tests in it should apply to all
     configurations of GDB (but generic native-only tests may live
     here).  The test programs should be in the subset of C that is
     valid K&R, ANSI/ISO, and C++ (`#ifdef's are allowed if necessary,
     for instance for prototypes).

`gdb.LANG'
     Language-specific tests for any language LANG besides C.  Examples
     are `gdb.c++' and `gdb.java'.

`gdb.PLATFORM'
     Non-portable tests.  The tests are specific to a specific
     configuration (host or target), such as HP-UX or eCos.  Example is
     `gdb.hp', for HP-UX.

`gdb.COMPILER'
     Tests specific to a particular compiler.  As of this writing (June
     1999), there aren't currently any groups of tests in this category
     that couldn't just as sensibly be made platform-specific, but one
     could imagine a `gdb.gcc', for tests of GDB's handling of GCC
     extensions.

`gdb.SUBSYSTEM'
     Tests that exercise a specific GDB subsystem in more depth.  For
     instance, `gdb.disasm' exercises various disassemblers, while
     `gdb.stabs' tests pathways through the stabs symbol reader.

Writing Tests
=============

   In many areas, the GDB tests are already quite comprehensive; you
should be able to copy existing tests to handle new cases.

   You should try to use `gdb_test' whenever possible, since it
includes cases to handle all the unexpected errors that might happen.
However, it doesn't cost anything to add new test procedures; for
instance, `gdb.base/exprs.exp' defines a `test_expr' that calls
`gdb_test' multiple times.

   Only use `send_gdb' and `gdb_expect' when absolutely necessary, such
as when GDB has several valid responses to a command.

   The source language programs do _not_ need to be in a consistent
style.  Since GDB is used to debug programs written in many different
styles, it's worth having a mix of styles in the testsuite; for
instance, some GDB bugs involving the display of source lines would
never manifest themselves if the programs used GNU coding style
uniformly.


File: gdbint.info,  Node: Hints,  Next: Index,  Prev: Testsuite,  Up: Top

Hints
*****

   Check the `README' file, it often has useful information that does
not appear anywhere else in the directory.

* Menu:

* Getting Started::             Getting started working on GDB
* Debugging GDB::               Debugging GDB with itself


File: gdbint.info,  Node: Getting Started,  Up: Hints

Getting Started
===============

   GDB is a large and complicated program, and if you first starting to
work on it, it can be hard to know where to start.  Fortunately, if you
know how to go about it, there are ways to figure out what is going on.

   This manual, the GDB Internals manual, has information which applies
generally to many parts of GDB.

   Information about particular functions or data structures are
located in comments with those functions or data structures.  If you
run across a function or a global variable which does not have a
comment correctly explaining what is does, this can be thought of as a
bug in GDB; feel free to submit a bug report, with a suggested comment
if you can figure out what the comment should say.  If you find a
comment which is actually wrong, be especially sure to report that.

   Comments explaining the function of macros defined in host, target,
or native dependent files can be in several places.  Sometimes they are
repeated every place the macro is defined.  Sometimes they are where the
macro is used.  Sometimes there is a header file which supplies a
default definition of the macro, and the comment is there.  This manual
also documents all the available macros.

   Start with the header files.  Once you have some idea of how GDB's
internal symbol tables are stored (see `symtab.h', `gdbtypes.h'), you
will find it much easier to understand the code which uses and creates
those symbol tables.

   You may wish to process the information you are getting somehow, to
enhance your understanding of it.  Summarize it, translate it to another
language, add some (perhaps trivial or non-useful) feature to GDB, use
the code to predict what a test case would do and write the test case
and verify your prediction, etc.  If you are reading code and your eyes
are starting to glaze over, this is a sign you need to use a more active
approach.

   Once you have a part of GDB to start with, you can find more
specifically the part you are looking for by stepping through each
function with the `next' command.  Do not use `step' or you will
quickly get distracted; when the function you are stepping through
calls another function try only to get a big-picture understanding
(perhaps using the comment at the beginning of the function being
called) of what it does.  This way you can identify which of the
functions being called by the function you are stepping through is the
one which you are interested in.  You may need to examine the data
structures generated at each stage, with reference to the comments in
the header files explaining what the data structures are supposed to
look like.

   Of course, this same technique can be used if you are just reading
the code, rather than actually stepping through it.  The same general
principle applies--when the code you are looking at calls something
else, just try to understand generally what the code being called does,
rather than worrying about all its details.

   A good place to start when tracking down some particular area is with
a command which invokes that feature.  Suppose you want to know how
single-stepping works.  As a GDB user, you know that the `step' command
invokes single-stepping.  The command is invoked via command tables
(see `command.h'); by convention the function which actually performs
the command is formed by taking the name of the command and adding
`_command', or in the case of an `info' subcommand, `_info'.  For
example, the `step' command invokes the `step_command' function and the
`info display' command invokes `display_info'.  When this convention is
not followed, you might have to use `grep' or `M-x tags-search' in
emacs, or run GDB on itself and set a breakpoint in `execute_command'.

   If all of the above fail, it may be appropriate to ask for
information on `bug-gdb'.  But _never_ post a generic question like "I
was wondering if anyone could give me some tips about understanding
GDB"--if we had some magic secret we would put it in this manual.
Suggestions for improving the manual are always welcome, of course.

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