

\input texinfo


                           GDB Manual

               The GNU Source-Level Debugger


               Third Edition, GDB version 3.4

                        October 1989


                    Richard M. Stallman


Copyright  1988, 1989 Free Software Foundation, Inc.

     Permission is granted to make and  distribute  verbatim
copies of this manual provided the copyright notice and this
permission notice are preserved on all copies.

     Permission is granted to copy and  distribute  modified
versions  of  this  manual under the conditions for verbatim
copying, provided also that the section entitled ``GNU  Gen-
eral  Public  License'' is included exactly as in the origi-
nal, and provided that the entire resulting derived work  is
distributed under the terms of a permission notice identical
to this one.

     Permission is granted to copy and  distribute  transla-
tions  of this manual into another language, under the above
conditions for modified versions, except  that  the  section
entitled ``GNU General Public License'' may be included in a
translation approved by the author instead of in the  origi-
nal English.


22                                                 GGDDBB MMaannuuaall


SSuummmmaarryy ooff GGDDBB

     The purpose of a debugger such as GDB is to  allow  you
to  execute another program while examining what is going on
inside it.  We call the other program  ``your  program''  or
``the program being debugged''.

     GDB can do four kinds of things (plus other  things  in
support of these):

     1.   Start the program, specifying anything that  might
          affect its behavior.

     2.   Make the program stop on specified conditions.

     3.   Examine what has happened, when  the  program  has
          stopped, so that you can see bugs happen.

     4.   Change things in the program, so you  can  correct
          the  effects  of  one bug and go on to learn about
          another without having to recompile first.


     GDB can be used to debug programs written in C and C++.
Pascal  support  is  being  implemented, and Fortran support
will be added when a GNU Fortran compiler is written.

GGNNUU GGEENNEERRAALL PPUUBBLLIICC LLIICCEENNSSEE
                  Version 1, February 1989

    Copyright  1989 Free Software Foundation, Inc.
    675 Mass Ave, Cambridge, MA 02139, USA

    Everyone is permitted to copy and distribute verbatim copies
    of this license document, but changing it is not allowed.


PPrreeaammbbllee

       The license agreements of most software companies try
to keep users at the mercy of those companies.  By contrast,
our General Public License is  intended  to  guarantee  your
freedom to share and change free software---to make sure the
software is free for all  its  users.   The  General  Public
License  applies  to the Free Software Foundation's software
and to any other program whose authors commit to  using  it.
You can use it for your programs, too.

       When we speak of free software, we are  referring  to
freedom,   not  price.   Specifically,  the  General  Public
License is designed to make sure that you have  the  freedom
to  give  away  or  sell  copies  of free software, that you
receive source code or can get it if you want it,  that  you
can  change  the  software  or  use pieces of it in new free


GGDDBB MMaannuuaall                                                 33


programs; and that you know you can do these things.

       To protect your rights, we need to make  restrictions
that forbid anyone to deny you these rights or to ask you to
surrender the rights.  These restrictions translate to  cer-
tain  responsibilities  for  you if you distribute copies of
the software, or if you modify it.

       For example, if you distribute copies  of  a  such  a
program,  whether  gratis  or  for  a fee, you must give the
recipients all the rights that you have.  You must make sure
that they, too, receive or can get the source code.  And you
must tell them their rights.

       We protect your rights with two steps: (1)  copyright
the software, and (2) offer you this license which gives you
legal permission  to  copy,  distribute  and/or  modify  the
software.

       Also, for each author's protection and ours, we  want
to  make  certain that everyone understands that there is no
warranty for this free software.  If the software  is  modi-
fied  by  someone else and passed on, we want its recipients
to know that what they have is not the original, so that any
problems introduced by others will not reflect on the origi-
nal authors' reputations.

       The precise terms and conditions for copying, distri-
bution and modification follow.

TTEERRMMSS AANNDD CCOONNDDIITTIIOONNSS

     1.   This License Agreement applies to any  program  or
          other  work  which contains a notice placed by the
          copyright holder  saying  it  may  be  distributed
          under  the  terms  of this General Public License.
          The ``Program'', below, refers to any such program
          or work, and a ``work based on the Program'' means
          either the Program or any work containing the Pro-
          gram  or  a portion of it, either verbatim or with
          modifications.   Each  licensee  is  addressed  as
          ``you''.

     2.   You may copy and distribute verbatim copies of the
          Program's  source  code  as you receive it, in any
          medium, provided that you  conspicuously  and  ap-
          propriately  publish  on  each copy an appropriate
          copyright notice and disclaimer of warranty;  keep
          intact  all the notices that refer to this General
          Public License and to the absence of any warranty;
          and  give  any  other  recipients of the Program a
          copy of this General Public License along with the
          Program.   You  may  charge a fee for the physical
          act of transferring a copy.


44                                                 GGDDBB MMaannuuaall


     3.   You may modify your copy or copies of the  Program
          or any portion of it, and copy and distribute such
          modifications  under  the  terms  of  Paragraph  1
          above, provided that you also do the following:

               cause the modified files to  carry  prominent
               notices  stating  that  you changed the files
               and the date of any change; and

               cause the whole of any work that you  distri-
               bute  or  publish,  that  in whole or in part
               contains the Program or any part thereof, ei-
               ther  with  or  without  modifications, to be
               licensed at no charge to  all  third  parties
               under   the  terms  of  this  General  Public
               License (except that you may choose to  grant
               warranty protection to some or all third par-
               ties, at your option).

               If the modified program normally  reads  com-
               mands  interactively when run, you must cause
               it, when started running for such interactive
               use  in  the  simplest and most usual way, to
               print or display an announcement including an
               appropriate  copyright  notice  and  a notice
               that there is no warranty  (or  else,  saying
               that  you  provide a warranty) and that users
               may redistribute the program under these con-
               ditions,  and  telling the user how to view a
               copy of this General Public License.

               You may charge a fee for the physical act  of
               transferring  a copy, and you may at your op-
               tion offer warranty  protection  in  exchange
               for a fee.


          Mere aggregation of another independent work  with
          the  Program  (or its derivative) on a volume of a
          storage or distribution medium does not bring  the
          other work under the scope of these terms.

     4.   You may copy and distribute the Program (or a por-
          tion  or  derivative  of it, under Paragraph 2) in
          object code or executable form under the terms  of
          Paragraphs 1 and 2 above provided that you also do
          one of the following:

               accompany it with the complete  corresponding
               machine-readable  source  code, which must be
               distributed under the terms of  Paragraphs  1
               and 2 above; or,


GGDDBB MMaannuuaall                                                 55


               accompany it with a written offer, valid  for
               at least three years, to give any third party
               free (except for a  nominal  charge  for  the
               cost  of  distribution)  a  complete machine-
               readable copy  of  the  corresponding  source
               code,  to  be  distributed under the terms of
               Paragraphs 1 and 2 above; or,

               accompany it with  the  information  you  re-
               ceived  as  to where the corresponding source
               code may be obtained.  (This  alternative  is
               allowed  only  for noncommercial distribution
               and only if you received the program  in  ob-
               ject code or executable form alone.)


          Source code for a work means the preferred form of
          the  work  for making modifications to it.  For an
          executable file, complete source  code  means  all
          the  source code for all modules it contains; but,
          as a special exception, it need not include source
          code for modules which are standard libraries that
          accompany the operating system on which  the  exe-
          cutable file runs, or for standard header files or
          definitions files that  accompany  that  operating
          system.

     5.   You may not copy, modify,  sublicense,  distribute
          or  transfer  the Program except as expressly pro-
          vided under this General Public License.  Any  at-
          tempt  otherwise to copy, modify, sublicense, dis-
          tribute or transfer the Program is void, and  will
          automatically  terminate  your  rights  to use the
          Program under this License.  However, parties  who
          have  received  copies,  or  rights to use copies,
          from you under this General  Public  License  will
          not have their licenses terminated so long as such
          parties remain in full compliance.

     6.   By copying, distributing or modifying the  Program
          (or  any  work  based on the Program) you indicate
          your acceptance of this license to do so, and  all
          its terms and conditions.

     7.   Each time you redistribute  the  Program  (or  any
          work based on the Program), the recipient automat-
          ically receives a license from the original licen-
          sor to copy, distribute or modify the Program sub-
          ject to these terms and conditions.  You  may  not
          impose any further restrictions on the recipients'
          exercise of the rights granted herein.

     8.   The Free Software Foundation may  publish  revised
          and/or  new versions of the General Public License


66                                                 GGDDBB MMaannuuaall


          from time to time.   Such  new  versions  will  be
          similar  in spirit to the present version, but may
          differ in detail to address new problems  or  con-
          cerns.

          Each version is  given  a  distinguishing  version
          number.  If the Program specifies a version number
          of the license which applies to it and ``any later
          version'',  you  have  the option of following the
          terms and conditions either of that version or  of
          any  later  version published by the Free Software
          Foundation.  If the Program  does  not  specify  a
          version  number of the license, you may choose any
          version ever published by the Free Software  Foun-
          dation.

     9.   If you wish to incorporate parts  of  the  Program
          into other free programs whose distribution condi-
          tions are different, write to the  author  to  ask
          for permission.  For software which is copyrighted
          by the Free Software Foundation, write to the Free
          Software  Foundation; we sometimes make exceptions
          for this.  Our decision will be guided by the  two
          goals of preserving the free status of all deriva-
          tives of our free software and  of  promoting  the
          sharing and reuse of software generally.

     NNOO WWAARRRRAANNTTYY

     10.  BECAUSE THE PROGRAM IS LICENSED  FREE  OF  CHARGE,
          THERE  IS  NO WARRANTY FOR THE PROGRAM, TO THE EX-
          TENT PERMITTED BY  APPLICABLE  LAW.   EXCEPT  WHEN
          OTHERWISE  STATED IN WRITING THE COPYRIGHT HOLDERS
          AND/OR OTHER PARTIES PROVIDE THE PROGRAM ``AS IS''
          WITHOUT  WARRANTY OF ANY KIND, EITHER EXPRESSED OR
          IMPLIED, INCLUDING, BUT NOT LIMITED  TO,  THE  IM-
          PLIED  WARRANTIES  OF  MERCHANTABILITY AND FITNESS
          FOR A PARTICULAR PURPOSE.  THE ENTIRE RISK  AS  TO
          THE QUALITY AND PERFORMANCE OF THE PROGRAM IS WITH
          YOU.  SHOULD THE PROGRAM PROVE DEFECTIVE, YOU  AS-
          SUME  THE  COST OF ALL NECESSARY SERVICING, REPAIR
          OR CORRECTION.

     11.  IN NO EVENT UNLESS REQUIRED BY APPLICABLE  LAW  OR
          AGREED TO IN WRITING WILL ANY COPYRIGHT HOLDER, OR
          ANY OTHER PARTY WHO MAY MODIFY AND/OR REDISTRIBUTE
          THE  PROGRAM  AS PERMITTED ABOVE, BE LIABLE TO YOU
          FOR DAMAGES, INCLUDING ANY GENERAL,  SPECIAL,  IN-
          CIDENTAL  OR  CONSEQUENTIAL DAMAGES ARISING OUT OF
          THE USE OR INABILITY TO USE THE PROGRAM (INCLUDING
          BUT NOT LIMITED TO LOSS OF DATA OR DATA BEING REN-
          DERED INACCURATE OR LOSSES  SUSTAINED  BY  YOU  OR
          THIRD  PARTIES  OR  A  FAILURE  OF  THE PROGRAM TO
          OPERATE WITH ANY OTHER  PROGRAMS),  EVEN  IF  SUCH


GGDDBB MMaannuuaall                                                 77


          HOLDER OR OTHER PARTY HAS BEEN ADVISED OF THE POS-
          SIBILITY OF SUCH DAMAGES.


EENNDD OOFF TTEERRMMSS AANNDD CCOONNDDIITTIIOONNSS

AAppppeennddiixx:: HHooww ttoo AAppppllyy TThheessee TTeerrmmss ttoo YYoouurr NNeeww PPrrooggrraammss

       If you develop a new program, and you want it  to  be
of  the  greatest  possible use to humanity, the best way to
achieve this is to make it free software which everyone  can
redistribute and change under these terms.

       To do so, attach the following notices  to  the  pro-
gram.   It  is  safest  to  attach them to the start of each
source file to most effectively convey the exclusion of war-
ranty;  and each file should have at least the ``copyright''
line and a pointer to where the full notice is found.


    _o_n_e _l_i_n_e _t_o _g_i_v_e _t_h_e _p_r_o_g_r_a_m'_s _n_a_m_e _a_n_d _a _b_r_i_e_f _i_d_e_a _o_f _w_h_a_t _i_t _d_o_e_s.
    Copyright (C) 19_y_y  _n_a_m_e _o_f _a_u_t_h_o_r

    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 1, or (at your option)
    any later version.

    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with this program; if not, write to the Free Software
    Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.


     Also add information on how to  contact  you  by  elec-
tronic and paper mail.

     If the program is interactive, make it output  a  short
notice like this when it starts in an interactive mode:


    Gnomovision version 69, Copyright (C) 19_y_y _n_a_m_e _o_f _a_u_t_h_o_r
    Gnomovision comes with ABSOLUTELY NO WARRANTY; for details type `show w'.
    This is free software, and you are welcome to redistribute it
    under certain conditions; type `show c' for details.


88                                                 GGDDBB MMaannuuaall


     The hypothetical commands `show w' and `show c'  should
show  the  appropriate  parts of the General Public License.
Of course, the commands you  use  may  be  called  something
other  than `show w' and `show c'; they could even be mouse-
clicks or menu items---whatever suits your program.

     You should also get your employer (if  you  work  as  a
programmer)  or  your  school, if any, to sign a ``copyright
disclaimer'' for the program, if necessary.  Here a  sample;
alter the names:


    Yoyodyne, Inc., hereby disclaims all copyright interest in the
    program `Gnomovision' (a program to direct compilers to make passes
    at assemblers) written by James Hacker.

    _s_i_g_n_a_t_u_r_e _o_f _T_y _C_o_o_n, 1 April 1989
    Ty Coon, President of Vice


     That's all there is to it!

11..  GGDDBB IInnppuutt aanndd OOuuttppuutt CCoonnvveennttiioonnss

     GDB is invoked with  the  shell  command  `gdb'.   Once
started,  it reads commands from the terminal until you tell
it to exit.

     A GDB command is a single line of input.  There  is  no
limit on how long it can be.  It starts with a command name,
which is followed by arguments whose meaning depends on  the
command  name.   For  example, the command `step' accepts an
argument which is the number of times to step, as  in  `step
5'.   You can also use the `step' command with no arguments.
Some command names do not allow any arguments.

     GDB command names may  always  be  abbreviated  if  the
abbreviation   is  unambiguous.   Sometimes  even  ambiguous
abbreviations are allowed; for  example,  `s'  is  specially
defined  as equivalent to `step' even though there are other
commands whose  names  start  with  `s'.   Possible  command
abbreviations  are  often stated in the documentation of the
individual commands.

     A blank line as input to GDB means to repeat the previ-
ous  command  verbatim.  Certain commands do not allow them-
selves to be repeated this way; these are commands for which
unintentional  repetition  might cause trouble and which you
are unlikely to want to repeat.  Certain others (`list'  and
`x') act differently when repeated because that is more use-
ful.


GGDDBB MMaannuuaall                                                 99


     A line of input starting with `#' is a comment; it does
nothing.   This  is useful mainly in command files (See sec-
tion Command Files).

     GDB indicates its readiness to read a command by print-
ing  a  string  called  the _p_r_o_m_p_t.  This string is normally
`(gdb)'.  You can change the prompt  string  with  the  `set
prompt' command.  For instance, when debugging GDB with GDB,
it is useful to change the prompt in one of the GDBs so that
you tell which one you are talking to.

     set prompt _n_e_w_p_r_o_m_p_t
          Directs GDB to use _n_e_w_p_r_o_m_p_t as its prompt  string
          henceforth.


     To exit GDB, use the `quit' command (abbreviated  `q').
Ctrl-c will not exit from GDB, but rather will terminate the
action of any GDB command that is in progress and return  to
GDB  command  level.   It is safe to type Ctrl-c at any time
because GDB does not allow it to take effect  until  a  time
when it is safe.

     Certain commands to GDB may produce  large  amounts  of
information  output  to the screen.  To help you read all of
it, GDB pauses and asks you for input at  the  end  of  each
page of output.  Type RET when you want to continue the out-
put.  Normally GDB knows the size of the screen from on  the
termcap  data  base  together  with  the  value  of the TERM
environment variable; if this is not correct, you can  over-
ride it with the `set screensize' command:

     set screensize _l_p_p

     set screensize _l_p_p _c_p_l
          Specify a screen height of _l_p_p lines and  (option-
          ally) a width of _c_p_l characters.  If you omit _c_p_l,
          the width does not change.

          If you specify a height of zero  lines,  GDB  will
          not  pause  during  output  no matter how long the
          output is.  This is useful if output is to a  file
          or to an editor buffer.


     Also, GDB may at times produce more  information  about
its  own  workings than is of interest to the user.  Some of
these informational messages can be turned on and  off  with
the `set verbose' command:

     set verbose off
          Disables GDB's  output  of  certain  informational
          messages.


1100                                                GGDDBB MMaannuuaall


     set verbose on
          Re-enables GDB's output of  certain  informational
          messages.


     Currently, the messages controlled by `set verbose' are
those which announce that the symbol table for a source file
is being read (see section  File Commands, in  the  descrip-
tion of the command `symbol-file').

22..  SSppeecciiffyyiinngg GGDDBB''ss FFiilleess

     GDB needs to know the file name of the  program  to  be
debugged,  both  in  order  to  read its symbol table and in
order to start the program.  To debug a core dump of a  pre-
vious run, GDB must be told the file name of the core dump.

22..11..  SSppeecciiffyyiinngg FFiilleess wwiitthh AArrgguummeennttss

     The usual way to specify the executable and  core  dump
file  names  is  with  two  command arguments given when you
start GDB.  The first argument is used as the file for  exe-
cution and symbols, and the second argument (if any) is used
as the core dump file name.  Thus,


    gdb progm core


specifies `progm' as the executable program and `core' as  a
core  dump file to examine.  (You do not need to have a core
dump file if what you  plan  to  do  is  debug  the  program
interactively.)

     See section Options, for full  information  on  options
and arguments for invoking GDB.

22..22..  SSppeecciiffyyiinngg FFiilleess wwiitthh CCoommmmaannddss

     Usually you specify the files for GDB to work  with  by
giving  arguments  when you invoke GDB.  But occasionally it
is necessary to change to a different file during a GDB ses-
sion.   Or  you  may run GDB and forget to specify the files
you want to use.  In these situations the  GDB  commands  to
specify new files are useful.

     exec-file _f_i_l_e_n_a_m_e
          Specify that the program to be  run  is  found  in
          _f_i_l_e_n_a_m_e.   If  you do not specify a directory and
          the file is not found in GDB's working  directory,
          GDB  will  use  the environment variable PATH as a
          list of directories to search, just as  the  shell
          does when looking for a program to run.


GGDDBB MMaannuuaall                                                1111


     symbol-file _f_i_l_e_n_a_m_e
          Read symbol table information from file  _f_i_l_e_n_a_m_e.
          PATH is searched when necessary.  Most of the time
          you will use both  the  `exec-file'  and  `symbol-
          file' commands on the same file.

          `symbol-file' with no argument  clears  out  GDB's
          symbol table.

          The `symbol-file' command does not  actually  read
          the  symbol table in full right away.  Instead, it
          scans the  symbol  table  quickly  to  find  which
          source  files  and which symbols are present.  The
          details are read later, one source file at a time,
          when they are needed.

          The purpose of this two-stage reading strategy  is
          to  make  GDB start up faster.  For the most part,
          it is invisible  except  for  occasional  messages
          telling  you  that  the symbol table details for a
          particular source file are being read.  (The  `set
          verbose'  command  controls whether these messages
          are printed; see section  User Interface).

          However, you  will  sometimes  see  in  backtraces
          lines for functions in source files whose data has
          not been read in; these lines omit some of the in-
          formation,  such  as argument values, which cannot
          be printed without  full  details  of  the  symbol
          table.

          When the symbol table is stored  in  COFF  format,
          `symbol-file'  does  read the symbol table data in
          full right away.  We haven't bothered to implement
          the two-stage strategy for COFF.

     core-file _f_i_l_e_n_a_m_e
          Specify the whereabouts of a core dump file to  be
          used as the ``contents of memory''.  Note that the
          core dump contains  only  the  writable  parts  of
          memory; the read-only parts must come from the ex-
          ecutable file.

          `core-file' with no  argument  specifies  that  no
          core file is to be used.

          Note that the core file is ignored when your  pro-
          gram  is  actually  running under GDB.  So, if you
          have been running the program and you wish to  de-
          bug a core file instead, you must kill the subpro-
          cess in which the program is running.  To do this,
          use  the  `kill'  command  (see section  Kill Pro-
          cess).


1122                                                GGDDBB MMaannuuaall


     add-file _f_i_l_e_n_a_m_e _a_d_d_r_e_s_s
          The `add-file'  command  reads  additional  symbol
          table  information  from  the  file _f_i_l_e_n_a_m_e.  You
          would use this when that file has been dynamically
          loaded  into the program that is running.  _a_d_d_r_e_s_s
          should be the memory address at which the file has
          been  loaded;  GDB  cannot figure this out for it-
          self.

          The symbol table of the file _f_i_l_e_n_a_m_e is added  to
          the   symbol   table   originally  read  with  the
          `symbol-file' command.  You can use the `add-file'
          command  any  number of times; the new symbol data
          thus read keeps adding to the old.   The  `symbol-
          file'  command forgets all the symbol data GDB has
          read; that is the only time symbol data is forgot-
          ten in GDB.

     info files
          Print the names of the executable  and  core  dump
          files  currently  in use by GDB, and the file from
          which symbols were loaded.


     While all three  file-specifying  commands  allow  both
absolute  and  relative  file names as arguments, GDB always
converts the file name to an absolute one and  remembers  it
that way.

     The `symbol-file' command causes GDB to forget the con-
tents  of  its convenience variables, the value history, and
all  breakpoints  and  auto-display  expressions.   This  is
because  they  may  contain  pointers  to  the internal data
recording symbols and data types, which are part of the  old
symbol table data being discarded inside GDB.

33..  CCoommppiilliinngg YYoouurr PPrrooggrraamm ffoorr DDeebbuuggggiinngg

     In order to debug a program effectively,  you  need  to
ask  for  debugging  information  when you compile it.  This
information in the object file describes the  data  type  of
each  variable  or  function  and the correspondence between
source line numbers and addresses in the executable code.

     To request  debugging  information,  specify  the  `-g'
option when you run the compiler.

     The Unix C compiler is unable to handle  the  `-g'  and
`-O'  options  together.  This means that you cannot ask for
optimization if you ask for debugger information.

     The GNU C compiler supports `-g' with or without  `-O',
making  it  possible  to debug optimized code.  We recommend
that you _a_l_w_a_y_s use `-g' whenever  you  compile  a  program.


GGDDBB MMaannuuaall                                                1133


You  may  think the program is correct, but there's no sense
in pushing your luck.

     GDB no longer supports the debugging  information  pro-
duced  by  giving the GNU C compiler the `-gg' option, so do
not use this option.


44..  RRuunnnniinngg YYoouurr PPrrooggrraamm UUnnddeerr GGDDBB

     To start your program under GDB, use the `run' command.
The  program  must  already  have  been  specified using the
`exec-file' command or with an argument to GDB (see  section
Files);  what `run' does is create an inferior process, load
the program into it, and set it in motion.

     The execution of  a  program  is  affected  by  certain
information  it  receives  from  its superior.  GDB provides
ways to specify this information, which you must  do  _b_e_f_o_r_e
starting the program.  (You can change it after starting the
program, but such changes do not affect the  program  unless
you  start  it over again.)  This information may be divided
into three categories:

     The _a_r_g_u_m_e_n_t_s.
          You specify the arguments to give the  program  as
          the arguments of the `run' command.

     The _e_n_v_i_r_o_n_m_e_n_t.
          The program normally inherits its environment from
          GDB,  but  you  can  use the GDB commands `set en-
          vironment' and `unset environment' to change parts
          of  the environment that will be given to the pro-
          gram.

     The _w_o_r_k_i_n_g _d_i_r_e_c_t_o_r_y.
          The program inherits its  working  directory  from
          GDB.  You can set GDB's working directory with the
          `cd' command in GDB.


     After the `run' command, the debugger does nothing  but
wait for your program to stop.  See section Stopping.

     Note that once your program has  been  started  by  the
`run'  command,  you  may  evaluate expressions that involve
calls to functions in the  inferior.   See  section  Expres-
sions.   If  you  wish to evaluate a function simply for its
side affects, you may use the `set'  command.   See  section
Assignment.


1144                                                GGDDBB MMaannuuaall


44..11..  YYoouurr PPrrooggrraamm''ss AArrgguummeennttss

     The arguments to your  program  are  specified  by  the
arguments of the `run' command.  They are passed to a shell,
which expands wildcard characters and  performs  redirection
of I/O, and thence to the program.

     `run' with no arguments uses the same arguments used by
the previous `run'.

     The command `set args' can be used to specify the argu-
ments  to be used the next time the program is run.  If `set
args' has no arguments, it means to  use  no  arguments  the
next  time the program is run.  If you have run your program
with arguments and want to run it again with  no  arguments,
this is the only way to do so.

44..22..  YYoouurr PPrrooggrraamm''ss EEnnvviirroonnmmeenntt

     The _e_n_v_i_r_o_n_m_e_n_t consists of a set of _e_n_v_i_r_o_n_m_e_n_t  _v_a_r_i_-
_a_b_l_e_s  and  their values.  Environment variables convention-
ally record such things as your user name, your home  direc-
tory,  your terminal type, and your search path for programs
to run.  Usually you set up environment variables  with  the
shell  and  they are inherited by all the other programs you
run.  When debugging, it can be useful to  try  running  the
program  with different environments without having to start
the debugger over again.

     info environment _v_a_r_n_a_m_e
          Print the value of environment variable _v_a_r_n_a_m_e to
          be given to your program when it is started.  This
          command can be abbreviated `i env _v_a_r_n_a_m_e'.

     info environment
          Print the names  and  values  of  all  environment
          variables  to  be given to your program when it is
          started.  This command can be abbreviated `i env'.

     set environment _v_a_r_n_a_m_e _v_a_l_u_e

     set environment _v_a_r_n_a_m_e = _v_a_l_u_e
          Sets environment variable _v_a_r_n_a_m_e  to  _v_a_l_u_e,  for
          your  program only, not for GDB itself.  _v_a_l_u_e may
          be any string; the values of environment variables
          are  just  strings, and any interpretation is sup-
          plied by your program itself.  The _v_a_l_u_e parameter
          is  optional; if it is eliminated, the variable is
          set to a null value.  This command can be abbrevi-
          ated as short as `set e'.

          For example, this command:


GGDDBB MMaannuuaall                                                1155


              set env USER = foo


     tells the program, when subsequently run, to assume
     it is being run on behalf of the user named `foo'.

     delete environment _v_a_r_n_a_m_e

     unset environment _v_a_r_n_a_m_e
          Remove variable _v_a_r_n_a_m_e from  the  environment
          to  be  passed  to your program.  This is dif-
          ferent  from  `set  env  _v_a_r_n_a_m_e  ='   because
          `delete  environment' leaves the variable with
          no value, which  is  distinguishable  from  an
          empty  value.  This command can be abbreviated
          `d e'.


44..33..  YYoouurr PPrrooggrraamm''ss WWoorrkkiinngg DDiirreeccttoorryy

     Each time you start your program with `run', it  inher-
its its working directory from the current working directory
of GDB.  GDB's working directory is  initially  whatever  it
inherited from its parent process (typically the shell), but
you can specify a new working directory in GDB with the `cd'
command.

     The GDB working directory also serves as a default  for
the  commands that specify files for GDB to operate on.  See
section Files.

     cd _d_i_r_e_c_t_o_r_y
          Set GDB's working directory to _d_i_r_e_c_t_o_r_y.

     pwd  Print GDB's working directory.


44..44..  YYoouurr PPrrooggrraamm''ss IInnppuutt aanndd OOuuttppuutt

     By default, the program you run under  GDB  does  input
and output to the same terminal that GDB uses.

     You can redirect  the  program's  input  and/or  output
using  `sh'-style redirection commands in the `run' command.
For example,


    run > outfile


1166                                                GGDDBB MMaannuuaall


starts the program, diverting its output to the  file  `out-
file'.

     Another way to specify  where  the  program  should  do
input  and  output  is with the `tty' command.  This command
accepts a file name as argument, and causes this file to  be
the  default  for future `run' commands.  It also resets the
controlling terminal for the child process, for future `run'
commands.  For example,


    tty /dev/ttyb


directs that processes started with  subsequent  `run'  com-
mands  default  to  do  input  and  output  on  the terminal
`/dev/ttyb' and have that as their controlling terminal.

     An explicit redirection in `run'  overrides  the  `tty'
command's  effect  on  input/output redirection, but not its
effect on the controlling terminal.

     When you use the `tty' command or redirect input in the
`run'  command, only the _i_n_p_u_t _f_o_r _y_o_u_r _p_r_o_g_r_a_m is affected.
The input for GDB still comes from your terminal.

44..55..  DDeebbuuggggiinngg aann AAllrreeaaddyy--RRuunnnniinngg PPrroocceessss

     Some operating systems allow GDB to debug  an  already-
running  process  that  was  started  outside of GDB.  To do
this, you use the `attach' command instead of the `run' com-
mand.

     The `attach' command requires one  argument,  which  is
the process-id of the process you want to debug.  (The usual
way to find out the process-id of the process is with the ps
utility.)

     The first thing GDB does after arranging to  debug  the
process  is  to  stop  it.   You  can  examine and modify an
attached process with all the GDB commands  that  ordinarily
available  when  you  start  processes  with `run'.  You can
insert breakpoints; you  can  step  and  continue;  you  can
modify  storage.   If  you would rather the process continue
running, you may use the `continue' command after  attaching
GDB to the process.

     When you have finished debugging the attached  process,
you  can  use  the `detach' command to release it from GDB's
control.  Detaching the  process  continues  its  execution.
After the `detach' command, that process and GDB become com-
pletely independent once more, and you are ready to `attach'
another process or start one with `run'.


GGDDBB MMaannuuaall                                                1177


     If you exit GDB or use the `run' command while you have
an  attached  process,  you  kill that process.  You will be
asked for confirmation if you try  to  do  either  of  these
things.

     The `attach' command is also used  to  debug  a  remote
machine  via  a  serial connection.  See section Attach, for
more info.

44..66..  KKiilllliinngg tthhee CChhiilldd PPrroocceessss

     kill
          Kill the child process in which the program  being
          debugged is running under GDB.

          This command is useful if you wish to debug a core
          dump  instead.   GDB ignores any core dump file if
          it is actually running the program, so the  `kill'
          command is the only sure way to make sure the core
          dump file is used once again.

          It is also useful if you wish to run  the  program
          outside  the debugger for once and then go back to
          debugging it.

          The `kill' command is also useful if you  wish  to
          recompile  and  relink  the program, since on many
          systems it is impossible to modify  an  executable
          file  which is running in a process.  But, in this
          case, it is just as good to exit  GDB,  since  you
          will  need  to  read  a new symbol table after the
          program is recompiled if you wish to debug the new
          version,  and restarting GDB is the easiest way to
          do that.


55..  SSttooppppiinngg aanndd CCoonnttiinnuuiinngg

     When you run a program normally, it runs until it  ter-
minates.   The  principal  purpose of using a debugger is so
that you can stop it before that point; or so  that  if  the
program  runs  into trouble you can investigate and find out
why.

55..11..  SSiiggnnaallss

     A signal is an asynchronous event that can happen in  a
program.  The operating system defines the possible kinds of
signals, and gives each kind a name and a number.  For exam-
ple,  SIGINT  is  the  signal  a  program gets when you type
Ctrl-c; SIGSEGV is the signal a program gets from  referenc-
ing  a  place  in memory far away from all the areas in use;
SIGALRM occurs when the alarm clock timer  goes  off  (which
happens only if the program has requested an alarm).


1188                                                GGDDBB MMaannuuaall


     Some signals, including SIGALRM, are a normal  part  of
the  functioning  of  the program.  Others, such as SIGSEGV,
indicate errors; these signals are _f_a_t_a_l (kill  the  program
immediately)  if  the  program  has not specified in advance
some other way to handle the signal.  SIGINT does not  indi-
cate an error in the program, but it is normally fatal so it
can carry out the purpose of Ctrl-c: to kill the program.

     GDB has the ability to detect any occurrence of a  sig-
nal  in  the  program  running under GDB's control.  You can
tell GDB in advance what to do for each kind of signal.

     Normally, GDB is set up to ignore non-erroneous signals
like  SIGALRM (so as not to interfere with their role in the
functioning of the program) but to stop the program  immedi-
ately  whenever  an  error  signal  happens.  You can change
these settings with the `handle' command.  You must  specify
which signal you are talking about with its number.

     info signal
          Print a table of all the kinds of signals and  how
          GDB has been told to handle each one.  You can use
          this to see the signal numbers of all the  defined
          types of signals.

     handle _s_i_g_n_a_l_n_u_m _k_e_y_w_o_r_d_s...
          Change the way GDB handles signal _s_i_g_n_a_l_n_u_m.   The
          _k_e_y_w_o_r_d_s say what change to make.


     To use the `handle' command  you  must  know  the  code
number  of  the  signal you are concerned with.  To find the
code number, type `info signal' which prints a table of sig-
nal names and numbers.

     The keywords allowed  by  the  handle  command  can  be
abbreviated.  Their full names are

     stop
          GDB should stop the program when this signal  hap-
          pens.  This implies the `print' keyword as well.

     print
          GDB should print a message when this  signal  hap-
          pens.

     nostop
          GDB should not stop the program when  this  signal
          happens.  It may still print a message telling you
          that the signal has come in.

     noprint
          GDB should not mention the occurrence of the  sig-
          nal  at all.  This implies the `nostop' keyword as


GGDDBB MMaannuuaall                                                1199


          well.

     pass
          GDB should allow the program to see  this  signal;
          the  program will be able to handle the signal, or
          may be terminated if the signal is fatal  and  not
          handled.

     nopass
          GDB should not allow the program to see this  sig-
          nal.


     When a signal has been set to  stop  the  program,  the
program  cannot  see the signal until you continue.  It will
see the signal then, if `pass' is in effect for  the  signal
in question _a_t _t_h_a_t _t_i_m_e.  In other words, after GDB reports
a signal, you can use the `handle' command  with  `pass'  or
`nopass'  to control whether that signal will be seen by the
program when you later continue it.

     You can also use the `signal' command  to  prevent  the
program from seeing a signal, or cause it to see a signal it
normally would not see, or to give  it  any  signal  at  any
time.  See section Signaling.

55..22..  BBrreeaakkppooiinnttss

     A _b_r_e_a_k_p_o_i_n_t makes your program stop whenever a certain
point in the program is reached.  You set breakpoints expli-
citly with GDB commands, specifying the place where the pro-
gram  should  stop  by  line  number, function name or exact
address in the program.  You can add  various  other  condi-
tions to control whether the program will stop.

     Each  breakpoint  is  assigned  a  number  when  it  is
created; these numbers are successive integers starting with
1.  In many of the commands for controlling various features
of  breakpoints  you  use the breakpoint number to say which
breakpoint you want  to  change.   Each  breakpoint  may  be
_e_n_a_b_l_e_d  or  _d_i_s_a_b_l_e_d;  if disabled, it has no effect on the
program until you enable it again.

     The command `info break' prints a list  of  all  break-
points  set and not deleted, showing their numbers, where in
the program they are, and any special features  in  use  for
them.   Disabled  breakpoints  are included in the list, but
marked as disabled.  `info break' with a  breakpoint  number
as  argument  lists  only  that breakpoint.  The convenience
variable $_ and the default examining-address  for  the  `x'
command are set to the address of the last breakpoint listed
(see section  Memory).


2200                                                GGDDBB MMaannuuaall


55..22..11..  SSeettttiinngg BBrreeaakkppooiinnttss

     Breakpoints are set with the `break' command  (abbrevi-
ated  `b').   You  have several ways to say where the break-
point should go.

     break _f_u_n_c_t_i_o_n
          Set a breakpoint at entry to function _f_u_n_c_t_i_o_n.

     break +_o_f_f_s_e_t

     break -_o_f_f_s_e_t
          Set a breakpoint some number of lines  forward  or
          back  from the position at which execution stopped
          in the currently selected frame.

     break _l_i_n_e_n_u_m
          Set a breakpoint at line _l_i_n_e_n_u_m  in  the  current
          source  file.   That  file  is the last file whose
          source text was  printed.   This  breakpoint  will
          stop  the  program  just before it executes any of
          the code on that line.

     break _f_i_l_e_n_a_m_e:_l_i_n_e_n_u_m
          Set a breakpoint at line _l_i_n_e_n_u_m  in  source  file
          _f_i_l_e_n_a_m_e.

     break _f_i_l_e_n_a_m_e:_f_u_n_c_t_i_o_n
          Set a breakpoint at  entry  to  function  _f_u_n_c_t_i_o_n
          found in file _f_i_l_e_n_a_m_e.  Specifying a file name as
          well as a function name is superfluous except when
          multiple files contain similarly named functions.

     break *_a_d_d_r_e_s_s
          Set a breakpoint at address _a_d_d_r_e_s_s.  You can  use
          this  to  set  breakpoints in parts of the program
          which do not have debugging information or  source
          files.

     break
          Set a breakpoint at the next instruction to be ex-
          ecuted  in  the  selected stack frame (see section
          Stack).  In any selected frame but the  innermost,
          this  will  cause  the  program to stop as soon as
          control returns to that frame.  This is equivalent
          to  a  `finish'  command  in  the frame inside the
          selected frame.  If this is done in the  innermost
          frame,  GDB will stop the next time it reaches the
          current location; this may  be  useful  inside  of
          loops.

          GDB normally ignores breakpoints when  it  resumes
          execution, until at least one instruction has been
          executed.  If it did not do this, you would be un-


GGDDBB MMaannuuaall                                                2211


          able  to  proceed  past a breakpoint without first
          disabling  the  breakpoint.   This  rule   applies
          whether or not the breakpoint already existed when
          the program stopped.

     break ... if _c_o_n_d
          Set a breakpoint with condition _c_o_n_d; evaluate the
          expression   _c_o_n_d  each  time  the  breakpoint  is
          reached, and stop only if the  value  is  nonzero.
          `...'  stands  for  one  of the possible arguments
          described above (or no argument) specifying  where
          to break.  See section Conditions, for more infor-
          mation on breakpoint conditions.

     tbreak _a_r_g_s
          Set a breakpoint enabled only for one stop.   _a_r_g_s
          are  the  same  as in the `break' command, and the
          breakpoint is set in the same way, but the  break-
          point  is automatically disabled the first time it
          is hit.  See section Disabling.


     GDB allows you to set any number of breakpoints at  the
same  place in the program.  There is nothing silly or mean-
ingless about this.  When the breakpoints  are  conditional,
this is even useful (see section  Conditions).

55..22..22..  DDeelleettiinngg BBrreeaakkppooiinnttss

     It is often necessary to eliminate a breakpoint once it
has  done its job and you no longer want the program to stop
there.  This is called _d_e_l_e_t_i_n_g the  breakpoint.   A  break-
point  that  has been deleted no longer exists in any sense;
it is forgotten.

     With the `clear' command  you  can  delete  breakpoints
according  to  where  they  are  in  the  program.  With the
`delete' command you can delete  individual  breakpoints  by
specifying their breakpoint numbers.

     IItt iiss nnoott nneecceessssaarryy ttoo ddeelleettee aa bbrreeaakkppooiinntt  ttoo  pprroocceeeedd
ppaasstt iitt..  GDB automatically ignores breakpoints in the first
instruction to  be  executed  when  you  continue  execution
without changing the execution address.

     clear
          Delete any breakpoints at the next instruction  to
          be  executed in the selected stack frame (see sec-
          tion  Selection).  When  the  innermost  frame  is
          selected,  this  is  a good way to delete a break-
          point that the program just stopped at.

     clear _f_u_n_c_t_i_o_n


2222                                                GGDDBB MMaannuuaall


     clear _f_i_l_e_n_a_m_e:_f_u_n_c_t_i_o_n
          Delete any breakpoints set at entry to  the  func-
          tion _f_u_n_c_t_i_o_n.

     clear _l_i_n_e_n_u_m

     clear _f_i_l_e_n_a_m_e:_l_i_n_e_n_u_m
          Delete any breakpoints set at or within  the  code
          of the specified line.

     delete _b_n_u_m_s...
          Delete the breakpoints of the numbers specified as
          arguments.


55..22..33..  DDiissaabblliinngg BBrreeaakkppooiinnttss

     Rather than deleting a breakpoint, you might prefer  to
_d_i_s_a_b_l_e  it.  This makes the breakpoint inoperative as if it
had been deleted,  but  remembers  the  information  on  the
breakpoint so that you can _e_n_a_b_l_e it again later.

     You disable and enable breakpoints  with  the  `enable'
and  `disable'  commands,  specifying one or more breakpoint
numbers as arguments.  Use `info break' to print a  list  of
breakpoints  if  you  don't know which breakpoint numbers to
use.

     A breakpoint can have any of four different  states  of
enablement:

          Enabled.  The breakpoint will stop the program.  A
          breakpoint  made  with  the `break' command starts
          out in this state.

          Disabled.  The breakpoint has  no  effect  on  the
          program.

          Enabled once.  The breakpoint will stop  the  pro-
          gram, but when it does so it will become disabled.
          A breakpoint made with the `tbreak' command starts
          out in this state.

          Enabled for deletion.  The  breakpoint  will  stop
          the  program,  but immediately after it does so it
          will be deleted permanently.


     You change the state of enablement of a breakpoint with
the following commands:

     disable breakpoints _b_n_u_m_s...


GGDDBB MMaannuuaall                                                2233


     disable _b_n_u_m_s...
          Disable the  specified  breakpoints.   A  disabled
          breakpoint  has  no  effect  but is not forgotten.
          All options such as ignore-counts, conditions  and
          commands  are remembered in case the breakpoint is
          enabled again later.

     enable breakpoints _b_n_u_m_s...

     enable _b_n_u_m_s...
          Enable the specified breakpoints.  They become ef-
          fective  once again in stopping the program, until
          you specify otherwise.

     enable breakpoints once _b_n_u_m_s...

     enable once _b_n_u_m_s...
          Enable  the  specified  breakpoints   temporarily.
          Each will be disabled again the next time it stops
          the program (unless you have  used  one  of  these
          commands  to specify a different state before that
          time comes).

     enable breakpoints delete _b_n_u_m_s...

     enable delete _b_n_u_m_s...
          Enable the specified breakpoints to work once  and
          then die.  Each of the breakpoints will be deleted
          the next time it stops  the  program  (unless  you
          have  used one of these commands to specify a dif-
          ferent state before that time comes).


     Aside from the automatic disablement or deletion  of  a
breakpoint  when it stops the program, which happens only in
certain states, the state  of  enablement  of  a  breakpoint
changes only when one of the commands above is used.

55..22..44..  BBrreeaakk CCoonnddiittiioonnss

     The simplest sort of breakpoint breaks every  time  the
program  reaches  a specified place.  You can also specify a
_c_o_n_d_i_t_i_o_n for a breakpoint.  A condition is just  a  boolean
expression  in  your  programming  language.   (See  section
Expressions).  A breakpoint with a condition  evaluates  the
expression each time the program reaches it, and the program
stops only if the condition is true.

     Break conditions may have side effects,  and  may  even
call  functions  in  your  program.   These  may  sound like
strange things to  do,  but  their  effects  are  completely
predictable  unless  there  is another enabled breakpoint at
the same address.  (In that case, GDB might  see  the  other
breakpoint  first  and stop the program without checking the


2244                                                GGDDBB MMaannuuaall


condition of this one.)  Note that breakpoint  commands  are
usually more convenient and flexible for the purpose of per-
forming side effects when a breakpoint is reached (see  sec-
tion  Break Commands).

     Break conditions can be specified when a breakpoint  is
set,  by using `if' in the arguments to the `break' command.
See section Set Breaks.  They can also  be  changed  at  any
time with the `condition' command:

     condition _b_n_u_m _e_x_p_r_e_s_s_i_o_n
          Specify _e_x_p_r_e_s_s_i_o_n  as  the  break  condition  for
          breakpoint  number _b_n_u_m.  From now on, this break-
          point will stop the program only if the  value  of
          _e_x_p_r_e_s_s_i_o_n is true (nonzero, in C).  _e_x_p_r_e_s_s_i_o_n is
          not evaluated at the time the `condition'  command
          is given.  See section Expressions.

     condition _b_n_u_m
          Remove the condition from breakpoint number  _b_n_u_m.
          It becomes an ordinary unconditional breakpoint.


     A special case of a breakpoint  condition  is  to  stop
only  when  the breakpoint has been reached a certain number
of times.  This is so useful that there is a special way  to
do  it,  using  the  _i_g_n_o_r_e  _c_o_u_n_t of the breakpoint.  Every
breakpoint has an ignore count, which is an  integer.   Most
of  the time, the ignore count is zero, and therefore has no
effect.  But if  the  program  reaches  a  breakpoint  whose
ignore  count is positive, then instead of stopping, it just
decrements the ignore count by  one  and  continues.   As  a
result,  if the ignore count value is _n, the breakpoint will
not stop the next _n times it is reached.

     ignore _b_n_u_m _c_o_u_n_t
          Set the ignore count of breakpoint number _b_n_u_m  to
          _c_o_u_n_t.   The  next  _c_o_u_n_t  times the breakpoint is
          reached, it will not stop.

          To make the breakpoint stop the next  time  it  is
          reached, specify a count of zero.

     cont _c_o_u_n_t
          Continue execution of the program, setting the ig-
          nore  count  of  the  breakpoint  that the program
          stopped at to _c_o_u_n_t minus one.  Thus, the  program
          will   not  stop  at  this  breakpoint  until  the
          _c_o_u_n_t'th time it is reached.

          This command is  allowed  only  when  the  program
          stopped  due to a breakpoint.  At other times, the
          argument to `cont' is ignored.


GGDDBB MMaannuuaall                                                2255


     If a breakpoint has a positive ignore count and a  con-
dition, the condition is not checked.  Once the ignore count
reaches zero, the condition will start to be checked.

     Note that you could achieve the effect  of  the  ignore
count with a condition such as  `$foo-- <= 0'
 using a debugger convenience variable that  is  decremented
each time.  See section Convenience Vars.

55..22..55..  CCoommmmaannddss EExxeeccuutteedd oonn BBrreeaakkiinngg

     You can give any breakpoint a  series  of  commands  to
execute  when the program stops due to that breakpoint.  For
example, you might want  to  print  the  values  of  certain
expressions, or enable other breakpoints.

     commands _b_n_u_m
          Specify commands for breakpoint number _b_n_u_m.   The
          commands themselves appear on the following lines.
          Type a line containing just `end' to terminate the
          commands.

          To remove all commands from a breakpoint, use  the
          command  `commands'  and  follow it immediately by
          `end'; that is, give no commands.

          With no arguments, `commands' refers to  the  last
          breakpoint set.


     It is possible for breakpoint  commands  to  start  the
program up again.  Simply use the `cont' command, or `step',
or any other command  to  resume  execution.   However,  any
remaining breakpoint commands are ignored.  When the program
stops again, GDB will act according to  the  cause  of  that
stop.

     If the first command specified is `silent',  the  usual
message about stopping at a breakpoint is not printed.  This
may be  desirable  for  breakpoints  that  are  to  print  a
specific  message  and then continue.  If the remaining com-
mands too print nothing, you  will  see  no  sign  that  the
breakpoint  was  reached  at  all.  `silent' is not really a
command; it is meaningful only at the beginning of the  com-
mands for a breakpoint.

     The commands `echo' and  `output'  that  allow  you  to
print precisely controlled output are often useful in silent
breakpoints.  See section Output.

     For example, here is how you could use breakpoint  com-
mands to print the value of x at entry to foo whenever it is
positive.


2266                                                GGDDBB MMaannuuaall


    break foo if x>0
    commands
    silent
    echo x is\040
    output x
    echo \n
    cont
    end


     One application for breakpoint commands is  to  correct
one  bug  so  you  can  test another.  Put a breakpoint just
after the erroneous line of code, give  it  a  condition  to
detect  the case in which something erroneous has been done,
and give it commands to assign correct values to  any  vari-
ables  that  need them.  End with the `cont' command so that
the program does not stop, and start with the `silent'  com-
mand so that no output is produced.  Here is an example:


    break 403
    commands
    silent
    set x = y + 4
    cont
    end


     One deficiency in the operation of  automatically  con-
tinuing  breakpoints  under  Unix  appears when your program
uses raw mode for the terminal.  GDB switches  back  to  its
own  terminal modes (not raw) before executing commands, and
then must switch back to raw mode when your program is  con-
tinued.  This causes any pending terminal input to be lost.

     In the GNU system, this will be fixed by  changing  the
behavior of terminal modes.

     Under Unix, when you have this problem,  you  might  be
able  to  get  around  it  by  putting your actions into the
breakpoint condition instead of commands.  For example


    condition 5  (x = y + 4), 0


specifies a condition expression (See  section  Expressions)
that  will  change x as needed, then always have the value 0
so the program will not stop.  Loss of input is avoided here
because  break conditions are evaluated without changing the


GGDDBB MMaannuuaall                                                2277


terminal modes.  When you want to have nontrivial conditions
for  performing  the  side effects, the operators `&&', `||'
and `?...:' may be useful.

55..22..66..  ````CCaannnnoott IInnsseerrtt BBrreeaakkppooiinnttss'''' EErrrroorr

     Under some operating  systems,  breakpoints  cannot  be
used  in a program if any other process is running that pro-
gram.  Attempting to run or  continue  the  program  with  a
breakpoint in this case will cause GDB to stop it.

     When this happens, you have three ways to proceed:

     1.   Remove or disable the breakpoints, then continue.

     2.   Suspend GDB, and copy the file containing the pro-
          gram  to  a  new  name.   Resume  GDB  and use the
          `exec-file' command to specify that GDB should run
          the  program under that name.  Then start the pro-
          gram again.

     3.   Relink the program so that  the  text  segment  is
          nonsharable,  using  the  linker option `-N'.  The
          operating  system  limitation  may  not  apply  to
          nonsharable executables.


55..33..  CCoonnttiinnuuiinngg

     After your program stops, most likely you will want  it
to run some more if the bug you are looking for has not hap-
pened yet.

     cont
          Continue running the program at the place where it
          stopped.


     If the program stopped at a breakpoint,  the  place  to
continue  running  is  the  address  of the breakpoint.  You
might expect that continuing would just  stop  at  the  same
breakpoint  immediately.  In fact, `cont' takes special care
to prevent that from happening.  You do not need  to  delete
the breakpoint to proceed through it after stopping at it.

     You can,  however,  specify  an  ignore-count  for  the
breakpoint that the program stopped at, by means of an argu-
ment to the `cont' command.  See section Conditions.

     If the program stopped because of a signal  other  than
SIGINT  or SIGTRAP, continuing will cause the program to see
that signal.  You may not want this to happen.  For example,
if  the program stopped due to some sort of memory reference
error, you might store correct  values  into  the  erroneous


2288                                                GGDDBB MMaannuuaall


variables  and  continue,  hoping to see more execution; but
the program would probably terminate immediately as a result
of  the  fatal  signal  once it sees the signal.  To prevent
this, you can continue with `signal 0'.  See section Signal-
ing.   You  can  also  act in advance to prevent the program
from seeing certain kinds of  signals,  using  the  `handle'
command (see section  Signals).

55..44..  SStteeppppiinngg

     _S_t_e_p_p_i_n_g means setting your program  in  motion  for  a
limited  time,  so that control will return automatically to
the debugger after one line of code or one machine  instruc-
tion.   Breakpoints  are active during stepping and the pro-
gram will stop for them even if it has not gone  as  far  as
the stepping command specifies.

     step
          Continue running the program until control reaches
          a  different line, then stop it and return control
          to the debugger.  This command is abbreviated `s'.

          This command may be given when control is within a
          function  for which there is no debugging informa-
          tion.  In that case, execution will proceed  until
          control  reaches a different function, or is about
          to return from this function.  An argument repeats
          this action.

     step _c_o_u_n_t
          Continue running as in `step',  but  do  so  _c_o_u_n_t
          times.  If a breakpoint is reached or a signal not
          related to stepping  occurs  before  _c_o_u_n_t  steps,
          stepping stops right away.

     next
          Similar to `step', but any function calls  appear-
          ing  within  the line of code are executed without
          stopping.  Execution stops when control reaches  a
          different  line  of  code at the stack level which
          was executing when the `next' command  was  given.
          This command is abbreviated `n'.

          An argument is a repeat count, as in `step'.

          `next' within a function without debugging  infor-
          mation acts as does `step', but any function calls
          appearing within the code of the function are exe-
          cuted without stopping.

     finish
          Continue running until  just  after  the  selected
          stack  frame returns (or until there is some other
          reason to stop, such as a fatal signal or a break-


GGDDBB MMaannuuaall                                                2299


          point).   Print  value  returned  by  the selected
          stack frame (if any).

          Contrast this with the `return' command (see  sec-
          tion  Returning).

     until
          This command is  used  to  avoid  single  stepping
          through  a  loop  more  than once.  It is like the
          `next'  command,  except  that  when  `until'  en-
          counters a jump, it automatically continues execu-
          tion until the program counter is greater than the
          address of the jump.

          This means that when you reach the end of  a  loop
          after  single  stepping  though  it,  `until' will
          cause the program to continue execution until  the
          loop  is exited.  In contrast, a `next' command at
          the end of a loop will simply step back to the be-
          ginning of the loop, which would force you to step
          through the next iteration.

          `until' always stops the program if it attempts to
          exit the current stack frame.

          `until'  may  produce  somewhat   counterintuitive
          results  if the order of the source lines does not
          match the actual order of execution.  For example,
          in  a  typical C for-loop, the third expression in
          the for-statement (the  loop-step  expression)  is
          executed  after  the statements in the body of the
          loop, but is written before them.  Therefore,  the
          `until'  command  would appear to step back to the
          beginning of the loop when it advances to this ex-
          pression.  However, it has not really done so, not
          in terms of the actual machine code.

          Note that `until' with no argument works by  means
          of  single  instruction  stepping,  and  hence  is
          slower than `until' with an argument.

     until _l_o_c_a_t_i_o_n
          Continue running  the  program  until  either  the
          specified location is reached, or the current (in-
          nermost) stack frame returns.  This  form  of  the
          command  uses  breakpoints,  and  hence is quicker
          than `until' without an argument.

     stepi

     si   Execute one machine instruction, then stop and re-
          turn to the debugger.


3300                                                GGDDBB MMaannuuaall


          It is often useful  to  do  `display/i  $pc'  when
          stepping by machine instructions.  This will cause
          the  next  instruction  to  be  executed   to   be
          displayed automatically at each stop.  See section
          Auto Display.

          An argument is a repeat count, as in `step'.

     nexti

     ni   Execute one machine instruction, but if  it  is  a
          subroutine  call, proceed until the subroutine re-
          turns.

          An argument is a repeat count, as in `next'.


     A typical technique for using  stepping  is  to  put  a
breakpoint  (see  section   Breakpoints) at the beginning of
the function or the section of the program in which a  prob-
lem  is  believed  to lie, and then step through the suspect
area, examining the variables that  are  interesting,  until
the problem happens.

     The `cont' command can be used after stepping to resume
execution until the next breakpoint or signal.

66..  EExxaammiinniinngg tthhee SSttaacckk

     When your program has stopped, the first thing you need
to know is where it stopped and how it got there.

     Each time your program performs a  function  call,  the
information  about  where  in  the program the call was made
from is saved in a block of data called a _s_t_a_c_k _f_r_a_m_e.   The
frame  also contains the arguments of the call and the local
variables of the function that was called.   All  the  stack
frames  are  allocated in a region of memory called the _c_a_l_l
_s_t_a_c_k.

     When your program stops, the GDB commands for examining
the stack allow you to see all of this information.

     One of the stack frames is _s_e_l_e_c_t_e_d by GDB and many GDB
commands refer implicitly to the selected frame.  In partic-
ular, whenever you ask GDB for the value of  a  variable  in
the  program,  the  value  is  found  in the selected frame.
There are special GDB commands to select whichever frame you
are interested in.

     When the program stops, GDB automatically  selects  the
currently  executing  frame  and describes it briefly as the
`frame' command does (see section  Frame Info, Info).


GGDDBB MMaannuuaall                                                3311


66..11..  SSttaacckk FFrraammeess

     The call stack is divided  up  into  contiguous  pieces
called  _s_t_a_c_k _f_r_a_m_e_s, or _f_r_a_m_e_s for short; each frame is the
data associated with one call to one  function.   The  frame
contains the arguments given to the function, the function's
local variables, and the address at which  the  function  is
executing.

     When your program is started, the stack  has  only  one
frame,  that  of the function main.  This is called the _i_n_i_-
_t_i_a_l frame or the _o_u_t_e_r_m_o_s_t frame.  Each time a function  is
called,  a new frame is made.  Each time a function returns,
the frame for that function invocation is eliminated.  If  a
function is recursive, there can be many frames for the same
function.  The frame for the function in which execution  is
actually  occurring  is called the _i_n_n_e_r_m_o_s_t frame.  This is
the most recently created of all the stack frames that still
exist.

     Inside your program, stack  frames  are  identified  by
their addresses.  A stack frame consists of many bytes, each
of which has its own address; each kind of  computer  has  a
convention  for  choosing  one  of those bytes whose address
serves as the address of the frame.  Usually this address is
kept  in  a register called the _f_r_a_m_e _p_o_i_n_t_e_r _r_e_g_i_s_t_e_r while
execution is going on in that frame.

     GDB assigns  numbers  to  all  existing  stack  frames,
starting  with  zero  for  the  innermost frame, one for the
frame that called it, and so on upward.   These  numbers  do
not really exist in your program; they are to give you a way
of talking about stack frames in GDB commands.

     Many GDB commands refer implicitly to one stack  frame.
GDB  records a stack frame that is called the _s_e_l_e_c_t_e_d stack
frame; you can select any frame using one set  of  GDB  com-
mands,  and  then other commands will operate on that frame.
When your  program  stops,  GDB  automatically  selects  the
innermost frame.

     Some functions can be compiled to run without  a  frame
reserved  for  them on the stack.  This is occasionally done
with heavily used library functions to save the frame  setup
time.   GDB  has  limited  facilities for dealing with these
function invocations; if the innermost  function  invocation
has  no  stack frame, GDB will give it a virtual stack frame
of 0 and correctly allow tracing of the function call chain.
Results  are  undefined if a function invocation besides the
innermost one is frameless.


3322                                                GGDDBB MMaannuuaall


66..22..  BBaacckkttrraacceess

     A backtrace is a summary of how the program  got  where
it is.  It shows one line per frame, for many frames, start-
ing with the currently executing frame  (frame  zero),  fol-
lowed by its caller (frame one), and on up the stack.

     backtrace

     bt   Print a backtrace of the entire  stack:  one  line
          per frame for all frames in the stack.

          You can stop the backtrace at any time  by  typing
          the  system interrupt character, normally Control-
          C.

     backtrace _n

     bt _n
          Similar, but print only the innermost _n frames.

     backtrace -_n

     bt -_n
          Similar, but print only the outermost _n frames.


     The names  `where'  and  `info  stack'  are  additional
aliases for `backtrace'.

     Every line in the backtrace shows the frame number, the
function name and the program counter value.

     If the function is in a source file whose symbol  table
data  has  been  fully  read, the backtrace shows the source
file name and line number, as well as the arguments  to  the
function.  (The program counter value is omitted if it is at
the beginning of the code for that line number.)

     If the source file's symbol data  has  not  been  fully
read,  just scanned, this extra information is replaced with
an ellipsis.  You can force the symbol data for that frame's
source file to be read by selecting the frame.  (See section
Selection).

     Here is an example of a backtrace.  It  was  made  with
the command `bt 3', so it shows the innermost three frames.


    #0  rtx_equal_p (x=(rtx) 0x8e58c, y=(rtx) 0x1086c4) (/gp/rms/cc/rtlanal.c line 337)
    #1  0x246b0 in expand_call (...) (...)
    #2  0x21cfc in expand_expr (...) (...)
    (More stack frames follow...)


GGDDBB MMaannuuaall                                                3333


The functions expand_call and  expand_expr  are  in  a  file
whose  symbol details have not been fully read.  Full detail
is available for the function rtx_equal_p, which is  in  the
file  `rtlanal.c'.   Its arguments, named x and y, are shown
with their typed values.

66..33..  SSeelleeccttiinngg aa FFrraammee

     Most commands for examining the stack and other data in
the program work on whichever stack frame is selected at the
moment.  Here are the commands for selecting a stack  frame;
all  of  them  finish by printing a brief description of the
stack frame just selected.

     frame _n
          Select frame number _n.  Recall that frame zero  is
          the  innermost  (currently executing) frame, frame
          one is the frame that called  the  innermost  one,
          and  so  on.  The highest-numbered frame is main's
          frame.

     frame _a_d_d_r
          Select the frame at address _a_d_d_r.  This is  useful
          mainly  if  the  chaining of stack frames has been
          damaged by a bug, making it impossible for GDB  to
          assign  numbers  properly to all frames.  In addi-
          tion, this can be useful when the program has mul-
          tiple stacks and switches between them.

     up _n
          Select the frame _n frames up from the frame previ-
          ously  selected.  For positive numbers _n, this ad-
          vances toward the outermost frame, to higher frame
          numbers,  to  frames  that have existed longer.  _n
          defaults to one.

     down _n
          Select the frame _n frames down from the frame pre-
          viously  selected.   For  positive numbers _n, this
          advances toward  the  innermost  frame,  to  lower
          frame  numbers,  to  frames that were created more
          recently.  _n defaults to one.


     All of these commands end by printing some  information
on  the  frame that has been selected: the frame number, the
function name, the  arguments,  the  source  file  and  line
number  of  execution  in  that  frame, and the text of that
source line.  For example:


    #3  main (argc=3, argv=??, env=??) at main.c, line 67


3344                                                GGDDBB MMaannuuaall


    67        read_input_file (argv[i]);


     After such a printout, the `list' command with no argu-
ments  will  print ten lines centered on the point of execu-
tion in the frame.  See section List.

66..44..  IInnffoorrmmaattiioonn oonn aa FFrraammee

     There are several other commands to  print  information
about the selected stack frame.

     frame
          This command prints a  brief  description  of  the
          selected  stack frame.  It can be abbreviated `f'.
          With an argument, this command is used to select a
          stack  frame; with no argument, it does not change
          which frame is selected, but still prints the same
          information.

     info frame
          This command prints a verbose description  of  the
          selected stack frame, including the address of the
          frame, the addresses of the next frame in  (called
          by  this  frame) and the next frame out (caller of
          this frame), the address of the frame's arguments,
          the  program  counter  saved in it (the address of
          execution in the caller frame), and  which  regis-
          ters   were  saved  in  the  frame.   The  verbose
          description is  useful  when  something  has  gone
          wrong  that  has made the stack format fail to fit
          the usual conventions.

     info frame _a_d_d_r
          Print a verbose description of the  frame  at  ad-
          dress  _a_d_d_r,  without  selecting  that frame.  The
          selected frame remains unchanged by this command.

     info args
          Print the arguments of the selected frame, each on
          a separate line.

     info locals
          Print the local variables of the  selected  frame,
          each  on a separate line.  These are all variables
          declared static or automatic  within  all  program
          blocks  that  execution in this frame is currently
          inside of.


GGDDBB MMaannuuaall                                                3355


77..  EExxaammiinniinngg SSoouurrccee FFiilleess

     GDB knows which source files your program was  compiled
from,  and can print parts of their text.  When your program
stops, GDB spontaneously prints  the  line  it  stopped  in.
Likewise, when you select a stack frame (see section  Selec-
tion), GDB prints the line which execution in that frame has
stopped  in.   You  can  also print parts of source files by
explicit command.


77..11..  PPrriinnttiinngg SSoouurrccee LLiinneess

     To print lines from a source file, use the `list'  com-
mand  (abbreviated  `l').  There are several ways to specify
what part of the file you want to print.

     Here are the forms of the `list' command most  commonly
used:

     list _l_i_n_e_n_u_m
          Print ten lines centered around line number  _l_i_n_e_-
          _n_u_m in the current source file.

     list _f_u_n_c_t_i_o_n
          Print ten lines centered around the  beginning  of
          function _f_u_n_c_t_i_o_n.

     list
          Print ten more lines.  If the last  lines  printed
          were  printed  with  a `list' command, this prints
          ten lines following the last lines printed; howev-
          er,  if  the last line printed was a solitary line
          printed as part of displaying a stack  frame  (see
          section   Stack),  this  prints ten lines centered
          around that line.

     list -
          Print ten lines just before the lines last  print-
          ed.


     Repeating a `list' command with RET discards the  argu-
ment,  so  it  is equivalent to typing just `list'.  This is
more useful than listing the same lines again.  An exception
is  made  for an argument of `-'; that argument is preserved
in repetition so that each repetition moves up in the file.

     In general, the `list' command expects  you  to  supply
zero, one or two _l_i_n_e_s_p_e_c_s.  Linespecs specify source lines;
there are several ways of writing them  but  the  effect  is
always  to  specify  some  source  line.  Here is a complete
description of the possible arguments for `list':


3366                                                GGDDBB MMaannuuaall


     list _l_i_n_e_s_p_e_c
          Print ten lines centered around the line specified
          by _l_i_n_e_s_p_e_c.

     list _f_i_r_s_t,_l_a_s_t
          Print lines from _f_i_r_s_t to  _l_a_s_t.   Both  arguments
          are linespecs.

     list ,_l_a_s_t
          Print ten lines ending with _l_a_s_t.

     list _f_i_r_s_t,
          Print ten lines starting with _f_i_r_s_t.

     list +
          Print ten lines just after the lines last printed.

     list -
          Print ten lines just before the lines last  print-
          ed.

     list
          As described in the preceding table.


     Here are the ways of specifying a single source  line--
-all the kinds of linespec.

     _l_i_n_e_n_u_m
          Specifies line _l_i_n_e_n_u_m of the current source file.
          When  a  `list'  command  has  two linespecs, this
          refers to  the  same  source  file  as  the  first
          linespec.

     +_o_f_f_s_e_t
          Specifies the line _o_f_f_s_e_t  lines  after  the  last
          line printed.  When used as the second linespec in
          a `list' command that has two, this specifies  the
          line _o_f_f_s_e_t lines down from the first linespec.

     -_o_f_f_s_e_t
          Specifies the line _o_f_f_s_e_t lines  before  the  last
          line printed.

     _f_i_l_e_n_a_m_e:_l_i_n_e_n_u_m
          Specifies  line  _l_i_n_e_n_u_m  in   the   source   file
          _f_i_l_e_n_a_m_e.

     _f_u_n_c_t_i_o_n
          Specifies the line of the open-brace  that  begins
          the body of the function _f_u_n_c_t_i_o_n.

     _f_i_l_e_n_a_m_e:_f_u_n_c_t_i_o_n
          Specifies the line of the open-brace  that  begins


GGDDBB MMaannuuaall                                                3377


          the  body  of  the  function  _f_u_n_c_t_i_o_n in the file
          _f_i_l_e_n_a_m_e.  The file name is needed with a function
          name  only for disambiguation of identically named
          functions in different source files.

     *_a_d_d_r_e_s_s
          Specifies the line containing the program  address
          _a_d_d_r_e_s_s.  _a_d_d_r_e_s_s may be any expression.


     One other command is used to map source lines  to  pro-
gram addresses.

     info line _l_i_n_e_n_u_m
          Print the starting and  ending  addresses  of  the
          compiled code for source line _l_i_n_e_n_u_m.

          The default examine address for the `x' command is
          changed  to  the  starting address of the line, so
          that `x/i' is sufficient to  begin  examining  the
          machine  code  (see  section  Memory).  Also, this
          address is saved as the value of  the  convenience
          variable $_ (see section  Convenience Vars).


77..22..  SSeeaarrcchhiinngg SSoouurrccee FFiilleess

     There  are  two  commands  for  searching  through  the
current source file for a regular expression.

     The command `forward-search _r_e_g_e_x_p' checks  each  line,
starting  with the one following the last line listed, for a
match for _r_e_g_e_x_p.  It lists the line that is found.  You can
abbreviate the command name as `fo'.

     The command `reverse-search _r_e_g_e_x_p' checks  each  line,
starting  with the one before the last line listed and going
backward, for a match for _r_e_g_e_x_p.  It lists the line that is
found.   You  can  abbreviate this command with as little as
`rev'.

77..33..  SSppeecciiffyyiinngg SSoouurrccee DDiirreeccttoorriieess

     Executable programs do not record  the  directories  of
the  source  files  from  which they were compiled, just the
names.  GDB remembers a list of directories  to  search  for
source files; this is called the _s_o_u_r_c_e _p_a_t_h.  Each time GDB
wants a source file, it tries all  the  directories  in  the
list,  in  the  order they are present in the list, until it
finds a file with the desired name.  NNoottee tthhaatt  tthhee  eexxeeccuutt--
aabbllee  sseeaarrcchh  ppaatthh iiss _n_o_t uusseedd ffoorr tthhiiss ppuurrppoossee..  NNeeiitthheerr iiss
tthhee ccuurrrreenntt wwoorrkkiinngg ddiirreeccttoorryy,, uunnlleessss iitt hhaappppeennss  ttoo  bbee  iinn
tthhee ssoouurrccee ppaatthh..


3388                                                GGDDBB MMaannuuaall


     When you start GDB, its source path contains  just  the
current  working  directory.   To add other directories, use
the `directory' command.

     directory _d_i_r_n_a_m_e_s...
          Add directory _d_i_r_n_a_m_e to the  end  of  the  source
          path.   Several  directory  names  may be given to
          this command, separated by whitespace or `:'.

     directory
          Reset the source path to just the current  working
          directory of GDB.  This requires confirmation.

          Since this command deletes  directories  from  the
          search  path, it may change the directory in which
          a previously read source file will be  discovered.
          To  make  this  work  correctly, this command also
          clears out the  tables  GDB  maintains  about  the
          source files it has already found.

     info directories
          Print the source path: show which  directories  it
          contains.


     Because the `directory' command adds to the end of  the
source  path,  it  does  not  affect  any  file that GDB has
already found.  If the source path contains directories that
you  do  not  want, and these directories contain misleading
files with names matching your  source  files,  the  way  to
correct the situation is as follows:

     1.   Choose the directory you want at the beginning  of
          the  source  path.   Use  the `cd' command to make
          that the current working directory.

     2.   Use `directory' with  no  argument  to  reset  the
          source path to just that directory.

     3.   Use `directory' with suitable arguments to add any
          other directories you want in the source path.


88..  EExxaammiinniinngg DDaattaa

     The usual way to examine data in your program  is  with
the  `print'  command  (abbreviated  `p').  It evaluates and
prints the value of any valid expression of the language the
program is written in (for now, C).  You type


    print _e_x_p


GGDDBB MMaannuuaall                                                3399


where _e_x_p is any valid expression, and the value of  _e_x_p  is
printed in a format appropriate to its data type.

     A more low-level way of examining data is with the  `x'
command.   It examines data in memory at a specified address
and prints it in a specified format.

88..11..  EExxpprreessssiioonnss

     Many different GDB commands accept  an  expression  and
compute its value.  Any kind of constant, variable or opera-
tor defined by the programming language  you  are  using  is
legal  in  an  expression in GDB.  This includes conditional
expressions, function calls, casts and string constants.  It
unfortunately does not include symbols defined by preproces-
sor #define commands.

     Casts are supported in all languages, not  just  in  C,
because  it  is so useful to cast a number into a pointer so
as to examine a structure at that address in memory.

     GDB supports three kinds of  operator  in  addition  to
those of programming languages:

     @    `@' is a binary operator  for  treating  parts  of
          memory  as  arrays.   See section Arrays, for more
          information.

     ::   `::' allows you to specify a variable in terms  of
          the  file  or function it is defined in.  See sec-
          tion Variables.

     {_t_y_p_e} _a_d_d_r
          Refers to an object of type _t_y_p_e stored at address
          _a_d_d_r  in memory.  _a_d_d_r may be any expression whose
          value is an integer or  pointer  (but  parentheses
          are required around nonunary operators, just as in
          a cast).  This construct is allowed regardless  of
          what kind of data is officially supposed to reside
          at _a_d_d_r.


88..22..  PPrrooggrraamm VVaarriiaabblleess

     The most common kind of expression to use is  the  name
of a variable in your program.

     Variables in expressions are understood in the selected
stack  frame  (see  section  Selection); they must either be
global (or static) or be  visible  according  to  the  scope
rules  of  the programming language from the point of execu-
tion in that frame.  This means that in the function


4400                                                GGDDBB MMaannuuaall


    foo (a)
         int a;
    {
      bar (a);
      {
        int b = test ();
        bar (b);
      }
    }


the variable a is usable whenever the program  is  executing
within  the function foo, but the variable b is visible only
while the program is executing inside the block in  which  b
is declared.

     As a special exception, you can refer to a variable  or
function  whose  scope  is  a single source file even if the
current execution point is not in this file.  But it is pos-
sible  to  have more than one such variable or function with
the same name (if they are in different source  files).   In
such  a  case, it is not defined which one you will get.  If
you wish, you can specify any one of them using  the  colon-
colon construct:


    _b_l_o_c_k::_v_a_r_i_a_b_l_e


Here _b_l_o_c_k is the name of the source file whose variable you
want.

88..33..  AArrttiiffiicciiaall AArrrraayyss

     It is often useful  to  print  out  several  successive
objects  of  the same type in memory; a section of an array,
or an array of dynamically determined size for which only  a
pointer exists in the program.

     This can be done by constructing  an  _a_r_t_i_f_i_c_i_a_l  _a_r_r_a_y
with  the  binary  operator  `@'.   The  left operand of `@'
should be the first element of  the  desired  array,  as  an
individual  object.   The right operand should be the length
of the array.  The result is an array value  whose  elements
are all of the type of the left argument.  The first element
is actually the left argument; the second element comes from
bytes  of  memory  immediately following those that hold the
first element, and so on.  Here is an example.  If a program
says


GGDDBB MMaannuuaall                                                4411


    int *array = (int *) malloc (len * sizeof (int));


you can print the contents of array with


    p *array@len


     The left operand of `@' must reside in  memory.   Array
values  made  with  `@'  in  this way behave just like other
arrays in terms of subscripting, and are coerced to pointers
when  used  in expressions.  (It would probably appear in an
expression via the value history, after you had  printed  it
out.)

88..44..  FFoorrmmaatt ooppttiioonnss

     GDB provides a few  ways  to  control  how  arrays  and
structures are printed.

     info format
          Display the current settings for  the  format  op-
          tions.

     set array-max _n_u_m_b_e_r-_o_f-_e_l_e_m_e_n_t_s
          If GDB is printing a large  array,  it  will  stop
          printing  after  it has printed the number of ele-
          ments set by the `set  array-max'  command.   This
          limit also applies to the display of strings.

     set prettyprint on
          Cause GDB to print structures in an indented  for-
          mat with one member per line, like this:


              $1 = {
                next = 0x0,
                flags = {
                  sweet = 1,
                  sour = 1
                },
                meat = 0x54 "Pork"
              }


     set prettyprint off
          Cause GDB to print  structures  in  a  compact
          format, like this:


4422                                                GGDDBB MMaannuuaall


              $1 = {next = 0x0, flags = {sweet = 1, sour = 1}, meat = 0x54 "Pork"}


          This is the default format.

     set unionprint on
          Tell GDB to print unions which  are  contained
          in structures.  This is the default setting.

     set unionprint off
          Tell GDB not to print unions  which  are  con-
          tained in structures.

          For example, given the declarations


              typedef enum {Tree, Bug} Species;
              typedef enum {Big_tree, Acorn, Seedling} Tree_forms;
              typedef enum {Caterpiller, Cocoon, Butterfly} Bug_forms;

              struct thing {
                Species it;
                union {
                  Tree_forms tree;
                  Bug_forms bug;
                } form;
              };

              struct thing foo = {Tree, {Acorn}};


     with `set unionprint on' in effect  `p  foo'  would
     print


              $1 = {it = Tree, form = {tree = Acorn, bug = Cocoon}}


     and with `set unionprint off' in  effect  it  would
     print


              $1 = {it = Tree, form = {...}}


GGDDBB MMaannuuaall                                                4433


88..55..  OOuuttppuutt ffoorrmmaattss

     GDB normally prints all values according to their  data
types.   Sometimes  this is not what you want.  For example,
you might want to print a number in hex,  or  a  pointer  in
decimal.  Or you might want to view data in memory at a cer-
tain address as a character string or an instruction.  These
things can be done with _o_u_t_p_u_t _f_o_r_m_a_t_s.

     The simplest use of output formats is  to  say  how  to
print  a  value  already computed.  This is done by starting
the arguments of the `print' command with a slash and a for-
mat letter.  The format letters supported are:

     `x'  Regard the bits of the value as  an  integer,  and
          print the integer in hexadecimal.

     `d'  Print as integer in signed decimal.

     `u'  Print as integer in unsigned decimal.

     `o'  Print as integer in octal.

     `a'  Print as an address, both absolute in hex and then
          relative  to  a symbol defined as an address below
          it.

     `c'  Regard as an integer and print it as  a  character
          constant.

     `f'  Regard the bits of the value as a  floating  point
          number and print using typical floating point syn-
          tax.


     For example, to print the program counter in  hex  (see
section  Registers), type


    p/x $pc


Note that no space is required before  the  slash;  this  is
because command names in GDB cannot contain a slash.

     To reprint the last value in the value history  with  a
different  format, you can use the `print' command with just
a format and no expression.  For example, `p/x' reprints the
last value in hex.


4444                                                GGDDBB MMaannuuaall


88..55..11..  EExxaammiinniinngg MMeemmoorryy

     The command `x' (for `examine') can be used to  examine
memory  without  reference to the program's data types.  The
format in which you wish to examine memory is instead expli-
citly  specified.   The  allowable formats are a superset of
the formats described in the previous section.

     `x' is followed by a slash and an output format specif-
ication,  followed  by  an  expression  for an address.  The
expression need not have a pointer value (though it may); it
is  used  as an integer, as the address of a byte of memory.
See section Expressions for more information on expressions.
For  example,  `x/4xw  $sp'  prints the four words of memory
above the stack pointer in hexadecimal.

     The output format in this case specifies both how big a
unit  of  memory to examine and how to print the contents of
that unit.  It is done with one  or  two  of  the  following
letters:

     These letters specify just the size of unit to examine:

     `b'  Examine individual bytes.

     `h'  Examine halfwords (two bytes each).

     `w'  Examine words (four bytes each).

          Many assemblers and cpu designers still use `word'
          for a 16-bit quantity, as a holdover from specific
          predecessor machines of the 1970's that really did
          use  two-byte  words.  But more generally the term
          `word' has always referred to the size of quantity
          that  a machine normally operates on and stores in
          its registers.   This  is  32  bits  for  all  the
          machines that GDB runs on.

     `g'  Examine giant words (8 bytes).


     These letters specify just the way to  print  the  con-
tents:

     `x'  Print as integers in unsigned hexadecimal.

     `d'  Print as integers in signed decimal.

     `u'  Print as integers in unsigned decimal.

     `o'  Print as integers in unsigned octal.

     `a'  Print as an address, both absolute in hex and then
          relative  to  a symbol defined as an address below


GGDDBB MMaannuuaall                                                4455


          it.

     `c'  Print as character constants.

     `f'  Print as floating point.   This  works  only  with
          sizes `w' and `g'.

     `s'  Print a null-terminated string of characters.  The
          specified  unit size is ignored; instead, the unit
          is however many bytes it takes  to  reach  a  null
          character (including the null character).

     `i'  Print a machine instruction  in  assembler  syntax
          (or  nearly).  The specified unit size is ignored;
          the number  of  bytes  in  an  instruction  varies
          depending  on  the type of machine, the opcode and
          the addressing modes used.


     If either the manner of printing or the  size  of  unit
fails  to  be  specified, the default is to use the same one
that was used last.  If you don't want to  use  any  letters
after the slash, you can omit the slash as well.

     You can also omit the address  to  examine.   Then  the
address  used is just after the last unit examined.  This is
why string and instruction formats actually compute a  unit-
size  based on the data: so that the next string or instruc-
tion examined will start in the right  place.   The  `print'
command  sometimes sets the default address for the `x' com-
mand; when the value printed resides in memory, the  default
is  set to examine the same location.  `info line' also sets
the default for `x', to the address  of  the  start  of  the
machine  code  for the specified line and `info breakpoints'
sets it to the address of the last breakpoint listed.

     When you use RET to repeat an `x' command, it does  not
repeat  exactly  the  same: the address specified previously
(if any) is ignored, so that the repeated  command  examines
the  successive  locations  in  memory  rather than the same
ones.

     You can examine several  consecutive  units  of  memory
with  one  command by writing a repeat-count after the slash
(before the format letters, if any).  The repeat count  must
be  a  decimal integer.  It has the same effect as repeating
the `x' command that many times except that the  output  may
be more compact with several units per line.  For example,


    x/10i $pc


4466                                                GGDDBB MMaannuuaall


prints ten instructions starting with the one to be executed
next  in  the  selected  frame.  After doing this, you could
print another ten following instructions with


    x/10


in which the format and address are allowed to default.

     The addresses and contents printed by the  `x'  command
are  not put in the value history because there is often too
much of them and they would get in the  way.   Instead,  GDB
makes  these  values available for subsequent use in expres-
sions as values of the convenience variables $_ and $__.

     After an `x' command,  the  last  address  examined  is
available for use in expressions in the convenience variable
$_.  The contents of that address, as examined,  are  avail-
able in the convenience variable $__.

     If the `x' command has a repeat count, the address  and
contents  saved  are from the last memory unit printed; this
is not the same as the last address printed if several units
were printed on the last line of output.

     The specialized command `disassemble' is also  provided
to  dump  a  range  of  memory as machine instructions.  The
default memory range is the function surrounding the program
counter  of  the  selected frame.  A single argument to this
command is a program counter value; the function surrounding
this value will be dumped.  Two arguments specify a range of
addresss (first inclusive, second exclusive) to be dumped.

88..66..  AAuuttoommaattiicc DDiissppllaayy

     If you find that you want to  print  the  value  of  an
expression  frequently  (to  see  how it changes), you might
want to add it to the _a_u_t_o_m_a_t_i_c _d_i_s_p_l_a_y  _l_i_s_t  so  that  GDB
will  print  its  value  each  time the program stops.  Each
expression added to the list is given a number  to  identify
it;  to remove an expression from the list, you specify that
number.  The automatic display looks like this:


    2: foo = 38
    3: bar[5] = (struct hack *) 0x3804


showing item numbers, expressions and their current values.


GGDDBB MMaannuuaall                                                4477


     If the expression refers to local  variables,  then  it
does not make sense outside the lexical context for which it
was set up.  Such an expression is printed only when  execu-
tion  is  inside  that lexical context.  For example, if you
give the command `display name' while inside a function with
an argument name, then this argument will be displayed when-
ever the program stops inside that function, but not when it
stops  elsewhere  (since  this  argument doesn't exist else-
where).

     display _e_x_p
          Add the expression _e_x_p to the list of  expressions
          to  display each time the program stops.  See sec-
          tion Expressions.

     display/_f_m_t _e_x_p
          For _f_m_t specifying only a display format and not a
          size  or  count,  add  the  expression  _e_x_p to the
          auto-display list but arranges to display it  each
          time in the specified format _f_m_t.

     display/_f_m_t _a_d_d_r
          For _f_m_t `i' or `s', or including a unit-size or  a
          number  of  units,  add  the  expression _a_d_d_r as a
          memory address to be examined each time  the  pro-
          gram  stops.   Examining  means  in  effect  doing
          `x/_f_m_t _a_d_d_r'.  See section Memory.

     undisplay _d_n_u_m_s...

     delete display _d_n_u_m_s...
          Remove item numbers _d_n_u_m_s from the list of expres-
          sions to display.

     disable display _d_n_u_m_s...
          Disable the display of item numbers _d_n_u_m_s.  A dis-
          abled  display  item is not printed automatically,
          but is not forgotten.  It may be reenabled later.

     enable display _d_n_u_m_s...
          Enable display of item numbers _d_n_u_m_s.  It  becomes
          effective  once  again  in auto display of its ex-
          pression, until you specify otherwise.

     display
          Display the current values of the  expressions  on
          the list, just as is done when the program stops.

     info display
          Print the list of expressions previously set up to
          display  automatically,  each  one  with  its item
          number, but without showing the values.  This  in-
          cludes  disabled  expressions, which are marked as
          such.  It also includes  expressions  which  would


4488                                                GGDDBB MMaannuuaall


          not  be  displayed right now because they refer to
          automatic variables not currently available.


88..77..  VVaalluuee HHiissttoorryy

     Every value printed by the `print' command is saved for
the  entire  session  in GDB's _v_a_l_u_e _h_i_s_t_o_r_y so that you can
refer to it in other expressions.

     The values printed are given _h_i_s_t_o_r_y _n_u_m_b_e_r_s for you to
refer  to  them  by.  These are successive integers starting
with 1.  `print' shows you the history number assigned to  a
value  by  printing  `$_n_u_m = ' before the value; here _n_u_m is
the history number.

     To refer to any previous value, use `$' followed by the
value's  history  number.   The output printed by `print' is
designed to remind you of this.  Just $ refers to  the  most
recent  value  in  the  history,  and $$ refers to the value
before that.

     For example, suppose you have just printed a pointer to
a  structure  and want to see the contents of the structure.
It suffices to type


    p *$


     If you have a chain of structures where  the  component
`next' points to the next one, you can print the contents of
the next one with this:


    p *$.next


It might be useful to repeat this command many times by typ-
ing RET.

     Note that the history records values, not  expressions.
If the value of x is 4 and you type this command:


    print x
    set x=5


then the value recorded in the value history by the  `print'
command remains 4 even though the value of x has changed.


GGDDBB MMaannuuaall                                                4499


     info values
          Print the last ten values in  the  value  history,
          with their item numbers.  This is like `p $$9' re-
          peated ten times, except that `info  values'  does
          not change the history.

     info values _n
          Print ten history values centered on history  item
          number _n.

     info values +
          Print ten history values  just  after  the  values
          last printed.


88..88..  CCoonnvveenniieennccee VVaarriiaabblleess

     GDB provides _c_o_n_v_e_n_i_e_n_c_e _v_a_r_i_a_b_l_e_s  that  you  can  use
within  GDB  to  hold  on  to a value and refer to it later.
These variables exist entirely within GDB; they are not part
of  your  program, and setting a convenience variable has no
effect on further execution of your program.  That's why you
can use them freely.

     Convenience variables have  names  starting  with  `$'.
Any  name  starting  with  `$' can be used for a convenience
variable, unless it is one of the predefined set of register
names (see section  Registers).

     You can save a value in a convenience variable with  an
assignment  expression,  just as you would set a variable in
your program.  Example:


    set $foo = *object_ptr


would save in $foo the value contained in the object pointed
to by object_ptr.

     Using a convenience variable for the first time creates
it; but its value is void until you assign a new value.  You
can alter the value with another assignment at any time.

     Convenience variables have no  fixed  types.   You  can
assign  a convenience variable any type of value, even if it
already has a value of a different  type.   The  convenience
variable  as  an  expression  has  whatever type its current
value has.

     info convenience
          Print a list of convenience variables used so far,
          and their values.  Abbreviated `i con'.


5500                                                GGDDBB MMaannuuaall


     One of the ways to use a convenience variable is  as  a
counter  to be incremented or a pointer to be advanced.  For
example:


    set $i = 0
    print bar[$i++]->contents
    ..._r_e_p_e_a_t _t_h_a_t _c_o_m_m_a_n_d _b_y _t_y_p_i_n_g RET.


     Some convenience variables are created automatically by
GDB and given values likely to be useful.

     $_   The variable $_ is automatically set  by  the  `x'
          command  to the last address examined (see section
          Memory).  Other commands which provide  a  default
          address for `x' to examine also set $_ to that ad-
          dress; these commands include `info line' and `in-
          fo breakpoint'.

     $__  The variable $__ is automatically set by  the  `x'
          command to the value found in the last address ex-
          amined.


88..99..  RReeggiisstteerrss

     Machine register contents can be referred to in expres-
sions  as variables with names starting with `$'.  The names
of registers are  different  for  each  machine;  use  `info
registers' to see the names used on your machine.  The names
$pc and $sp are used on all machines for the program counter
register  and  the  stack  pointer.  Often $fp is used for a
register that contains a pointer to the current stack frame,
and  $ps  is used for a register that contains the processor
status.  These standard register names may be  available  on
your machine even though the info registers command displays
them with a different name.  For example, on the SPARC, info
registers displays the processor status register as $psr but
you can also refer to it as $ps.

     GDB always considers the contents of an ordinary regis-
ter as an integer when the register is examined in this way.
Some machines have special registers which can hold  nothing
but  floating point; these registers are considered floating
point.  There is no way to refer to the contents of an ordi-
nary  register  as  floating  point  value (although you can
_p_r_i_n_t it as a floating point value with `print/f $_r_e_g_n_a_m_e').

     Some registers have distinct  ``raw''  and  ``virtual''
data  formats.  This means that the data format in which the
register contents are saved by the operating system  is  not
the  same one that your program normally sees.  For example,


GGDDBB MMaannuuaall                                                5511


the registers of the 68881 floating  point  coprocessor  are
always  saved  in  ``extended''  format,  but all C programs
expect to work with ``double'' format.  In such  cases,  GDB
normally works with the virtual format only (the format that
makes sense for your program), but the `info registers' com-
mand prints the data in both formats.

     Register values are  relative  to  the  selected  stack
frame (see section  Selection).  This means that you get the
value that the register would contain if  all  stack  frames
farther  in  were exited and their saved registers restored.
In order to see the real contents of all registers, you must
select the innermost frame (with `frame 0').

     Some registers are never saved  (typically  those  num-
bered zero or one) because they are used for returning func-
tion values; for these registers,  relativization  makes  no
difference.

     info registers
          Print the names and relativized values of all  re-
          gisters.

     info registers _r_e_g_n_a_m_e
          Print the relativized value of  register  _r_e_g_n_a_m_e.
          _r_e_g_n_a_m_e  may  be  any  register  name valid on the
          machine you are using, with or without the initial
          `$'.


88..99..11..  EExxaammpplleess

     You could print the program counter in hex with


    p/x $pc


or print the instruction to be executed next with


    x/i $pc


or add four to the stack pointer with


    set $sp += 4


5522                                                GGDDBB MMaannuuaall


The last is a way of removing one word from  the  stack,  on
machines   where   stacks  grow  downward  in  memory  (most
machines, nowadays).  This assumes that the innermost  stack
frame  is  selected.   Setting $sp is not allowed when other
stack frames are selected.

99..  EExxaammiinniinngg tthhee SSyymmbbooll TTaabbllee

     The commands described in this  section  allow  you  to
make  inquiries  for information about the symbols (names of
variables, functions and types)  defined  in  your  program.
This  information is found by GDB in the symbol table loaded
by the `symbol-file' command; it is inherent in the text  of
your program and does not change as the program executes.

     whatis _e_x_p
          Print the data type of expression _e_x_p.  _e_x_p is not
          actually  evaluated, and any side-effecting opera-
          tions (such as assignments or function calls)  in-
          side  it  do  not take place.  See section Expres-
          sions.

     whatis
          Print the data type of $, the last  value  in  the
          value history.

     info address _s_y_m_b_o_l
          Describe where the data for _s_y_m_b_o_l is stored.  For
          a  register  variable, this says which register it
          is kept in.  For a  non-register  local  variable,
          this  prints  the  stack-frame offset at which the
          variable is always stored.

          Note the contrast with `print &_s_y_m_b_o_l', which does
          not  work at all for a register variables, and for
          a stack local variable prints the exact address of
          the current instantiation of the variable.

     ptype _t_y_p_e_n_a_m_e
          Print  a  description  of  data   type   _t_y_p_e_n_a_m_e.
          _t_y_p_e_n_a_m_e  may be the name of a type, or for C code
          it may have the form `struct  _s_t_r_u_c_t-_t_a_g',  `union
          _u_n_i_o_n-_t_a_g' or `enum _e_n_u_m-_t_a_g'.

     info sources
          Print the names of all source files in the program
          for which there is debugging information.

     info functions
          Print the names and  data  types  of  all  defined
          functions.

     info functions _r_e_g_e_x_p
          Print the names and  data  types  of  all  defined


GGDDBB MMaannuuaall                                                5533


          functions  whose names contain a match for regular
          expression _r_e_g_e_x_p.  Thus, `info  fun  step'  finds
          all  functions  whose  names include `step'; `info
          fun ^step' finds  those  whose  names  start  with
          `step'.

     info variables
          Print the names and data types  of  all  variables
          that  are declared outside of functions (i.e., ex-
          cept for local variables).

     info variables _r_e_g_e_x_p
          Print the names and data types  of  all  variables
          (except for local variables) whose names contain a
          match for regular expression _r_e_g_e_x_p.

     info types
          Print all data types that are defined in the  pro-
          gram.

     info types _r_e_g_e_x_p
          Print all data types that are defined in the  pro-
          gram  whose  names contain a match for regular ex-
          pression _r_e_g_e_x_p.


     printsyms _f_i_l_e_n_a_m_e
          Write a complete dump  of  the  debugger's  symbol
          data into the file _f_i_l_e_n_a_m_e.


1100..  AAlltteerriinngg EExxeeccuuttiioonn

     Once you think you have find an error in  the  program,
you  might  want  to find out for certain whether correcting
the apparent error would lead to correct results in the rest
of  the  run.   You can find the answer by experiment, using
the GDB features for altering execution of the program.

     For example, you can store new values into variables or
memory locations, give the program a signal, restart it at a
different address, or even return prematurely from  a  func-
tion to its caller.

1100..11..  AAssssiiggnnmmeenntt ttoo VVaarriiaabblleess

     To alter the value of a variable, evaluate  an  assign-
ment expression.  See section Expressions.  For example,


    print x=4


5544                                                GGDDBB MMaannuuaall


would store the value 4 into the variable x, and then  print
the value of the assignment expression (which is 4).

     All  the  assignment  operators  of  C  are  supported,
including  the  incrementation  operators `++' and `--', and
combining assignments such as `+=' and `<<='.

     If you are not interested in seeing the  value  of  the
assignment,  use  the  `set'  command instead of the `print'
command.  `set' is really the same as  `print'  except  that
the  expression's value is not printed and is not put in the
value history (see section  Value History).  The  expression
is evaluated only for side effects.

     Note that if the beginning of the  argument  string  of
the  `set'  command appears identical to a `set' subcommand,
it may be necessary to use the `set variable' command.  This
command is identical to `set' except for its lack of subcom-
mands.

     GDB allows more  implicit  conversions  in  assignments
than  C  does;  you can freely store an integer value into a
pointer variable or vice versa, and  any  structure  can  be
converted  to any other structure that is the same length or
shorter.

     To store values into arbitrary places  in  memory,  use
the  `{...}' construct to generate a value of specified type
at a specified  address  (see  section   Expressions).   For
example, {int}0x83040 would refer to memory location 0x83040
as an integer (which implies a certain size and  representa-
tion in memory), and


    set {int}0x83040 = 4


     would store the value 4 into that memory location.

1100..22..  CCoonnttiinnuuiinngg aatt aa DDiiffffeerreenntt AAddddrreessss

     Ordinarily, when you continue the program, you do so at
the  place  where  it stopped, with the `cont' command.  You
can instead continue at an address  of  your  own  choosing,
with the following commands:

     jump _l_i_n_e_n_u_m
          Resume execution at line number  _l_i_n_e_n_u_m.   Execu-
          tion may stop immediately if there is a breakpoint
          there.

          The `jump' command does  not  change  the  current
          stack frame, or the stack pointer, or the contents


GGDDBB MMaannuuaall                                                5555


          of any memory location or any register other  than
          the program counter.  If line _l_i_n_e_n_u_m is in a dif-
          ferent function from the one currently  executing,
          the  results  may  be bizarre if the two functions
          expect different patterns of arguments or of local
          variables.   For  this  reason, the `jump' command
          requests confirmation if the specified line is not
          in  the  function  currently  executing.  However,
          even bizarre  results  are  predictable  based  on
          careful  study of the machine-language code of the
          program.

     jump *_a_d_d_r_e_s_s
          Resume execution at the instruction at address _a_d_-
          _d_r_e_s_s.


     You can get much the same effect as the jump command by
storing  a  new value into the register $pc.  The difference
is that this does not start the  program  running;  it  only
changes  the address where it _w_i_l_l run when it is continued.
For example,


    set $pc = 0x485


causes the next `cont' command or stepping command  to  exe-
cute  at address 0x485, rather than at the address where the
program stopped.  See section Stepping.

     The most common occasion to use the `jump'  command  is
when  you have stepped across a function call with next, and
found that the  return  value  is  incorrect.   If  all  the
relevant data appeared correct before the function call, the
error is probably in the function that just returned.

     In general, your next step would now be  to  rerun  the
program  and execute up to this function call, and then step
into it to see where it goes astray.  But this may  be  time
consuming.   If  the  function did not have significant side
effects, you could get the same information by resuming exe-
cution  just  before  the function call and stepping through
it.  To do this, first put a breakpoint  on  that  function;
then,  use  the  `jump' command to continue on the line with
the function call.


5566                                                GGDDBB MMaannuuaall


1100..33..  GGiivviinngg tthhee PPrrooggrraamm aa SSiiggnnaall

     signal _s_i_g_n_a_l_n_u_m
          Resume execution where the  program  stopped,  but
          give it immediately the signal number _s_i_g_n_a_l_n_u_m.

          Alternatively, if _s_i_g_n_a_l_n_u_m is zero, continue exe-
          cution  without  giving  a signal.  This is useful
          when the program stopped on account  of  a  signal
          and  would  ordinary  see  the signal when resumed
          with the `cont' command; `signal 0' causes  it  to
          resume without a signal.


1100..44..  RReettuurrnniinngg ffrroomm aa FFuunnccttiioonn

     You can cancel execution of a function  call  with  the
`return' command.  This command has the effect of discarding
the selected stack frame (and all frames within it), so that
control moves to the caller of that function.  You can think
of this as making the discarded frame return prematurely.

     First select the stack frame that you  wish  to  return
from  (see section  Selection).  Then type the `return' com-
mand.  If you wish to specify the value to be returned, give
that as an argument.

     This pops the  selected  stack  frame  (and  any  other
frames  inside  of  it), leaving its caller as the innermost
remaining frame.  That frame becomes selected.   The  speci-
fied  value  is  stored  in the registers used for returning
values of functions.

     The `return' command  does  not  resume  execution;  it
leaves  the program stopped in the state that would exist if
the function had just  returned.   Contrast  this  with  the
`finish' command (see section  Stepping), which resumes exe-
cution until the selected stack frame returns _n_a_t_u_r_a_l_l_y.

1111..  CCaannnneedd SSeeqquueenncceess ooff CCoommmmaannddss

     GDB provides two ways to store  sequences  of  commands
for  execution  as a unit: user-defined commands and command
files.

1111..11..  UUsseerr--DDeeffiinneedd CCoommmmaannddss

     A _u_s_e_r-_d_e_f_i_n_e_d _c_o_m_m_a_n_d is a sequence of GDB commands to
which you assign a new name as a command.  This is done with
the `define' command.

     define _c_o_m_m_a_n_d_n_a_m_e
          Define a command named _c_o_m_m_a_n_d_n_a_m_e.  If  there  is
          already  a  command by that name, you are asked to


GGDDBB MMaannuuaall                                                5577


          confirm that you want to redefine it.

          The definition of the command is made up of  other
          GDB  command  lines, which are given following the
          `define' command.  The end of  these  commands  is
          marked by a line containing `end'.

     document _c_o_m_m_a_n_d_n_a_m_e
          Give documentation  to  the  user-defined  command
          _c_o_m_m_a_n_d_n_a_m_e.  The command _c_o_m_m_a_n_d_n_a_m_e must already
          be defined.  This command reads lines of  documen-
          tation  just  as  `define'  reads the lines of the
          command definition, ending with `end'.  After  the
          `document'  command is finished, `help' on command
          _c_o_m_m_a_n_d_n_a_m_e will print the documentation you  have
          specified.

          You may use the `document' command again to change
          the  documentation  of  a command.  Redefining the
          command with `define' does not change the documen-
          tation.


     User-defined commands do not take arguments.  When they
are  executed,  the  commands  of  the  definition  are  not
printed.  An error in any command  stops  execution  of  the
user-defined command.

     Commands  that  would  ask  for  confirmation  if  used
interactively  proceed  without  asking  when  used inside a
user-defined command.  Many GDB commands that normally print
messages  to  say what they are doing omit the messages when
used in user-defined command.

1111..22..  CCoommmmaanndd FFiilleess

     A command file for GDB is a file of lines that are  GDB
commands.   Comments  (lines  starting with `#') may also be
included.  An empty line in a command file does nothing;  it
does  not  mean to repeat the last command, as it would from
the terminal.

     When GDB starts, it  automatically  executes  its  _i_n_i_t
_f_i_l_e_s,  command  files named `.gdbinit'.  GDB reads the init
file (if any) in your home directory and then the init  file
(if  any) in the current working directory.  (The init files
are not executed if the `-nx' option  is  given.)   You  can
also request the execution of a command file with the `sour-
ce' command:

     source _f_i_l_e_n_a_m_e
          Execute the command file _f_i_l_e_n_a_m_e.


5588                                                GGDDBB MMaannuuaall


     The lines in a command file are executed  sequentially.
They  are not printed as they are executed.  An error in any
command terminates execution of the command file.

     Commands  that  would  ask  for  confirmation  if  used
interactively  proceed without asking when used in a command
file.  Many GDB commands that normally print messages to say
what they are doing omit the messages when used in a command
file.

1111..33..  CCoommmmaannddss ffoorr CCoonnttrroolllleedd OOuuttppuutt

     During the execution of  a  command  file  or  a  user-
defined  command,  the  only  output that appears is what is
explicitly printed by the commands of the definition.   This
section  describes  three  commands  useful  for  generating
exactly the output you want.

     echo _t_e_x_t
          Print _t_e_x_t.  Nonprinting characters can be includ-
          ed  in _t_e_x_t using C escape sequences, such as `\n'
          to print a newline.  NNoo nneewwlliinnee  wwiillll  bbee  pprriinntteedd
          uunnlleessss  yyoouu  ssppeecciiffyy oonnee.. In addition to the stan-
          dard C escape sequences a backslash followed by  a
          space stands for a space.  This is useful for out-
          putting a string with spaces at the  beginning  or
          the  end,  since  leading  and trailing spaces are
          trimmed from all arguments.  Thus, to  print    ``
          and foo = '' , use the command  ``echo \ and foo =
          \ ''

          A backslash at the end of _t_e_x_t can be used, as  in
          C,  to continue the command onto subsequent lines.
          For example,


              echo This is some text\n\
              which is continued\n\
              onto several lines.\n


          produces the same output as


              echo This is some text\n
              echo which is continued\n
              echo onto several lines.\n


     output _e_x_p_r_e_s_s_i_o_n
          Print the value of _e_x_p_r_e_s_s_i_o_n and nothing  but
          that  value:  no  newlines,  no `$_n_n = '.  The


GGDDBB MMaannuuaall                                                5599


          value is not entered in the value history  ei-
          ther.  See section Expressions for more infor-
          mation on expressions.

     output/_f_m_t _e_x_p_r_e_s_s_i_o_n
          Print the value of _e_x_p_r_e_s_s_i_o_n in  format  _f_m_t.
          See  section Output formats, for more informa-
          tion.

     printf _s_t_r_i_n_g, _e_x_p_r_e_s_s_i_o_n_s...
          Print the values of the _e_x_p_r_e_s_s_i_o_n_s under  the
          control   of   _s_t_r_i_n_g.   The  _e_x_p_r_e_s_s_i_o_n_s  are
          separated by commas and may be either  numbers
          or  pointers.   Their  values  are  printed as
          specified by _s_t_r_i_n_g, exactly as if the program
          were to execute


              printf (_s_t_r_i_n_g, _e_x_p_r_e_s_s_i_o_n_s...);


          For example, you can print two values  in  hex
          like this:


              printf "foo, bar-foo = 0x%x, 0x%x\n", foo, bar-foo


          The only backslash-escape sequences  that  you
          can use in the string are the simple ones that
          consist of backslash followed by a letter.


1122..  OOppttiioonnss aanndd AArrgguummeennttss ffoorr GGDDBB

     When you invoke GDB, you can specify arguments  telling
it what files to operate on and what other things to do.

1122..11..  MMooddee OOppttiioonnss

     `-nx'
          Do  not  execute  commands  from  the  init  files
          `.gdbinit'.  Normally, the commands in these files
          are executed after all the command options and ar-
          guments  have been processed.  See section Command
          Files.

     `-q'
          ``Quiet''.  Do not print  the  usual  introductory
          messages.


6600                                                GGDDBB MMaannuuaall


     `-batch'
          Run in batch mode.  Exit with code  0  after  pro-
          cessing  all the command files specified with `-x'
          (and `.gdbinit', if  not  inhibited).   Exit  with
          nonzero status if an error occurs in executing the
          GDB commands in the command files.

     `-fullname'
          This option is used when Emacs runs GDB as a  sub-
          process.   It  tells  GDB  to output the full file
          name and line number in a  standard,  recognizable
          fashion  each  time  a  stack  frame  is displayed
          (which includes  each  time  the  program  stops).
          This  recognizable  format  looks  like two `\032'
          characters, followed by the file name, line number
          and  character position separated by colons, and a
          newline.  The Emacs-to-GDB interface program  uses
          the  two  `\032' characters as a signal to display
          the source code for the frame.


1122..22..  FFiillee--ssppeecciiffyyiinngg OOppttiioonnss

     All the options and command line  arguments  given  are
processed in sequential order.  The order makes a difference
when the `-x' option is used.

     `-s _f_i_l_e'
          Read symbol table from file _f_i_l_e.

     `-e _f_i_l_e'
          Use file _f_i_l_e as the executable  file  to  execute
          when  appropriate,  and for examining pure data in
          conjunction with a core dump.

     `-se _f_i_l_e'
          Read symbol table from file _f_i_l_e and use it as the
          executable file.

     `-c _f_i_l_e'
          Use file _f_i_l_e as a core dump to examine.

     `-x _f_i_l_e'
          Execute GDB commands from file _f_i_l_e.

     `-d _d_i_r_e_c_t_o_r_y'
          Add _d_i_r_e_c_t_o_r_y to the path  to  search  for  source
          files.


GGDDBB MMaannuuaall                                                6611


1122..33..  OOtthheerr AArrgguummeennttss

     If there are arguments to GDB that are not  options  or
associated  with options, the first one specifies the symbol
table and executable file name (as if it  were  preceded  by
`-se')  and  the  second one specifies a core dump file name
(as if it were preceded by `-c').

1133..  UUssiinngg GGDDBB uunnddeerr GGNNUU EEmmaaccss

     A special interface allows you to use GNU Emacs to view
(and  edit)  the source files for the program you are debug-
ging with GDB.

     To use this interface,  use  the  command  M-x  gdb  in
Emacs.   Give  the  executable  file you want to debug as an
argument.  This command starts GDB as a subprocess of Emacs,
with input and output through a newly created Emacs buffer.

     Using GDB under Emacs is just like using  GDB  normally
except for two things:

          All ``terminal'' input and output goes through the
          Emacs  buffer.   This applies both to GDB commands
          and their output, and to the input and output done
          by the program you are debugging.

          This is useful because it means that you can  copy
          the  text  of  previous  commands  and  input them
          again; you can even use parts  of  the  output  in
          this way.

          All the  facilities  of  Emacs's  Shell  mode  are
          available for this purpose.

          GDB displays source code through Emacs.  Each time
          GDB  displays  a  stack frame, Emacs automatically
          finds the source file for that frame and  puts  an
          arrow  (`=>')  at  the  left margin of the current
          line.

          Explicit GDB `list' or search commands still  pro-
          duce  output  as usual, but you probably will have
          no reason to use them.


     In the GDB I/O buffer, you can use these special  Emacs
commands:

     M-s  Execute to  another  source  line,  like  the  GDB
          `step' command.

     M-n  Execute to next  source  line  in  this  function,
          skipping  all  function calls, like the GDB `next'


6622                                                GGDDBB MMaannuuaall


          command.

     M-i  Execute one instruction, like the GDB `stepi' com-
          mand.

     C-c C-f
          Execute until exit from the selected stack  frame,
          like the GDB `finish' command.

     M-c  Continue execution of the program,  like  the  GDB
          `cont' command.

     M-u  Go up the number of frames indicated by the numer-
          ic argument (see section  Arguments, , Numeric Ar-
          guments, emacs, The GNU Emacs  Manual),  like  the
          GDB `up' command.

     M-d  Go down the number  of  frames  indicated  by  the
          numeric argument, like the GDB `down' command.


     In any source file, the Emacs  command  C-x  SPC  (gdb-
break)  tells  GDB  to  set  a breakpoint on the source line
point is on.

     The source files displayed in  Emacs  are  in  ordinary
Emacs  buffers  which  are  visiting the source files in the
usual way.  You can edit the files with these buffers if you
wish;  but  keep in mind that GDB communicates with Emacs in
terms of line numbers.  If you add or delete lines from  the
text,  the  line  numbers  that  GDB  knows  will  cease  to
correspond properly to the code.

1144..  RReemmoottee KKeerrnneell DDeebbuuggggiinngg

     If you are trying to  debug  a  program  running  on  a
machine  that  can't  run  GDB in the usual way, it is often
useful to use remote debugging.  For example, you  might  be
debugging  an  operating system kernel, or debugging a small
system which does not have a general purpose operating  sys-
tem   powerful  enough  to  run  a  full-featured  debugger.
Currently GDB supports remote debugging over a  serial  con-
nection.

     The program to be debugged on the remote machine  needs
to contain a debugging device driver which talks to GDB over
the serial line using the  protocol  described  below.   The
same  version of GDB that is used ordinarily can be used for
this.  Several sample remote debugging drivers  are  distri-
buted  with  GDB; see the `README' file in the GDB distribu-
tion for more information.

     For details of the communication protocol, see the com-
ments in the GDB source file `remote.c'.


GGDDBB MMaannuuaall                                                6633


1144..11..  CCoommmmaannddss ffoorr RReemmoottee DDeebbuuggggiinngg

     To start remote debugging, first run GDB and specify as
an executable file the program that is running in the remote
machine.  This tells GDB how to find the  program's  symbols
and  the contents of its pure text.  Then establish communi-
cation using the `attach' command with a device name  rather
than a pid as an argument.  For example:


    attach /dev/ttyd


if  the  serial  line  is  connected  to  the  device  named
`/dev/ttyd'.  This will stop the remote machine if it is not
already stopped.

     Now you can use all the usual commands to  examine  and
change data and to step and continue the remote program.

     To resume the remote program and stop debugging it, use
the `detach' command.


CCoommmmaanndd IInnddeexx

CCoonncceepptt IInnddeexx


GGDDBB MMaannuuaall                                                 ii


                        TTaabbllee ooff CCoonntteennttss


Summary of GDB ........................................    2
GNU GENERAL PUBLIC LICENSE ............................    2
Preamble ..............................................    2
TERMS AND CONDITIONS ..................................    3
NO WARRANTY ...........................................    6
END OF TERMS AND CONDITIONS ...........................    7
Appendix: How to Apply These Terms to Your New Programs
     ..................................................    7
1       GDB Input and Output Conventions ..............    8
2       Specifying GDB's Files ........................   10
2.1      Specifying Files with Arguments ..............   10
2.2      Specifying Files with Commands ...............   10
3       Compiling Your Program for Debugging ..........   12
4       Running Your Program Under GDB ................   13
4.1      Your Program's Arguments .....................   14
4.2      Your Program's Environment ...................   14
4.3      Your Program's Working Directory .............   15
4.4      Your Program's Input and Output ..............   15
4.5      Debugging an Already-Running Process .........   16
4.6      Killing the Child Process ....................   17
5       Stopping and Continuing .......................   17
5.1      Signals ......................................   17
5.2      Breakpoints ..................................   19
5.2.1    Setting Breakpoints ..........................   20
5.2.2    Deleting Breakpoints .........................   21
5.2.3    Disabling Breakpoints ........................   22
5.2.4    Break Conditions .............................   23
5.2.5    Commands Executed on Breaking ................   25
5.2.6    ``Cannot Insert Breakpoints'' Error ..........   27
5.3      Continuing ...................................   27
5.4      Stepping .....................................   28
6       Examining the Stack ...........................   30
6.1      Stack Frames .................................   31
6.2      Backtraces ...................................   32
6.3      Selecting a Frame ............................   33
6.4      Information on a Frame .......................   34
7       Examining Source Files ........................   35
7.1      Printing Source Lines ........................   35
7.2      Searching Source Files .......................   37
7.3      Specifying Source Directories ................   37
8       Examining Data ................................   38
8.1      Expressions ..................................   39
8.2      Program Variables ............................   39
8.3      Artificial Arrays ............................   40
8.4      Format options ...............................   41
8.5      Output formats ...............................   43
8.5.1    Examining Memory .............................   44
8.6      Automatic Display ............................   46
8.7      Value History ................................   48
8.8      Convenience Variables ........................   49
8.9      Registers ....................................   50


iiii                                                GGDDBB MMaannuuaall


8.9.1    Examples .....................................   51
9       Examining the Symbol Table ....................   52
10      Altering Execution ............................   53
10.1      Assignment to Variables .....................   53
10.2      Continuing at a Different Address ...........   54
10.3      Giving the Program a Signal .................   56
10.4      Returning from a Function ...................   56
11      Canned Sequences of Commands ..................   56
11.1      User-Defined Commands .......................   56
11.2      Command Files ...............................   57
11.3      Commands for Controlled Output ..............   58
12      Options and Arguments for GDB .................   59
12.1      Mode Options ................................   59
12.2      File-specifying Options .....................   60
12.3      Other Arguments .............................   61
13      Using GDB under GNU Emacs .....................   61
14      Remote Kernel Debugging .......................   62
14.1      Commands for Remote Debugging ...............   63
Command Index .........................................   63
Concept Index .........................................   63

     Occasionally it is useful to execute  a  shell  command
from within GDB.  This can be done with the `shell' command.

     shell _s_h_e_l_l _c_o_m_m_a_n_d _s_t_r_i_n_g
          Directs GDB to invoke an inferior shell to execute
          _s_h_e_l_l  _c_o_m_m_a_n_d  _s_t_r_i_n_g.   The environment variable
          SHELL is used if it  exists,  otherwise  GDB  uses
          `/bin/sh'.


c abbreviation   8 c repeating commands   8 c prompt    9  k
set  prompt    9  c exiting GDB   9 k quit   9 c screen size
9 c pauses in output   9 k set screensize   9 k set  verbose
9  c  core  dump  file    10 c executable file   10 c symbol
table   10 k exec-file   10 k symbol-file   11  k  core-file
11  k add-file   12 c dynamic linking   12 k info files   12
c running   13 k run   13 c arguments (to your program)   14
k  set args   14 c environment (of your program)   14 k info
environment   14 k set environment   14 k delete environment
15  k  unset  environment    15 c working directory (of your
program)   15 k cd   15 k pwd   15 c redirection   15 c con-
trolling  terminal    15  k  tty   16 k detach   16 k attach
16 c attach   16 k kill   17 c signals   17 c fatal  signals
18  c handling signals   18 k info signal   18 k handle   18
c breakpoints   19 k info break   19 k $_   19 k break    20
k  tbreak    21 c clearing breakpoint   21 c deleting break-
points   21 k clear   21 k delete    22  c  disabled  break-
points   22 c enabled breakpoints   22 k disable breakpoints
23 k disable   23 k enable breakpoints   23 k enable   23  c
conditional  breakpoints   23 c breakpoint conditions   23 k
condition   24 c ignore count (of breakpoint)   24 k  ignore
24  c  breakpoint  commands   25 k silent   25 k cont   27 c
stepping   28 k step   28 k next   28 k finish   28 k  until
29  k  stepi    29  k  si   29 k nexti   30 k ni   30 c call
stack   30 c frame   31 c stack frame   31 c  initial  frame
31  c  outermost  frame    31 c innermost frame   31 c frame
pointer   31 c frame number   31 c  selected  frame    31  c
frameless  execution   31 k backtrace   32 k bt   32 k where
32 k info stack   32 k frame   33 k up   33 k  down    33  k
info  frame    34 k info args   34 k info locals   34 k list
35 c linespec   35 k info line   37 k $_    37  c  searching
37 k forward-search   37 k reverse-search   37 c source path
37 c directories for source files   37 k  directory    38  k
info  directories   38 c printing data   38 c examining data
38 k print   38 c expressions   39 c artificial array   40 c
format  options   41 k info format   41 k set array-max   41
k set prettyprint   41 k set  unionprint    42  c  formatted
output    43 c output formats   43 c examining memory   44 k
x   44 c word   44 k $_   46 k $__   46 k disassemble   46 c
automatic  display    46  c  display  of  expressions   46 k
display   47 k delete display   47 k undisplay   47  k  dis-
able  display   47 k enable display   47 k info display   47
c value history   48 c $   48 c $$    48  c  history  number
48  k  info  values   49 c convenience variables   49 k info
convenience   49 c registers   50 k info  registers    51  k
whatis    52 k info address   52 k ptype   52 k info sources
52 k info functions   52 k info variables   53 k info  types
53  k  printsyms    53 c assignment   53 c setting variables
53 k set   54 k set variable   54 k jump   54 k signal    56
c  returning  from  a  function    56  k return   56 c user-
defined command   56 k define   56 k document   57 c command
files    57 c init file   57 c .gdbinit   57 k source   57 k
echo   58 k output   58 k printf   59 k shell   ii  c  shell
escape   ii