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This is ./gdb.info, produced by makeinfo version 4.0 from gdb.texinfo.
INFO-DIR-SECTION Programming & development tools.
START-INFO-DIR-ENTRY
* Gdb: (gdb). The GNU debugger.
END-INFO-DIR-ENTRY
This file documents the GNU debugger GDB.
This is the Eighth Edition, March 2000, of `Debugging with GDB: the
GNU Source-Level Debugger' for GDB Version 5.0.
Copyright (C) 1988-2000 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 entire resulting derived work is distributed under the terms
of a permission notice identical to this one.
Permission is granted to copy and distribute translations of this
manual into another language, under the above conditions for modified
versions.
File: gdb.info, Node: Conditions, Next: Break Commands, Prev: Disabling, Up: Breakpoints
Break conditions
----------------
The simplest sort of breakpoint breaks every time your program
reaches a specified place. You can also specify a "condition" for a
breakpoint. A condition is just a Boolean expression in your
programming language (*note Expressions: Expressions.). A breakpoint
with a condition evaluates the expression each time your program
reaches it, and your program stops only if the condition is _true_.
This is the converse of using assertions for program validation; in
that situation, you want to stop when the assertion is violated--that
is, when the condition is false. In C, if you want to test an
assertion expressed by the condition ASSERT, you should set the
condition `! ASSERT' on the appropriate breakpoint.
Conditions are also accepted for watchpoints; you may not need them,
since a watchpoint is inspecting the value of an expression anyhow--but
it might be simpler, say, to just set a watchpoint on a variable name,
and specify a condition that tests whether the new value is an
interesting one.
Break conditions can have side effects, and may even call functions
in your program. This can be useful, for example, to activate functions
that log program progress, or to use your own print functions to format
special data structures. The 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 your program
without checking the condition of this one.) Note that breakpoint
commands are usually more convenient and flexible than break conditions
for the purpose of performing side effects when a breakpoint is reached
(*note Breakpoint command lists: Break Commands.).
Break conditions can be specified when a breakpoint is set, by using
`if' in the arguments to the `break' command. *Note Setting
breakpoints: Set Breaks. They can also be changed at any time with the
`condition' command.
You can also use the `if' keyword with the `watch' command. The
`catch' command does not recognize the `if' keyword; `condition' is the
only way to impose a further condition on a catchpoint.
`condition BNUM EXPRESSION'
Specify EXPRESSION as the break condition for breakpoint,
watchpoint, or catchpoint number BNUM. After you set a condition,
breakpoint BNUM stops your program only if the value of EXPRESSION
is true (nonzero, in C). When you use `condition', GDB checks
EXPRESSION immediately for syntactic correctness, and to determine
whether symbols in it have referents in the context of your
breakpoint. If EXPRESSION uses symbols not referenced in the
context of the breakpoint, GDB prints an error message:
No symbol "foo" in current context.
GDB does not actually evaluate EXPRESSION at the time the
`condition' command (or a command that sets a breakpoint with a
condition, like `break if ...') is given, however. *Note
Expressions: Expressions.
`condition BNUM'
Remove the condition from breakpoint number BNUM. 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 "ignore count"
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 your 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 does not stop the next N times your program reaches
it.
`ignore BNUM COUNT'
Set the ignore count of breakpoint number BNUM to COUNT. The next
COUNT times the breakpoint is reached, your program's execution
does not stop; other than to decrement the ignore count, GDB takes
no action.
To make the breakpoint stop the next time it is reached, specify a
count of zero.
When you use `continue' to resume execution of your program from a
breakpoint, you can specify an ignore count directly as an
argument to `continue', rather than using `ignore'. *Note
Continuing and stepping: Continuing and Stepping.
If a breakpoint has a positive ignore count and a condition, the
condition is not checked. Once the ignore count reaches zero, GDB
resumes checking the condition.
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. *Note Convenience variables:
Convenience Vars.
Ignore counts apply to breakpoints, watchpoints, and catchpoints.
File: gdb.info, Node: Break Commands, Next: Breakpoint Menus, Prev: Conditions, Up: Breakpoints
Breakpoint command lists
------------------------
You can give any breakpoint (or watchpoint or catchpoint) a series of
commands to execute when your program stops due to that breakpoint. For
example, you might want to print the values of certain expressions, or
enable other breakpoints.
`commands [BNUM]'
`... COMMAND-LIST ...'
`end'
Specify a list of commands for breakpoint number BNUM. 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, type `commands' and
follow it immediately with `end'; that is, give no commands.
With no BNUM argument, `commands' refers to the last breakpoint,
watchpoint, or catchpoint set (not to the breakpoint most recently
encountered).
Pressing <RET> as a means of repeating the last GDB command is
disabled within a COMMAND-LIST.
You can use breakpoint commands to start your program up again.
Simply use the `continue' command, or `step', or any other command that
resumes execution.
Any other commands in the command list, after a command that resumes
execution, are ignored. This is because any time you resume execution
(even with a simple `next' or `step'), you may encounter another
breakpoint--which could have its own command list, leading to
ambiguities about which list to execute.
If the first command you specify in a command list 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 none of the remaining commands print anything, you
see no sign that the breakpoint was reached. `silent' is meaningful
only at the beginning of a breakpoint command list.
The commands `echo', `output', and `printf' allow you to print
precisely controlled output, and are often useful in silent
breakpoints. *Note Commands for controlled output: Output.
For example, here is how you could use breakpoint commands to print
the value of `x' at entry to `foo' whenever `x' is positive.
break foo if x>0
commands
silent
printf "x is %d\n",x
cont
end
One application for breakpoint commands is to compensate for one bug
so you can test for 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 variables that need them. End with the `continue' command so
that your program does not stop, and start with the `silent' command so
that no output is produced. Here is an example:
break 403
commands
silent
set x = y + 4
cont
end
File: gdb.info, Node: Breakpoint Menus, Next: Error in Breakpoints, Prev: Break Commands, Up: Breakpoints
Breakpoint menus
----------------
Some programming languages (notably C++) permit a single function
name to be defined several times, for application in different contexts.
This is called "overloading". When a function name is overloaded,
`break FUNCTION' is not enough to tell GDB where you want a breakpoint.
If you realize this is a problem, you can use something like `break
FUNCTION(TYPES)' to specify which particular version of the function
you want. Otherwise, GDB offers you a menu of numbered choices for
different possible breakpoints, and waits for your selection with the
prompt `>'. The first two options are always `[0] cancel' and `[1]
all'. Typing `1' sets a breakpoint at each definition of FUNCTION, and
typing `0' aborts the `break' command without setting any new
breakpoints.
For example, the following session excerpt shows an attempt to set a
breakpoint at the overloaded symbol `String::after'. We choose three
particular definitions of that function name:
(gdb) b String::after
[0] cancel
[1] all
[2] file:String.cc; line number:867
[3] file:String.cc; line number:860
[4] file:String.cc; line number:875
[5] file:String.cc; line number:853
[6] file:String.cc; line number:846
[7] file:String.cc; line number:735
> 2 4 6
Breakpoint 1 at 0xb26c: file String.cc, line 867.
Breakpoint 2 at 0xb344: file String.cc, line 875.
Breakpoint 3 at 0xafcc: file String.cc, line 846.
Multiple breakpoints were set.
Use the "delete" command to delete unwanted
breakpoints.
(gdb)
File: gdb.info, Node: Error in Breakpoints, Prev: Breakpoint Menus, Up: Breakpoints
"Cannot insert breakpoints"
---------------------------
Under some operating systems, breakpoints cannot be used in a
program if any other process is running that program. In this
situation, attempting to run or continue a program with a breakpoint
causes GDB to print an error message:
Cannot insert breakpoints.
The same program may be running in another process.
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 your program to a new
name. Resume GDB and use the `exec-file' command to specify that
GDB should run your program under that name. Then start your
program again.
3. Relink your program so that the text segment is nonsharable, using
the linker option `-N'. The operating system limitation may not
apply to nonsharable executables.
A similar message can be printed if you request too many active
hardware-assisted breakpoints and watchpoints:
Stopped; cannot insert breakpoints.
You may have requested too many hardware breakpoints and watchpoints.
This message is printed when you attempt to resume the program, since
only then GDB knows exactly how many hardware breakpoints and
watchpoints it needs to insert.
When this message is printed, you need to disable or remove some of
the hardware-assisted breakpoints and watchpoints, and then continue.
File: gdb.info, Node: Continuing and Stepping, Next: Signals, Prev: Breakpoints, Up: Stopping
Continuing and stepping
=======================
"Continuing" means resuming program execution until your program
completes normally. In contrast, "stepping" means executing just one
more "step" of your program, where "step" may mean either one line of
source code, or one machine instruction (depending on what particular
command you use). Either when continuing or when stepping, your
program may stop even sooner, due to a breakpoint or a signal. (If it
stops due to a signal, you may want to use `handle', or use `signal 0'
to resume execution. *Note Signals: Signals.)
`continue [IGNORE-COUNT]'
`c [IGNORE-COUNT]'
`fg [IGNORE-COUNT]'
Resume program execution, at the address where your program last
stopped; any breakpoints set at that address are bypassed. The
optional argument IGNORE-COUNT allows you to specify a further
number of times to ignore a breakpoint at this location; its
effect is like that of `ignore' (*note Break conditions:
Conditions.).
The argument IGNORE-COUNT is meaningful only when your program
stopped due to a breakpoint. At other times, the argument to
`continue' is ignored.
The synonyms `c' and `fg' (for "foreground", as the debugged
program is deemed to be the foreground program) are provided
purely for convenience, and have exactly the same behavior as
`continue'.
To resume execution at a different place, you can use `return'
(*note Returning from a function: Returning.) to go back to the calling
function; or `jump' (*note Continuing at a different address: Jumping.)
to go to an arbitrary location in your program.
A typical technique for using stepping is to set a breakpoint (*note
Breakpoints; watchpoints; and catchpoints: Breakpoints.) at the
beginning of the function or the section of your program where a problem
is believed to lie, run your program until it stops at that breakpoint,
and then step through the suspect area, examining the variables that are
interesting, until you see the problem happen.
`step'
Continue running your program until control reaches a different
source line, then stop it and return control to GDB. This command
is abbreviated `s'.
_Warning:_ If you use the `step' command while control is
within a function that was compiled without debugging
information, execution proceeds until control reaches a
function that does have debugging information. Likewise, it
will not step into a function which is compiled without
debugging information. To step through functions without
debugging information, use the `stepi' command, described
below.
The `step' command only stops at the first instruction of a source
line. This prevents the multiple stops that could otherwise occur
in switch statements, for loops, etc. `step' continues to stop if
a function that has debugging information is called within the
line. In other words, `step' _steps inside_ any functions called
within the line.
Also, the `step' command only enters a function if there is line
number information for the function. Otherwise it acts like the
`next' command. This avoids problems when using `cc -gl' on MIPS
machines. Previously, `step' entered subroutines if there was any
debugging information about the routine.
`step COUNT'
Continue running as in `step', but do so COUNT times. If a
breakpoint is reached, or a signal not related to stepping occurs
before COUNT steps, stepping stops right away.
`next [COUNT]'
Continue to the next source line in the current (innermost) stack
frame. This is similar to `step', but function calls that appear
within the line of code are executed without stopping. Execution
stops when control reaches a different line of code at the
original stack level that was executing when you gave the `next'
command. This command is abbreviated `n'.
An argument COUNT is a repeat count, as for `step'.
The `next' command only stops at the first instruction of a source
line. This prevents multiple stops that could otherwise occur in
switch statements, for loops, etc.
`finish'
Continue running until just after function in the selected stack
frame returns. Print the returned value (if any).
Contrast this with the `return' command (*note Returning from a
function: Returning.).
`until'
`u'
Continue running until a source line past the current line, in the
current stack frame, is reached. This command is used to avoid
single stepping through a loop more than once. It is like the
`next' command, except that when `until' encounters a jump, it
automatically continues execution 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' makes your program continue execution
until it exits the loop. In contrast, a `next' command at the end
of a loop simply steps back to the beginning of the loop, which
forces you to step through the next iteration.
`until' always stops your program if it attempts to exit the
current stack frame.
`until' may produce somewhat counterintuitive results if the order
of machine code does not match the order of the source lines. For
example, in the following excerpt from a debugging session, the `f'
(`frame') command shows that execution is stopped at line `206';
yet when we use `until', we get to line `195':
(gdb) f
#0 main (argc=4, argv=0xf7fffae8) at m4.c:206
206 expand_input();
(gdb) until
195 for ( ; argc > 0; NEXTARG) {
This happened because, for execution efficiency, the compiler had
generated code for the loop closure test at the end, rather than
the start, of the loop--even though the test in a C `for'-loop is
written before the body of the loop. The `until' command appeared
to step back to the beginning of the loop when it advanced to this
expression; however, it has not really gone to an earlier
statement--not in terms of the actual machine code.
`until' with no argument works by means of single instruction
stepping, and hence is slower than `until' with an argument.
`until LOCATION'
`u LOCATION'
Continue running your program until either the specified location
is reached, or the current stack frame returns. LOCATION is any of
the forms of argument acceptable to `break' (*note Setting
breakpoints: Set Breaks.). This form of the command uses
breakpoints, and hence is quicker than `until' without an argument.
`stepi'
`stepi ARG'
`si'
Execute one machine instruction, then stop and return to the
debugger.
It is often useful to do `display/i $pc' when stepping by machine
instructions. This makes GDB automatically display the next
instruction to be executed, each time your program stops. *Note
Automatic display: Auto Display.
An argument is a repeat count, as in `step'.
`nexti'
`nexti ARG'
`ni'
Execute one machine instruction, but if it is a function call,
proceed until the function returns.
An argument is a repeat count, as in `next'.
File: gdb.info, Node: Signals, Next: Thread Stops, Prev: Continuing and Stepping, Up: Stopping
Signals
=======
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 example, in Unix `SIGINT' is the signal
a program gets when you type an interrupt character (often `C-c');
`SIGSEGV' is the signal a program gets from referencing 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 your program has
requested an alarm).
Some signals, including `SIGALRM', are a normal part of the
functioning of your program. Others, such as `SIGSEGV', indicate
errors; these signals are "fatal" (they kill your program immediately)
if the program has not specified in advance some other way to handle
the signal. `SIGINT' does not indicate an error in your program, but
it is normally fatal so it can carry out the purpose of the interrupt:
to kill the program.
GDB has the ability to detect any occurrence of a signal in your
program. 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
your program) but to stop your program immediately whenever an error
signal happens. You can change these settings with the `handle'
command.
`info signals'
`info handle'
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.
`info handle' is an alias for `info signals'.
`handle SIGNAL KEYWORDS...'
Change the way GDB handles signal SIGNAL. SIGNAL can be the
number of a signal or its name (with or without the `SIG' at the
beginning). The KEYWORDS say what change to make.
The keywords allowed by the `handle' command can be abbreviated.
Their full names are:
`nostop'
GDB should not stop your program when this signal happens. It may
still print a message telling you that the signal has come in.
`stop'
GDB should stop your program when this signal happens. This
implies the `print' keyword as well.
`print'
GDB should print a message when this signal happens.
`noprint'
GDB should not mention the occurrence of the signal at all. This
implies the `nostop' keyword as well.
`pass'
GDB should allow your program to see this signal; your program can
handle the signal, or else it may terminate if the signal is fatal
and not handled.
`nopass'
GDB should not allow your program to see this signal.
When a signal stops your program, the signal is not visible to the
program until you continue. Your program sees the signal then, if
`pass' is in effect for the signal in question _at that time_. In
other words, after GDB reports a signal, you can use the `handle'
command with `pass' or `nopass' to control whether your program sees
that signal when you continue.
You can also use the `signal' command to prevent your 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. For example, if your program
stopped due to some sort of memory reference error, you might store
correct values into the erroneous variables and continue, hoping to see
more execution; but your program would probably terminate immediately as
a result of the fatal signal once it saw the signal. To prevent this,
you can continue with `signal 0'. *Note Giving your program a signal:
Signaling.
File: gdb.info, Node: Thread Stops, Prev: Signals, Up: Stopping
Stopping and starting multi-thread programs
===========================================
When your program has multiple threads (*note Debugging programs
with multiple threads: Threads.), you can choose whether to set
breakpoints on all threads, or on a particular thread.
`break LINESPEC thread THREADNO'
`break LINESPEC thread THREADNO if ...'
LINESPEC specifies source lines; there are several ways of writing
them, but the effect is always to specify some source line.
Use the qualifier `thread THREADNO' with a breakpoint command to
specify that you only want GDB to stop the program when a
particular thread reaches this breakpoint. THREADNO is one of the
numeric thread identifiers assigned by GDB, shown in the first
column of the `info threads' display.
If you do not specify `thread THREADNO' when you set a breakpoint,
the breakpoint applies to _all_ threads of your program.
You can use the `thread' qualifier on conditional breakpoints as
well; in this case, place `thread THREADNO' before the breakpoint
condition, like this:
(gdb) break frik.c:13 thread 28 if bartab > lim
Whenever your program stops under GDB for any reason, _all_ threads
of execution stop, not just the current thread. This allows you to
examine the overall state of the program, including switching between
threads, without worrying that things may change underfoot.
Conversely, whenever you restart the program, _all_ threads start
executing. _This is true even when single-stepping_ with commands like
`step' or `next'.
In particular, GDB cannot single-step all threads in lockstep.
Since thread scheduling is up to your debugging target's operating
system (not controlled by GDB), other threads may execute more than one
statement while the current thread completes a single step. Moreover,
in general other threads stop in the middle of a statement, rather than
at a clean statement boundary, when the program stops.
You might even find your program stopped in another thread after
continuing or even single-stepping. This happens whenever some other
thread runs into a breakpoint, a signal, or an exception before the
first thread completes whatever you requested.
On some OSes, you can lock the OS scheduler and thus allow only a
single thread to run.
`set scheduler-locking MODE'
Set the scheduler locking mode. If it is `off', then there is no
locking and any thread may run at any time. If `on', then only the
current thread may run when the inferior is resumed. The `step'
mode optimizes for single-stepping. It stops other threads from
"seizing the prompt" by preempting the current thread while you are
stepping. Other threads will only rarely (or never) get a chance
to run when you step. They are more likely to run when you `next'
over a function call, and they are completely free to run when you
use commands like `continue', `until', or `finish'. However,
unless another thread hits a breakpoint during its timeslice, they
will never steal the GDB prompt away from the thread that you are
debugging.
`show scheduler-locking'
Display the current scheduler locking mode.
File: gdb.info, Node: Stack, Next: Source, Prev: Stopping, Up: Top
Examining the Stack
*******************
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, information about
the call is generated. That information includes the location of the
call in your program, the arguments of the call, and the local
variables of the function being called. The information is saved in a
block of data called a "stack frame". The stack frames are allocated
in a region of memory called the "call stack".
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 "selected" by GDB and many GDB commands
refer implicitly to the selected frame. In particular, whenever you
ask GDB for the value of a variable in your program, the value is found
in the selected frame. There are special GDB commands to select
whichever frame you are interested in. *Note Selecting a frame:
Selection.
When your program stops, GDB automatically selects the currently
executing frame and describes it briefly, similar to the `frame'
command (*note Information about a frame: Frame Info.).
* Menu:
* Frames:: Stack frames
* Backtrace:: Backtraces
* Selection:: Selecting a frame
* Frame Info:: Information on a frame
File: gdb.info, Node: Frames, Next: Backtrace, Up: Stack
Stack frames
============
The call stack is divided up into contiguous pieces called "stack
frames", or "frames" 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 "initial" frame or the
"outermost" 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 "innermost" 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 byte
whose address serves as the address of the frame. Usually this address
is kept in a register called the "frame pointer register" 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
assigned by GDB to give you a way of designating stack frames in GDB
commands.
Some compilers provide a way to compile functions so that they
operate without stack frames. (For example, the gcc option
`-fomit-frame-pointer'
generates functions without a frame.) 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 nevertheless
regards it as though it had a separate frame, which is numbered zero as
usual, allowing correct tracing of the function call chain. However,
GDB has no provision for frameless functions elsewhere in the stack.
`frame ARGS'
The `frame' command allows you to move from one stack frame to
another, and to print the stack frame you select. ARGS may be
either the address of the frame or the stack frame number.
Without an argument, `frame' prints the current stack frame.
`select-frame'
The `select-frame' command allows you to move from one stack frame
to another without printing the frame. This is the silent version
of `frame'.
File: gdb.info, Node: Backtrace, Next: Selection, Prev: Frames, Up: Stack
Backtraces
==========
A backtrace is a summary of how your program got where it is. It
shows one line per frame, for many frames, starting with the currently
executing frame (frame zero), followed 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 `C-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' (abbreviated `info s') are
additional aliases for `backtrace'.
Each line in the backtrace shows the frame number and the function
name. The program counter value is also shown--unless you use `set
print address off'. The backtrace also 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.
Here is an example of a backtrace. It was made with the command `bt
3', so it shows the innermost three frames.
#0 m4_traceon (obs=0x24eb0, argc=1, argv=0x2b8c8)
at builtin.c:993
#1 0x6e38 in expand_macro (sym=0x2b600) at macro.c:242
#2 0x6840 in expand_token (obs=0x0, t=177664, td=0xf7fffb08)
at macro.c:71
(More stack frames follow...)
The display for frame zero does not begin with a program counter value,
indicating that your program has stopped at the beginning of the code
for line `993' of `builtin.c'.
File: gdb.info, Node: Selection, Next: Frame Info, Prev: Backtrace, Up: Stack
Selecting a frame
=================
Most commands for examining the stack and other data in your 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'
`f 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 the one
for `main'.
`frame ADDR'
`f ADDR'
Select the frame at address ADDR. 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
addition, this can be useful when your program has multiple stacks
and switches between them.
On the SPARC architecture, `frame' needs two addresses to select
an arbitrary frame: a frame pointer and a stack pointer.
On the MIPS and Alpha architecture, it needs two addresses: a stack
pointer and a program counter.
On the 29k architecture, it needs three addresses: a register stack
pointer, a program counter, and a memory stack pointer.
`up N'
Move N frames up the stack. For positive numbers N, this advances
toward the outermost frame, to higher frame numbers, to frames
that have existed longer. N defaults to one.
`down N'
Move N frames down the stack. 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. You
may abbreviate `down' as `do'.
All of these commands end by printing two lines of output describing
the frame. The first line shows the frame number, the function name,
the arguments, and the source file and line number of execution in that
frame. The second line shows the text of that source line.
For example:
(gdb) up
#1 0x22f0 in main (argc=1, argv=0xf7fffbf4, env=0xf7fffbfc)
at env.c:10
10 read_input_file (argv[i]);
After such a printout, the `list' command with no arguments prints
ten lines centered on the point of execution in the frame. *Note
Printing source lines: List.
`up-silently N'
`down-silently N'
These two commands are variants of `up' and `down', respectively;
they differ in that they do their work silently, without causing
display of the new frame. They are intended primarily for use in
GDB command scripts, where the output might be unnecessary and
distracting.
File: gdb.info, Node: Frame Info, Prev: Selection, Up: Stack
Information about a frame
=========================
There are several other commands to print information about the
selected stack frame.
`frame'
`f'
When used without any argument, this command does not change which
frame is selected, but prints a brief description of the currently
selected stack frame. It can be abbreviated `f'. With an
argument, this command is used to select a stack frame. *Note
Selecting a frame: Selection.
`info frame'
`info f'
This command prints a verbose description of the selected stack
frame, including:
* the address of the frame
* the address of the next frame down (called by this frame)
* the address of the next frame up (caller of this frame)
* the language in which the source code corresponding to this
frame is written
* the address of the frame's arguments
* the address of the frame's local variables
* the program counter saved in it (the address of execution in
the caller frame)
* which registers 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 ADDR'
`info f ADDR'
Print a verbose description of the frame at address ADDR, without
selecting that frame. The selected frame remains unchanged by this
command. This requires the same kind of address (more than one
for some architectures) that you specify in the `frame' command.
*Note Selecting a frame: Selection.
`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 either static or
automatic) accessible at the point of execution of the selected
frame.
`info catch'
Print a list of all the exception handlers that are active in the
current stack frame at the current point of execution. To see
other exception handlers, visit the associated frame (using the
`up', `down', or `frame' commands); then type `info catch'. *Note
Setting catchpoints: Set Catchpoints.
File: gdb.info, Node: Source, Next: Data, Prev: Stack, Up: Top
Examining Source Files
**********************
GDB can print parts of your program's source, since the debugging
information recorded in the program tells GDB what source files were
used to build it. When your program stops, GDB spontaneously prints
the line where it stopped. Likewise, when you select a stack frame
(*note Selecting a frame: Selection.), GDB prints the line where
execution in that frame has stopped. You can print other portions of
source files by explicit command.
If you use GDB through its GNU Emacs interface, you may prefer to
use Emacs facilities to view source; see *Note Using GDB under GNU
Emacs: Emacs.
* Menu:
* List:: Printing source lines
* Search:: Searching source files
* Source Path:: Specifying source directories
* Machine Code:: Source and machine code
File: gdb.info, Node: List, Next: Search, Up: Source
Printing source lines
=====================
To print lines from a source file, use the `list' command
(abbreviated `l'). By default, ten lines are printed. 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 LINENUM'
Print lines centered around line number LINENUM in the current
source file.
`list FUNCTION'
Print lines centered around the beginning of function FUNCTION.
`list'
Print more lines. If the last lines printed were printed with a
`list' command, this prints lines following the last lines
printed; however, if the last line printed was a solitary line
printed as part of displaying a stack frame (*note Examining the
Stack: Stack.), this prints lines centered around that line.
`list -'
Print lines just before the lines last printed.
By default, GDB prints ten source lines with any of these forms of
the `list' command. You can change this using `set listsize':
`set listsize COUNT'
Make the `list' command display COUNT source lines (unless the
`list' argument explicitly specifies some other number).
`show listsize'
Display the number of lines that `list' prints.
Repeating a `list' command with <RET> discards the argument, 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 source file.
In general, the `list' command expects you to supply zero, one or two
"linespecs". 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':
`list LINESPEC'
Print lines centered around the line specified by LINESPEC.
`list FIRST,LAST'
Print lines from FIRST to LAST. Both arguments are linespecs.
`list ,LAST'
Print lines ending with LAST.
`list FIRST,'
Print lines starting with FIRST.
`list +'
Print lines just after the lines last printed.
`list -'
Print lines just before the lines last printed.
`list'
As described in the preceding table.
Here are the ways of specifying a single source line--all the kinds
of linespec.
`NUMBER'
Specifies line NUMBER of the current source file. When a `list'
command has two linespecs, this refers to the same source file as
the first linespec.
`+OFFSET'
Specifies the line OFFSET lines after the last line printed. When
used as the second linespec in a `list' command that has two, this
specifies the line OFFSET lines down from the first linespec.
`-OFFSET'
Specifies the line OFFSET lines before the last line printed.
`FILENAME:NUMBER'
Specifies line NUMBER in the source file FILENAME.
`FUNCTION'
Specifies the line that begins the body of the function FUNCTION.
For example: in C, this is the line with the open brace.
`FILENAME:FUNCTION'
Specifies the line of the open-brace that begins the body of the
function FUNCTION in the file FILENAME. You only need the file
name with a function name to avoid ambiguity when there are
identically named functions in different source files.
`*ADDRESS'
Specifies the line containing the program address ADDRESS.
ADDRESS may be any expression.
File: gdb.info, Node: Search, Next: Source Path, Prev: List, Up: Source
Searching source files
======================
There are two commands for searching through the current source file
for a regular expression.
`forward-search REGEXP'
`search REGEXP'
The command `forward-search REGEXP' checks each line, starting
with the one following the last line listed, for a match for
REGEXP. It lists the line that is found. You can use the synonym
`search REGEXP' or abbreviate the command name as `fo'.
`reverse-search REGEXP'
The command `reverse-search REGEXP' checks each line, starting
with the one before the last line listed and going backward, for a
match for REGEXP. It lists the line that is found. You can
abbreviate this command as `rev'.
File: gdb.info, Node: Source Path, Next: Machine Code, Prev: Search, Up: Source
Specifying source directories
=============================
Executable programs sometimes do not record the directories of the
source files from which they were compiled, just the names. Even when
they do, the directories could be moved between the compilation and
your debugging session. GDB has a list of directories to search for
source files; this is called the "source path". 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. Note that the executable search path is _not_ used for this
purpose. Neither is the current working directory, unless it happens
to be in the source path.
If GDB cannot find a source file in the source path, and the object
program records a directory, GDB tries that directory too. If the
source path is empty, and there is no record of the compilation
directory, GDB looks in the current directory as a last resort.
Whenever you reset or rearrange the source path, GDB clears out any
information it has cached about where source files are found and where
each line is in the file.
When you start GDB, its source path includes only `cdir' and `cwd',
in that order. To add other directories, use the `directory' command.
`directory DIRNAME ...'
`dir DIRNAME ...'
Add directory DIRNAME to the front of the source path. Several
directory names may be given to this command, separated by `:'
(`;' on MS-DOS and MS-Windows, where `:' usually appears as part
of absolute file names) or whitespace. You may specify a
directory that is already in the source path; this moves it
forward, so GDB searches it sooner.
You can use the string `$cdir' to refer to the compilation
directory (if one is recorded), and `$cwd' to refer to the current
working directory. `$cwd' is not the same as `.'--the former
tracks the current working directory as it changes during your GDB
session, while the latter is immediately expanded to the current
directory at the time you add an entry to the source path.
`directory'
Reset the source path to empty again. This requires confirmation.
`show directories'
Print the source path: show which directories it contains.
If your source path is cluttered with directories that are no longer
of interest, GDB may sometimes cause confusion by finding the wrong
versions of source. You can correct the situation as follows:
1. Use `directory' with no argument to reset the source path to empty.
2. Use `directory' with suitable arguments to reinstall the
directories you want in the source path. You can add all the
directories in one command.
File: gdb.info, Node: Machine Code, Prev: Source Path, Up: Source
Source and machine code
=======================
You can use the command `info line' to map source lines to program
addresses (and vice versa), and the command `disassemble' to display a
range of addresses as machine instructions. When run under GNU Emacs
mode, the `info line' command causes the arrow to point to the line
specified. Also, `info line' prints addresses in symbolic form as well
as hex.
`info line LINESPEC'
Print the starting and ending addresses of the compiled code for
source line LINESPEC. You can specify source lines in any of the
ways understood by the `list' command (*note Printing source
lines: List.).
For example, we can use `info line' to discover the location of the
object code for the first line of function `m4_changequote':
(gdb) info line m4_changequote
Line 895 of "builtin.c" starts at pc 0x634c and ends at 0x6350.
We can also inquire (using `*ADDR' as the form for LINESPEC) what
source line covers a particular address:
(gdb) info line *0x63ff
Line 926 of "builtin.c" starts at pc 0x63e4 and ends at 0x6404.
After `info line', the default 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 (*note Examining memory:
Memory.). Also, this address is saved as the value of the convenience
variable `$_' (*note Convenience variables: Convenience Vars.).
`disassemble'
This specialized command dumps 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; GDB dumps the
function surrounding this value. Two arguments specify a range of
addresses (first inclusive, second exclusive) to dump.
The following example shows the disassembly of a range of addresses
of HP PA-RISC 2.0 code:
(gdb) disas 0x32c4 0x32e4
Dump of assembler code from 0x32c4 to 0x32e4:
0x32c4 <main+204>: addil 0,dp
0x32c8 <main+208>: ldw 0x22c(sr0,r1),r26
0x32cc <main+212>: ldil 0x3000,r31
0x32d0 <main+216>: ble 0x3f8(sr4,r31)
0x32d4 <main+220>: ldo 0(r31),rp
0x32d8 <main+224>: addil -0x800,dp
0x32dc <main+228>: ldo 0x588(r1),r26
0x32e0 <main+232>: ldil 0x3000,r31
End of assembler dump.
Some architectures have more than one commonly-used set of
instruction mnemonics or other syntax.
`set disassembly-flavor INSTRUCTION-SET'
Select the instruction set to use when disassembling the program
via the `disassemble' or `x/i' commands.
Currently this command is only defined for the Intel x86 family.
You can set INSTRUCTION-SET to either `intel' or `att'. The
default is `att', the AT&T flavor used by default by Unix
assemblers for x86-based targets.
File: gdb.info, Node: Data, Next: Languages, Prev: Source, Up: Top
Examining Data
**************
The usual way to examine data in your program is with the `print'
command (abbreviated `p'), or its synonym `inspect'. It evaluates and
prints the value of an expression of the language your program is
written in (*note Using GDB with Different Languages: Languages.).
`print EXPR'
`print /F EXPR'
EXPR is an expression (in the source language). By default the
value of EXPR is printed in a format appropriate to its data type;
you can choose a different format by specifying `/F', where F is a
letter specifying the format; see *Note Output formats: Output
Formats.
`print'
`print /F'
If you omit EXPR, GDB displays the last value again (from the
"value history"; *note Value history: Value History.). This
allows you to conveniently inspect the same value in an
alternative format.
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. *Note Examining memory: Memory.
If you are interested in information about types, or about how the
fields of a struct or a class are declared, use the `ptype EXP' command
rather than `print'. *Note Examining the Symbol Table: Symbols.
* Menu:
* Expressions:: Expressions
* Variables:: Program variables
* Arrays:: Artificial arrays
* Output Formats:: Output formats
* Memory:: Examining memory
* Auto Display:: Automatic display
* Print Settings:: Print settings
* Value History:: Value history
* Convenience Vars:: Convenience variables
* Registers:: Registers
* Floating Point Hardware:: Floating point hardware