freebsd-dev/share/doc/handbook/kerneldebug.sgml

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<!-- $Id: kerneldebug.sgml,v 1.3 1995/07/31 01:18:46 jfieber Exp $ -->
<!-- The FreeBSD Documentation Project -->
<chapt><heading>Kernel Debugging<label id="kerneldebug"></heading>
<p><em>Contributed by &a.paul; and &a.joerg;</em>
<sect><heading>Debugging a kernel crash dump with kgdb</heading>
<p>Here are some instructions for getting kernel debugging
working on a crash dump, it assumes that you have enough swap
space for a crash dump. If you have multiple swap
partitions and the first one is too small to hold the dump,
you can configure your kernel to use an alternate dump device
(in the <tt>config kernel</tt> line), or
you can specify an alternate using the dumpon(8) command.
Dumps to non-swap devices,
tapes for example, are currently not supported. Config your
kernel using <tt>config -g</tt>.
See <ref id="kernelconfig" name="Kernel Configuration"> for
details on configuring the FreeBSD kernel.
Use the <tt>dumpon(8)</tt> command to tell the kernel where to dump
to (note that this will have to be done after configuring the
partition in question as swap space via <tt>swapon(8)</tt>). This is
normally arranged via <tt>/etc/sysconfig</tt> and <tt>/etc/rc</tt>.
Alternatively, you can
hard-code the dump device via the `dump' clause in the `config' line
of your kernel config file. This is deprecated, but might be the
only chance to get a crash dump from a kernel that's not booting at
all, so that you didn't had the ability to run any command before it
used to crash.
<em><bf>Note:</bf> In the following, the term `<tt>kgdb</tt>' refers
to <tt>gdb</tt> run in `kernel debug mode'. This can be accomplished by
either starting the <tt>gdb</tt> with the option <tt>-k</tt>, or by linking
and starting it under the name <tt>kgdb</tt>. This is not being
done by default, however.</em>
When the kernel has been built make a copy of it, say
<tt>kernel.debug</tt>, and then run <tt>strip -x</tt> on the
original. Install the original as normal. You may also install
the unstripped kernel, but symbol table lookup time for some
programs will drastically increase, and since
the whole kernel is loaded entirely at boot time and cannot be
swapped out later, several megabytes of
physical RAM will be wasted.
If you are testing a new kernel, for example by typing the new
kernel's name at the boot prompt, but need to boot a different
one in order to get your system up and running again, boot it
only into single user state using the <tt>-s</tt> flag at the
boot prompt, and then perform the following steps:
<tscreen><verb>
fsck -p
mount -a -t ufs # so your file system for /var/crash is writable
savecore -N /kernel.panicked /var/crash
exit # ...to multi-user
</verb></tscreen>
This instructs <tt>savecore(8)</tt> to use another kernel for symbol name
extraction. It would otherwise default to the currently running kernel.
Now, after a crash dump, go to <tt>/sys/compile/WHATEVER</tt> and run
<tt>kgdb</tt>. From <tt>kgdb</tt> do:
<tscreen><verb>
symbol-file kernel.debug
exec-file /var/crash/system.0
core-file /var/crash/ram.0
</verb></tscreen>
and voila, you can debug the crash dump using the kernel sources
just like you can for any other program.
If your kernel panicked due to a trap, perhaps the most common
case for getting a core dump, the following trick might help
you. Examine the stack using <tt>kgdb</tt>'s `where' command,
and look for the stack frame in the function <tt>trap()</tt>. Go `up'
to that frame, and then type:
<tscreen><verb>
frame frame->tf_ebp frame->tf_eip
</verb></tscreen>
This will tell <tt>kgdb</tt> to go to the stack frame explicitly named by a
frame pointer and instruction pointer, which is the location where
the trap occured. There are still some bugs in <tt>kgdb</tt> (you can go
`up' from there, but not `down'; the stack trace will still remain
as it was before going to here), but generally this method will lead
you much closer to the failing piece of code.
Here's a script log of a <tt>kgdb</tt> session illustrating the above. Long
lines have been folded to improve readability, and the lines are
numbered for reference. Despite of this, it's a real-world error
trace taken during the development of the pcvt console driver.
<tscreen><verb>
1:Script started on Fri Dec 30 23:15:22 1994
2:uriah # cd /sys/compile/URIAH
3:uriah # kgdb kernel /var/crash/vmcore.1
4:Reading symbol data from /usr/src/sys/compile/URIAH/kernel...done.
5:IdlePTD 1f3000
6:panic: because you said to!
7:current pcb at 1e3f70
8:Reading in symbols for ../../i386/i386/machdep.c...done.
9:(kgdb) where
10:#0 boot (arghowto=256) (../../i386/i386/machdep.c line 767)
11:#1 0xf0115159 in panic ()
12:#2 0xf01955bd in diediedie () (../../i386/i386/machdep.c line 698)
13:#3 0xf010185e in db_fncall ()
14:#4 0xf0101586 in db_command (-266509132, -266509516, -267381073)
15:#5 0xf0101711 in db_command_loop ()
16:#6 0xf01040a0 in db_trap ()
17:#7 0xf0192976 in kdb_trap (12, 0, -272630436, -266743723)
18:#8 0xf019d2eb in trap_fatal (...)
19:#9 0xf019ce60 in trap_pfault (...)
20:#10 0xf019cb2f in trap (...)
21:#11 0xf01932a1 in exception:calltrap ()
22:#12 0xf0191503 in cnopen (...)
23:#13 0xf0132c34 in spec_open ()
24:#14 0xf012d014 in vn_open ()
25:#15 0xf012a183 in open ()
26:#16 0xf019d4eb in syscall (...)
27:(kgdb) up 10
28:Reading in symbols for ../../i386/i386/trap.c...done.
29:#10 0xf019cb2f in trap (frame={tf_es = -260440048, tf_ds = 16, tf_\
30:edi = 3072, tf_esi = -266445372, tf_ebp = -272630356, tf_isp = -27\
31:2630396, tf_ebx = -266427884, tf_edx = 12, tf_ecx = -266427884, tf\
32:_eax = 64772224, tf_trapno = 12, tf_err = -272695296, tf_eip = -26\
33:6672343, tf_cs = -266469368, tf_eflags = 66066, tf_esp = 3072, tf_\
34:ss = -266427884}) (../../i386/i386/trap.c line 283)
35:283 (void) trap_pfault(&amp;frame, FALSE);
36:(kgdb) frame frame->tf_ebp frame->tf_eip
37:Reading in symbols for ../../i386/isa/pcvt/pcvt_drv.c...done.
38:#0 0xf01ae729 in pcopen (dev=3072, flag=3, mode=8192, p=(struct p\
39:roc *) 0xf07c0c00) (../../i386/isa/pcvt/pcvt_drv.c line 403)
40:403 return ((*linesw[tp->t_line].l_open)(dev, tp));
41:(kgdb) list
42:398
43:399 tp->t_state |= TS_CARR_ON;
44:400 tp->t_cflag |= CLOCAL; /* cannot be a modem (:-) */
45:401
46:402 #if PCVT_NETBSD || (PCVT_FREEBSD >= 200)
47:403 return ((*linesw[tp->t_line].l_open)(dev, tp));
48:404 #else
49:405 return ((*linesw[tp->t_line].l_open)(dev, tp, flag));
50:406 #endif /* PCVT_NETBSD || (PCVT_FREEBSD >= 200) */
51:407 }
52:(kgdb) print tp
53:Reading in symbols for ../../i386/i386/cons.c...done.
54:$1 = (struct tty *) 0x1bae
55:(kgdb) print tp->t_line
56:$2 = 1767990816
57:(kgdb) up
58:#1 0xf0191503 in cnopen (dev=0x00000000, flag=3, mode=8192, p=(st\
59:ruct proc *) 0xf07c0c00) (../../i386/i386/cons.c line 126)
60: return ((*cdevsw[major(dev)].d_open)(dev, flag, mode, p));
61:(kgdb) up
62:#2 0xf0132c34 in spec_open ()
63:(kgdb) up
64:#3 0xf012d014 in vn_open ()
65:(kgdb) up
66:#4 0xf012a183 in open ()
67:(kgdb) up
68:#5 0xf019d4eb in syscall (frame={tf_es = 39, tf_ds = 39, tf_edi =\
69: 2158592, tf_esi = 0, tf_ebp = -272638436, tf_isp = -272629788, tf\
70:_ebx = 7086, tf_edx = 1, tf_ecx = 0, tf_eax = 5, tf_trapno = 582, \
71:tf_err = 582, tf_eip = 75749, tf_cs = 31, tf_eflags = 582, tf_esp \
72:= -272638456, tf_ss = 39}) (../../i386/i386/trap.c line 673)
73:673 error = (*callp->sy_call)(p, args, rval);
74:(kgdb) up
75:Initial frame selected; you cannot go up.
76:(kgdb) quit
77:uriah # exit
78:exit
79:
80:Script done on Fri Dec 30 23:18:04 1994
</verb></tscreen>
Comments to the above script:
<descrip>
<tag/line 6:/ This is a dump taken from within DDB (see below), hence the
panic comment ``because you said to!'', and a rather long
stack trace; the initial reason for going into DDB has been
a page fault trap though.
<tag/line 20:/ This is the location of function <tt>trap()</tt>
in the stack trace.
<tag/line 36:/ Force usage of a new stack frame, kgdb responds and displays
the source line where the trap happened; from looking at the
code, there's a high probability that either the pointer
access for ``tp'' was messed up, or the array access was
out of bounds.
<tag/line 52:/ The pointer looks suspicious, but happens to be a valid
address.
<tag/line 56:/ However, it obviously points to garbage, so we have found our
error! (For those unfamiliar with that particular piece
of code: <tt>tp-&gt;t_line</tt> refers to the line discipline
of the console device here, which must be a rather small integer
number.)
</descrip>
<sect><heading>Post-mortem analysis of a dump</heading>
<p>What do you do if a kernel dumped core but you did not expect
it, and it's therefore not compiled using <tt>config -g</tt>?
Not everything is lost here. Don't panic!
Of course, you still need to enable crash dumps. See above
on the options you've got to do this.
(This is for safety reasons in the default kernels, to avoid them
trying to dump e.g. during system installation where there's no
FreeBSD partition at all and valuable data on the disk could be
destroyed.)
Go to your kernel compile directory, and edit the line
containing <tt>COPTFLAGS?=-O</tt>. Add the <tt>-g</tt> option
there (but <em>don't</em> change anything on the level of
optimization). If you do already know roughly the probable
location of the failing piece of code (e.g., the <tt>pcvt</tt>
driver in the example above), remove all the object files for
this code. Rebuild the kernel. Due to the time stamp change on
the Makefile, there will be some other object files rebuild,
for example <tt>trap.o</tt>. With a bit of luck, the added
<tt>-g</tt> option won't change anything for the generated
code, so you'll finally get a new kernel with similar code to
the faulting one but some debugging symbols. You should at
least verify the old and new sizes with the <tt>size(1)</tt> command. If
there is a mismatch, you probably need to give up here.
Go and examine the dump as described above. The debugging
symbols might be incomplete for some places, as can be seen in
the stack trace in the example above where some functions are
displayed without line numbers and argument lists. If you need
more debugging symbols, remove the appropriate object files and
repeat the <tt>kgdb</tt> session until you know enough.
All this is not guaranteed to work, but it will do it fine in
most cases.
<sect><heading>On-line kernel debugging using DDB</heading>
<p>While <tt>kgdb</tt> as an offline debugger provides a very
high level of user interface, there are some things it cannot do.
The most important ones being breakpointing and single-stepping
kernel code.
If you need to do low-level debugging on your kernel, there's
an on- line debugger available called DDB. It allows to
setting breakpoints, single-steping kernel functions, examining
and changing kernel variables, etc. However, it cannot not
access kernel source files, and only has access to the global
and static symbols, not to the full debug information like
<tt>kgdb</tt>.
To configure your kernel to include DDB, add the option line
<tscreen><verb>
options DDB
</verb></tscreen>
to your config file, and rebuild. (See <ref id="kernelconfig"
name="Kernel Configuration"> for details on configuring the
FreeBSD kernel. Note that if you have an older version of the
boot blocks, your debugger symbols might not be loaded at all.
Update the boot blocks, the recent ones do load the DDB symbols
automagically.)
Once your DDB kernel is running, there are several ways to
enter DDB. The first, and earliest way is to type the boot
flag <tt>-d</tt> right at the boot prompt. The kernel will
start up in debug mode and enter DDB prior to any device
probing. Hence you are able to even debug the device
probe/attach functions.
The second scenario is a hot-key on the keyboard, usually
Ctrl-Alt-ESC. For syscons, this can be remapped, and some of
the distributed maps do this, so watch out.
There's an option
available for a COMCONSOLE kernel (``options BREAK_TO_DEBUGGER'')
that allows the use of a serial line BREAK on the console line to
enter DDB.
The third way is that any panic condition will branch to DDB if
the kernel is configured to use it. It is not wise to
configure a kernel with DDB for a machine running unattended
for this reason.
The DDB commands roughly resemble some <tt>gdb</tt> commands. The first you
probably need is to set a breakpoint:
<tscreen><verb>
b function-name
b address
</verb></tscreen>
Numbers are taken hexadecimal by default, but to make them
distinct from symbol names, hexadecimal numbers starting with the
letters <tt>a</tt>-<tt>f</tt> need to be preceded with
<tt>0x</tt> (for other numbers, this is optional). Simple
expressions are allowed, for example: <tt>function-name + 0x103</tt>.
To continue the operation of an interrupted kernel, simply type
<tscreen><verb>
c
</verb></tscreen>
To get a stack trace, use
<tscreen><verb>
trace
</verb></tscreen>
Note that when entering DDB via a hot-key, the kernel is currently
servicing an interrupt, so the stack trace might be not of much use
for you.
If you want to remove a breakpoint, use
<tscreen><verb>
del
del address-expression
</verb></tscreen>
The first form will be accepted immediately after a breakpoint hit,
and deletes the current breakpoint. The second form can remove any
breakpoint, but you need to specify the exact address, as it can be
obtained from
<tscreen><verb>
show b
</verb></tscreen>
To single-step the kernel, try
<tscreen><verb>
s
</verb></tscreen>
This will step into functions, but you can make DDB trace them until
the matching return statement is reached by
<tscreen><verb>
n
</verb></tscreen>
Note: this is different from <tt>gdb</tt>'s `next' statement, it's like
<tt>gdb</tt>'s `finish'.
To examine data from memory, use (for example):
<tscreen><verb>
x/wx 0xf0133fe0,40
x/hd db_symtab_space
x/bc termbuf,10
x/s stringbuf
</verb></tscreen>
for word/halfword/byte access, and hexadecimal/decimal/character/
string display. The number after the comma is the object count.
To display the next 0x10 items, simply use
<tscreen><verb>
x ,10
</verb></tscreen>
Similiarly, use
<tscreen><verb>
x/ia foofunc,10
</verb></tscreen>
to disassemble the first 0x10 instructions of <tt>foofunc</tt>, and display
them along with their offset from the beginning of <tt>foofunc</tt>.
To modify the memory, use the write command:
<tscreen><verb>
w/b termbuf 0xa 0xb 0
w/w 0xf0010030 0 0
</verb></tscreen>
The command modifier (<tt>b</tt>/<tt>h</tt>/<tt>w</tt>)
specifies the size of the data to be written, the first
following expression is the address to write to, the remainder
is interpreted as data to write to successive memory locations.
If you need to know the current registers, use
<tscreen><verb>
show reg
</verb></tscreen>
Alternatively, you can display a single register value by e.g.
<tscreen><verb>
print $eax
</verb></tscreen>
and modify it by
<tscreen><verb>
set $eax new-value
</verb></tscreen>
Should you need to call some kernel functions from DDB, simply
say
<tscreen><verb>
call func(arg1, arg2, ...)
</verb></tscreen>
The return value will be printed.
For a <tt>ps(1)</tt> style summary of all running processes, use
<tscreen><verb>
ps
</verb></tscreen>
Now you have now examined why your kernel failed, and you wish to
reboot. Remember that, depending on the severity of previous
malfunctioning, not all parts of the kernel might still be working
as expected. Perform one of the following actions to shut down and
reboot your system:
<tscreen><verb>
call diediedie()
</verb></tscreen>
will cause your kernel to dump core and reboot, so you can
later analyze the core on a higher level with kgdb. This
command usually must be followed by another
`<tt>continue</tt>' statement.
There is now an alias for this: `<tt>panic</tt>'.
<tscreen><verb>
call boot(0)
</verb></tscreen>
might be a good way to cleanly shut down the running system, <tt>sync()</tt>
all disks, and finally reboot. As long as the disk and file system
interfaces of the kernel are not damaged, this might be a good way
for an almost clean shutdown.
<tscreen><verb>
call cpu_reset()
</verb></tscreen>
is the final way out of disaster and almost the same as hitting
the Big Red Button.
<sect><heading>Debugging a console driver</heading>
<p>Since you need a console driver to run DDB on, things are more
complicated if the console driver itself is flakey. You might
remember the <tt>options COMCONSOLE</tt> line, and hook up a standard
terminal onto your first serial port. DDB works on any configured
console driver, of course it also works on a <tt>COMCONSOLE</tt>.