Documentation/BUG-HUNTING - pub/scm/linux/kernel/git/ebiederm/linux-namespace-control-devel - Git at Google

 Table of contents
 =================

 Last updated: 20 December 2005

 Contents
 ========

 - Introduction
 - Devices not appearing
 - Finding patch that caused a bug
 -- Finding using git-bisect
 -- Finding it the old way
 - Fixing the bug

 Introduction
 ============

 Always try the latest kernel from kernel.org and build from source. If you are
 not confident in doing that please report the bug to your distribution vendor
 instead of to a kernel developer.

 Finding bugs is not always easy. Have a go though. If you can't find it don't
 give up. Report as much as you have found to the relevant maintainer. See
 MAINTAINERS for who that is for the subsystem you have worked on.

 Before you submit a bug report read REPORTING-BUGS.

 Devices not appearing
 =====================

 Often this is caused by udev. Check that first before blaming it on the
 kernel.

 Finding patch that caused a bug
 ===============================


 Finding using git-bisect
 ------------------------

 Using the provided tools with git makes finding bugs easy provided the bug is
 reproducible.

 Steps to do it:
 - start using git for the kernel source
 - read the man page for git-bisect
 - have fun

 Finding it the old way
 ----------------------

 [Sat Mar  2 10:32:33 PST 1996 KERNEL_BUG-HOWTO lm@sgi.com (Larry McVoy)]

 This is how to track down a bug if you know nothing about kernel hacking.
 It's a brute force approach but it works pretty well.

 You need:

         . A reproducible bug - it has to happen predictably (sorry)
         . All the kernel tar files from a revision that worked to the
           revision that doesn't

 You will then do:

         . Rebuild a revision that you believe works, install, and verify that.
         . Do a binary search over the kernels to figure out which one
           introduced the bug.  I.e., suppose 1.3.28 didn't have the bug, but
           you know that 1.3.69 does.  Pick a kernel in the middle and build
           that, like 1.3.50.  Build & test; if it works, pick the mid point
           between .50 and .69, else the mid point between .28 and .50.
         . You'll narrow it down to the kernel that introduced the bug.  You
           can probably do better than this but it gets tricky.

         . Narrow it down to a subdirectory

           - Copy kernel that works into "test".  Let's say that 3.62 works,
             but 3.63 doesn't.  So you diff -r those two kernels and come
             up with a list of directories that changed.  For each of those
             directories:

                 Copy the non-working directory next to the working directory
                 as "dir.63".
                 One directory at time, try moving the working directory to
                 "dir.62" and mv dir.63 dir"time, try

                         mv dir dir.62
                         mv dir.63 dir
                         find dir -name '*.[oa]' -print | xargs rm -f

                 And then rebuild and retest.  Assuming that all related
                 changes were contained in the sub directory, this should
                 isolate the change to a directory.

                 Problems: changes in header files may have occurred; I've
                 found in my case that they were self explanatory - you may
                 or may not want to give up when that happens.

         . Narrow it down to a file

           - You can apply the same technique to each file in the directory,
             hoping that the changes in that file are self contained.

         . Narrow it down to a routine

           - You can take the old file and the new file and manually create
             a merged file that has

                 #ifdef VER62
                 routine()
                 {
                         ...
                 }
                 #else
                 routine()
                 {
                         ...
                 }
                 #endif

             And then walk through that file, one routine at a time and
             prefix it with

                 #define VER62
                 /* both routines here */
                 #undef VER62

             Then recompile, retest, move the ifdefs until you find the one
             that makes the difference.

 Finally, you take all the info that you have, kernel revisions, bug
 description, the extent to which you have narrowed it down, and pass
 that off to whomever you believe is the maintainer of that section.
 A post to linux.dev.kernel isn't such a bad idea if you've done some
 work to narrow it down.

 If you get it down to a routine, you'll probably get a fix in 24 hours.

 My apologies to Linus and the other kernel hackers for describing this
 brute force approach, it's hardly what a kernel hacker would do.  However,
 it does work and it lets non-hackers help fix bugs.  And it is cool
 because Linux snapshots will let you do this - something that you can't
 do with vendor supplied releases.

 Fixing the bug
 ==============

 Nobody is going to tell you how to fix bugs. Seriously. You need to work it
 out. But below are some hints on how to use the tools.

 To debug a kernel, use objdump and look for the hex offset from the crash
 output to find the valid line of code/assembler. Without debug symbols, you
 will see the assembler code for the routine shown, but if your kernel has
 debug symbols the C code will also be available. (Debug symbols can be enabled
 in the kernel hacking menu of the menu configuration.) For example:

     objdump -r -S -l --disassemble net/dccp/ipv4.o

 NB.: you need to be at the top level of the kernel tree for this to pick up
 your C files.

 If you don't have access to the code you can also debug on some crash dumps
 e.g. crash dump output as shown by Dave Miller.

 >    EIP is at ip_queue_xmit+0x14/0x4c0
 >     ...
 >    Code: 44 24 04 e8 6f 05 00 00 e9 e8 fe ff ff 8d 76 00 8d bc 27 00 00
 >    00 00 55 57  56 53 81 ec bc 00 00 00 8b ac 24 d0 00 00 00 8b 5d 08
 >    <8b> 83 3c 01 00 00 89 44  24 14 8b 45 28 85 c0 89 44 24 18 0f 85
 >
 >    Put the bytes into a "foo.s" file like this:
 >
 >           .text
 >           .globl foo
 >    foo:
 >           .byte  .... /* bytes from Code: part of OOPS dump */
 >
 >    Compile it with "gcc -c -o foo.o foo.s" then look at the output of
 >    "objdump --disassemble foo.o".
 >
 >    Output:
 >
 >    ip_queue_xmit:
 >        push       %ebp
 >        push       %edi
 >        push       %esi
 >        push       %ebx
 >        sub        $0xbc, %esp
 >        mov        0xd0(%esp), %ebp        ! %ebp = arg0 (skb)
 >        mov        0x8(%ebp), %ebx         ! %ebx = skb->sk
 >        mov        0x13c(%ebx), %eax       ! %eax = inet_sk(sk)->opt

 In addition, you can use GDB to figure out the exact file and line
 number of the OOPS from the vmlinux file. If you have
 CONFIG_DEBUG_INFO enabled, you can simply copy the EIP value from the
 OOPS:

  EIP:    0060:[<c021e50e>]    Not tainted VLI

 And use GDB to translate that to human-readable form:

   gdb vmlinux
   (gdb) l *0xc021e50e

 If you don't have CONFIG_DEBUG_INFO enabled, you use the function
 offset from the OOPS:

  EIP is at vt_ioctl+0xda8/0x1482

 And recompile the kernel with CONFIG_DEBUG_INFO enabled:

   make vmlinux
   gdb vmlinux
   (gdb) p vt_ioctl
   (gdb) l *(0x<address of vt_ioctl> + 0xda8)
 or, as one command
   (gdb) l *(vt_ioctl + 0xda8)

 If you have a call trace, such as :-
 >Call Trace:
 > [<ffffffff8802c8e9>] :jbd:log_wait_commit+0xa3/0xf5
 > [<ffffffff810482d9>] autoremove_wake_function+0x0/0x2e
 > [<ffffffff8802770b>] :jbd:journal_stop+0x1be/0x1ee
 > ...
 this shows the problem in the :jbd: module. You can load that module in gdb
 and list the relevant code.
   gdb fs/jbd/jbd.ko
   (gdb) p log_wait_commit
   (gdb) l *(0x<address> + 0xa3)
 or
   (gdb) l *(log_wait_commit + 0xa3)


 Another very useful option of the Kernel Hacking section in menuconfig is
 Debug memory allocations. This will help you see whether data has been
 initialised and not set before use etc. To see the values that get assigned
 with this look at mm/slab.c and search for POISON_INUSE. When using this an
 Oops will often show the poisoned data instead of zero which is the default.

 Once you have worked out a fix please submit it upstream. After all open
 source is about sharing what you do and don't you want to be recognised for
 your genius?

 Please do read Documentation/SubmittingPatches though to help your code get
 accepted.
	Table of contents
	=================

	Last updated: 20 December 2005

	Contents
	========

	- Introduction
	- Devices not appearing
	- Finding patch that caused a bug
	-- Finding using git-bisect
	-- Finding it the old way
	- Fixing the bug

	Introduction
	============

	Always try the latest kernel from kernel.org and build from source. If you are
	not confident in doing that please report the bug to your distribution vendor
	instead of to a kernel developer.

	Finding bugs is not always easy. Have a go though. If you can't find it don't
	give up. Report as much as you have found to the relevant maintainer. See
	MAINTAINERS for who that is for the subsystem you have worked on.

	Before you submit a bug report read REPORTING-BUGS.

	Devices not appearing
	=====================

	Often this is caused by udev. Check that first before blaming it on the
	kernel.

	Finding patch that caused a bug
	===============================



	Finding using git-bisect
	------------------------

	Using the provided tools with git makes finding bugs easy provided the bug is
	reproducible.

	Steps to do it:
	- start using git for the kernel source
	- read the man page for git-bisect
	- have fun

	Finding it the old way
	----------------------

	[Sat Mar 2 10:32:33 PST 1996 KERNEL_BUG-HOWTO lm@sgi.com (Larry McVoy)]

	This is how to track down a bug if you know nothing about kernel hacking.
	It's a brute force approach but it works pretty well.

	You need:

	. A reproducible bug - it has to happen predictably (sorry)
	. All the kernel tar files from a revision that worked to the
	revision that doesn't

	You will then do:

	. Rebuild a revision that you believe works, install, and verify that.
	. Do a binary search over the kernels to figure out which one
	introduced the bug. I.e., suppose 1.3.28 didn't have the bug, but
	you know that 1.3.69 does. Pick a kernel in the middle and build
	that, like 1.3.50. Build & test; if it works, pick the mid point
	between .50 and .69, else the mid point between .28 and .50.
	. You'll narrow it down to the kernel that introduced the bug. You
	can probably do better than this but it gets tricky.

	. Narrow it down to a subdirectory

	- Copy kernel that works into "test". Let's say that 3.62 works,
	but 3.63 doesn't. So you diff -r those two kernels and come
	up with a list of directories that changed. For each of those
	directories:

	Copy the non-working directory next to the working directory
	as "dir.63".
	One directory at time, try moving the working directory to
	"dir.62" and mv dir.63 dir"time, try

	mv dir dir.62
	mv dir.63 dir
	find dir -name '*.[oa]' -print \| xargs rm -f

	And then rebuild and retest. Assuming that all related
	changes were contained in the sub directory, this should
	isolate the change to a directory.

	Problems: changes in header files may have occurred; I've
	found in my case that they were self explanatory - you may
	or may not want to give up when that happens.

	. Narrow it down to a file

	- You can apply the same technique to each file in the directory,
	hoping that the changes in that file are self contained.

	. Narrow it down to a routine

	- You can take the old file and the new file and manually create
	a merged file that has

	#ifdef VER62
	routine()
	{
	...
	}
	#else
	routine()
	{
	...
	}
	#endif

	And then walk through that file, one routine at a time and
	prefix it with

	#define VER62
	/* both routines here */
	#undef VER62

	Then recompile, retest, move the ifdefs until you find the one
	that makes the difference.

	Finally, you take all the info that you have, kernel revisions, bug
	description, the extent to which you have narrowed it down, and pass
	that off to whomever you believe is the maintainer of that section.
	A post to linux.dev.kernel isn't such a bad idea if you've done some
	work to narrow it down.

	If you get it down to a routine, you'll probably get a fix in 24 hours.

	My apologies to Linus and the other kernel hackers for describing this
	brute force approach, it's hardly what a kernel hacker would do. However,
	it does work and it lets non-hackers help fix bugs. And it is cool
	because Linux snapshots will let you do this - something that you can't
	do with vendor supplied releases.

	Fixing the bug
	==============

	Nobody is going to tell you how to fix bugs. Seriously. You need to work it
	out. But below are some hints on how to use the tools.

	To debug a kernel, use objdump and look for the hex offset from the crash
	output to find the valid line of code/assembler. Without debug symbols, you
	will see the assembler code for the routine shown, but if your kernel has
	debug symbols the C code will also be available. (Debug symbols can be enabled
	in the kernel hacking menu of the menu configuration.) For example:

	objdump -r -S -l --disassemble net/dccp/ipv4.o

	NB.: you need to be at the top level of the kernel tree for this to pick up
	your C files.

	If you don't have access to the code you can also debug on some crash dumps
	e.g. crash dump output as shown by Dave Miller.

	> EIP is at ip_queue_xmit+0x14/0x4c0
	> ...
	> Code: 44 24 04 e8 6f 05 00 00 e9 e8 fe ff ff 8d 76 00 8d bc 27 00 00
	> 00 00 55 57 56 53 81 ec bc 00 00 00 8b ac 24 d0 00 00 00 8b 5d 08
	> <8b> 83 3c 01 00 00 89 44 24 14 8b 45 28 85 c0 89 44 24 18 0f 85
	>
	> Put the bytes into a "foo.s" file like this:
	>
	> .text
	> .globl foo
	> foo:
	> .byte .... /* bytes from Code: part of OOPS dump */
	>
	> Compile it with "gcc -c -o foo.o foo.s" then look at the output of
	> "objdump --disassemble foo.o".
	>
	> Output:
	>
	> ip_queue_xmit:
	> push %ebp
	> push %edi
	> push %esi
	> push %ebx
	> sub $0xbc, %esp
	> mov 0xd0(%esp), %ebp ! %ebp = arg0 (skb)
	> mov 0x8(%ebp), %ebx ! %ebx = skb->sk
	> mov 0x13c(%ebx), %eax ! %eax = inet_sk(sk)->opt

	In addition, you can use GDB to figure out the exact file and line
	number of the OOPS from the vmlinux file. If you have
	CONFIG_DEBUG_INFO enabled, you can simply copy the EIP value from the
	OOPS:

	EIP: 0060:[<c021e50e>] Not tainted VLI

	And use GDB to translate that to human-readable form:

	gdb vmlinux
	(gdb) l *0xc021e50e

	If you don't have CONFIG_DEBUG_INFO enabled, you use the function
	offset from the OOPS:

	EIP is at vt_ioctl+0xda8/0x1482

	And recompile the kernel with CONFIG_DEBUG_INFO enabled:

	make vmlinux
	gdb vmlinux
	(gdb) p vt_ioctl
	(gdb) l *(0x<address of vt_ioctl> + 0xda8)
	or, as one command
	(gdb) l *(vt_ioctl + 0xda8)

	If you have a call trace, such as :-
	>Call Trace:
	> [<ffffffff8802c8e9>] :jbd:log_wait_commit+0xa3/0xf5
	> [<ffffffff810482d9>] autoremove_wake_function+0x0/0x2e
	> [<ffffffff8802770b>] :jbd:journal_stop+0x1be/0x1ee
	> ...
	this shows the problem in the :jbd: module. You can load that module in gdb
	and list the relevant code.
	gdb fs/jbd/jbd.ko
	(gdb) p log_wait_commit
	(gdb) l *(0x<address> + 0xa3)
	or
	(gdb) l *(log_wait_commit + 0xa3)


	Another very useful option of the Kernel Hacking section in menuconfig is
	Debug memory allocations. This will help you see whether data has been
	initialised and not set before use etc. To see the values that get assigned
	with this look at mm/slab.c and search for POISON_INUSE. When using this an
	Oops will often show the poisoned data instead of zero which is the default.

	Once you have worked out a fix please submit it upstream. After all open
	source is about sharing what you do and don't you want to be recognised for
	your genius?

	Please do read Documentation/SubmittingPatches though to help your code get
	accepted.