[linux.git] / Documentation / gdb-kernel-debugging.txt

Debugging kernel and modules via gdb
====================================

The kernel debugger kgdb, hypervisors like QEMU or JTAG-based hardware
interfaces allow to debug the Linux kernel and its modules during runtime
using gdb. Gdb comes with a powerful scripting interface for python. The
kernel provides a collection of helper scripts that can simplify typical
kernel debugging steps. This is a short tutorial about how to enable and use
them. It focuses on QEMU/KVM virtual machines as target, but the examples can
be transferred to the other gdb stubs as well.


Requirements
------------

 o gdb 7.2+ (recommended: 7.4+) with python support enabled (typically true
   for distributions)


Setup
-----

 o Create a virtual Linux machine for QEMU/KVM (see www.linux-kvm.org and
   www.qemu.org for more details). For cross-development,
   http://landley.net/aboriginal/bin keeps a pool of machine images and
   toolchains that can be helpful to start from.

 o Build the kernel with CONFIG_GDB_SCRIPTS enabled, but leave
   CONFIG_DEBUG_INFO_REDUCED off. If your architecture supports
   CONFIG_FRAME_POINTER, keep it enabled.

 o Install that kernel on the guest.

   Alternatively, QEMU allows to boot the kernel directly using -kernel,
   -append, -initrd command line switches. This is generally only useful if
   you do not depend on modules. See QEMU documentation for more details on
   this mode.

 o Enable the gdb stub of QEMU/KVM, either
    - at VM startup time by appending "-s" to the QEMU command line
   or
    - during runtime by issuing "gdbserver" from the QEMU monitor
      console

 o cd /path/to/linux-build

 o Start gdb: gdb vmlinux

   Note: Some distros may restrict auto-loading of gdb scripts to known safe
   directories. In case gdb reports to refuse loading vmlinux-gdb.py, add

    add-auto-load-safe-path /path/to/linux-build

   to ~/.gdbinit. See gdb help for more details.

 o Attach to the booted guest:
    (gdb) target remote :1234


Examples of using the Linux-provided gdb helpers
------------------------------------------------

 o Load module (and main kernel) symbols:
    (gdb) lx-symbols
    loading vmlinux
    scanning for modules in /home/user/linux/build
    loading @0xffffffffa0020000: /home/user/linux/build/net/netfilter/xt_tcpudp.ko
    loading @0xffffffffa0016000: /home/user/linux/build/net/netfilter/xt_pkttype.ko
    loading @0xffffffffa0002000: /home/user/linux/build/net/netfilter/xt_limit.ko
    loading @0xffffffffa00ca000: /home/user/linux/build/net/packet/af_packet.ko
    loading @0xffffffffa003c000: /home/user/linux/build/fs/fuse/fuse.ko
    ...
    loading @0xffffffffa0000000: /home/user/linux/build/drivers/ata/ata_generic.ko

 o Set a breakpoint on some not yet loaded module function, e.g.:
    (gdb) b btrfs_init_sysfs
    Function "btrfs_init_sysfs" not defined.
    Make breakpoint pending on future shared library load? (y or [n]) y
    Breakpoint 1 (btrfs_init_sysfs) pending.

 o Continue the target
    (gdb) c

 o Load the module on the target and watch the symbols being loaded as well as
   the breakpoint hit:
    loading @0xffffffffa0034000: /home/user/linux/build/lib/libcrc32c.ko
    loading @0xffffffffa0050000: /home/user/linux/build/lib/lzo/lzo_compress.ko
    loading @0xffffffffa006e000: /home/user/linux/build/lib/zlib_deflate/zlib_deflate.ko
    loading @0xffffffffa01b1000: /home/user/linux/build/fs/btrfs/btrfs.ko

    Breakpoint 1, btrfs_init_sysfs () at /home/user/linux/fs/btrfs/sysfs.c:36
    36              btrfs_kset = kset_create_and_add("btrfs", NULL, fs_kobj);

 o Dump the log buffer of the target kernel:
    (gdb) lx-dmesg
    [     0.000000] Initializing cgroup subsys cpuset
    [     0.000000] Initializing cgroup subsys cpu
    [     0.000000] Linux version 3.8.0-rc4-dbg+ (...
    [     0.000000] Command line: root=/dev/sda2 resume=/dev/sda1 vga=0x314
    [     0.000000] e820: BIOS-provided physical RAM map:
    [     0.000000] BIOS-e820: [mem 0x0000000000000000-0x000000000009fbff] usable
    [     0.000000] BIOS-e820: [mem 0x000000000009fc00-0x000000000009ffff] reserved
    ....

 o Examine fields of the current task struct:
    (gdb) p $lx_current().pid
    $1 = 4998
    (gdb) p $lx_current().comm
    $2 = "modprobe\000\000\000\000\000\000\000"

 o Make use of the per-cpu function for the current or a specified CPU:
    (gdb) p $lx_per_cpu("runqueues").nr_running
    $3 = 1
    (gdb) p $lx_per_cpu("runqueues", 2).nr_running
    $4 = 0

 o Dig into hrtimers using the container_of helper:
    (gdb) set $next = $lx_per_cpu("hrtimer_bases").clock_base[0].active.next
    (gdb) p *$container_of($next, "struct hrtimer", "node")
    $5 = {
      node = {
        node = {
          __rb_parent_color = 18446612133355256072,
          rb_right = 0x0 <irq_stack_union>,
          rb_left = 0x0 <irq_stack_union>
        },
        expires = {
          tv64 = 1835268000000
        }
      },
      _softexpires = {
        tv64 = 1835268000000
      },
      function = 0xffffffff81078232 <tick_sched_timer>,
      base = 0xffff88003fd0d6f0,
      state = 1,
      start_pid = 0,
      start_site = 0xffffffff81055c1f <hrtimer_start_range_ns+20>,
      start_comm = "swapper/2\000\000\000\000\000\000"
    }

 o Dig into a radix tree data structure, such as the IRQ descriptors:
    (gdb) print (struct irq_desc)$lx_radix_tree_lookup(irq_desc_tree, 18)
    $6 = {
      irq_common_data = {
        state_use_accessors = 67584,
        handler_data = 0x0 <__vectors_start>,
        msi_desc = 0x0 <__vectors_start>,
        affinity = {{
            bits = {65535}
          }}
      },
      irq_data = {
        mask = 0,
        irq = 18,
        hwirq = 27,
        common = 0xee803d80,
        chip = 0xc0eb0854 <gic_data>,
        domain = 0xee808000,
        parent_data = 0x0 <__vectors_start>,
        chip_data = 0xc0eb0854 <gic_data>
      } <... trimmed ...>

List of commands and functions
------------------------------

The number of commands and convenience functions may evolve over the time,
this is just a snapshot of the initial version:

 (gdb) apropos lx
 function lx_current -- Return current task
 function lx_module -- Find module by name and return the module variable
 function lx_per_cpu -- Return per-cpu variable
 function lx_task_by_pid -- Find Linux task by PID and return the task_struct variable
 function lx_thread_info -- Calculate Linux thread_info from task variable
 lx-dmesg -- Print Linux kernel log buffer
 lx-lsmod -- List currently loaded modules
 lx-symbols -- (Re-)load symbols of Linux kernel and currently loaded modules

Detailed help can be obtained via "help <command-name>" for commands and "help
function <function-name>" for convenience functions.
Commit	Line	Data
bda1a921 JK	1	Debugging kernel and modules via gdb
	2	====================================
	3
	4	The kernel debugger kgdb, hypervisors like QEMU or JTAG-based hardware
	5	interfaces allow to debug the Linux kernel and its modules during runtime
	6	using gdb. Gdb comes with a powerful scripting interface for python. The
	7	kernel provides a collection of helper scripts that can simplify typical
	8	kernel debugging steps. This is a short tutorial about how to enable and use
	9	them. It focuses on QEMU/KVM virtual machines as target, but the examples can
	10	be transferred to the other gdb stubs as well.
	11
	12
	13	Requirements
	14	------------
	15
	16	o gdb 7.2+ (recommended: 7.4+) with python support enabled (typically true
	17	for distributions)
	18
	19
	20	Setup
	21	-----
	22
	23	o Create a virtual Linux machine for QEMU/KVM (see www.linux-kvm.org and
	24	www.qemu.org for more details). For cross-development,
	25	http://landley.net/aboriginal/bin keeps a pool of machine images and
	26	toolchains that can be helpful to start from.
	27
	28	o Build the kernel with CONFIG_GDB_SCRIPTS enabled, but leave
	29	CONFIG_DEBUG_INFO_REDUCED off. If your architecture supports
	30	CONFIG_FRAME_POINTER, keep it enabled.
	31
	32	o Install that kernel on the guest.
	33
	34	Alternatively, QEMU allows to boot the kernel directly using -kernel,
	35	-append, -initrd command line switches. This is generally only useful if
	36	you do not depend on modules. See QEMU documentation for more details on
	37	this mode.
	38
	39	o Enable the gdb stub of QEMU/KVM, either
	40	- at VM startup time by appending "-s" to the QEMU command line
	41	or
	42	- during runtime by issuing "gdbserver" from the QEMU monitor
	43	console
	44
	45	o cd /path/to/linux-build
	46
	47	o Start gdb: gdb vmlinux
	48
	49	Note: Some distros may restrict auto-loading of gdb scripts to known safe
	50	directories. In case gdb reports to refuse loading vmlinux-gdb.py, add
	51
	52	add-auto-load-safe-path /path/to/linux-build
	53
	54	to ~/.gdbinit. See gdb help for more details.
	55
	56	o Attach to the booted guest:
	57	(gdb) target remote :1234
	58
	59
	60	Examples of using the Linux-provided gdb helpers
	61	------------------------------------------------
	62
	63	o Load module (and main kernel) symbols:
	64	(gdb) lx-symbols
65	loading vmlinux
66	scanning for modules in /home/user/linux/build
67	loading @0xffffffffa0020000: /home/user/linux/build/net/netfilter/xt_tcpudp.ko
68	loading @0xffffffffa0016000: /home/user/linux/build/net/netfilter/xt_pkttype.ko
69	loading @0xffffffffa0002000: /home/user/linux/build/net/netfilter/xt_limit.ko
70	loading @0xffffffffa00ca000: /home/user/linux/build/net/packet/af_packet.ko
71	loading @0xffffffffa003c000: /home/user/linux/build/fs/fuse/fuse.ko
72	...
73	loading @0xffffffffa0000000: /home/user/linux/build/drivers/ata/ata_generic.ko
74
75	o Set a breakpoint on some not yet loaded module function, e.g.:
76	(gdb) b btrfs_init_sysfs
77	Function "btrfs_init_sysfs" not defined.
78	Make breakpoint pending on future shared library load? (y or [n]) y
79	Breakpoint 1 (btrfs_init_sysfs) pending.
80
81	o Continue the target
82	(gdb) c
83
84	o Load the module on the target and watch the symbols being loaded as well as
85	the breakpoint hit:
86	loading @0xffffffffa0034000: /home/user/linux/build/lib/libcrc32c.ko
87	loading @0xffffffffa0050000: /home/user/linux/build/lib/lzo/lzo_compress.ko
88	loading @0xffffffffa006e000: /home/user/linux/build/lib/zlib_deflate/zlib_deflate.ko
89	loading @0xffffffffa01b1000: /home/user/linux/build/fs/btrfs/btrfs.ko
90
91	Breakpoint 1, btrfs_init_sysfs () at /home/user/linux/fs/btrfs/sysfs.c:36
92	36 btrfs_kset = kset_create_and_add("btrfs", NULL, fs_kobj);
93
94	o Dump the log buffer of the target kernel:
95	(gdb) lx-dmesg
96	[ 0.000000] Initializing cgroup subsys cpuset
97	[ 0.000000] Initializing cgroup subsys cpu
98	[ 0.000000] Linux version 3.8.0-rc4-dbg+ (...
99	[ 0.000000] Command line: root=/dev/sda2 resume=/dev/sda1 vga=0x314
100	[ 0.000000] e820: BIOS-provided physical RAM map:
101	[ 0.000000] BIOS-e820: [mem 0x0000000000000000-0x000000000009fbff] usable
102	[ 0.000000] BIOS-e820: [mem 0x000000000009fc00-0x000000000009ffff] reserved
103	....
104
105	o Examine fields of the current task struct:
106	(gdb) p $lx_current().pid
107	$1 = 4998
108	(gdb) p $lx_current().comm
109	$2 = "modprobe\000\000\000\000\000\000\000"
110
111	o Make use of the per-cpu function for the current or a specified CPU:
112	(gdb) p $lx_per_cpu("runqueues").nr_running
113	$3 = 1
114	(gdb) p $lx_per_cpu("runqueues", 2).nr_running
115	$4 = 0
116
117	o Dig into hrtimers using the container_of helper:
118	(gdb) set $next = $lx_per_cpu("hrtimer_bases").clock_base[0].active.next
119	(gdb) p *$container_of($next, "struct hrtimer", "node")
120	$5 = {
121	node = {
122	node = {
123	__rb_parent_color = 18446612133355256072,
124	rb_right = 0x0 <irq_stack_union>,
125	rb_left = 0x0 <irq_stack_union>
126	},
127	expires = {
128	tv64 = 1835268000000
129	}
130	},
131	_softexpires = {
132	tv64 = 1835268000000
133	},
134	function = 0xffffffff81078232 <tick_sched_timer>,
135	base = 0xffff88003fd0d6f0,
136	state = 1,
137	start_pid = 0,
138	start_site = 0xffffffff81055c1f <hrtimer_start_range_ns+20>,
139	start_comm = "swapper/2\000\000\000\000\000\000"
140	}
141
9b558035 KB	142	o Dig into a radix tree data structure, such as the IRQ descriptors:
	143	(gdb) print (struct irq_desc)$lx_radix_tree_lookup(irq_desc_tree, 18)
	144	$6 = {
	145	irq_common_data = {
	146	state_use_accessors = 67584,
	147	handler_data = 0x0 <__vectors_start>,
	148	msi_desc = 0x0 <__vectors_start>,
	149	affinity = {{
	150	bits = {65535}
	151	}}
	152	},
	153	irq_data = {
	154	mask = 0,
	155	irq = 18,
	156	hwirq = 27,
	157	common = 0xee803d80,
	158	chip = 0xc0eb0854 <gic_data>,
	159	domain = 0xee808000,
	160	parent_data = 0x0 <__vectors_start>,
	161	chip_data = 0xc0eb0854 <gic_data>
	162	} <... trimmed ...>
bda1a921 JK	163
	164	List of commands and functions
	165	------------------------------
	166
	167	The number of commands and convenience functions may evolve over the time,
	168	this is just a snapshot of the initial version:
	169
	170	(gdb) apropos lx
	171	function lx_current -- Return current task
	172	function lx_module -- Find module by name and return the module variable
	173	function lx_per_cpu -- Return per-cpu variable
	174	function lx_task_by_pid -- Find Linux task by PID and return the task_struct variable
	175	function lx_thread_info -- Calculate Linux thread_info from task variable
	176	lx-dmesg -- Print Linux kernel log buffer
	177	lx-lsmod -- List currently loaded modules
	178	lx-symbols -- (Re-)load symbols of Linux kernel and currently loaded modules
	179
	180	Detailed help can be obtained via "help <command-name>" for commands and "help
	181	function <function-name>" for convenience functions.