[net-next-2.6.git] / Documentation / nmi_watchdog.txt


[NMI watchdog is available for x86 and x86-64 architectures]

Is your system locking up unpredictably? No keyboard activity, just
a frustrating complete hard lockup? Do you want to help us debugging
such lockups? If all yes then this document is definitely for you.

On many x86/x86-64 type hardware there is a feature that enables
us to generate 'watchdog NMI interrupts'.  (NMI: Non Maskable Interrupt
which get executed even if the system is otherwise locked up hard).
This can be used to debug hard kernel lockups.  By executing periodic
NMI interrupts, the kernel can monitor whether any CPU has locked up,
and print out debugging messages if so.  

In order to use the NMI watchdog, you need to have APIC support in your
kernel. For SMP kernels, APIC support gets compiled in automatically. For
UP, enable either CONFIG_X86_UP_APIC (Processor type and features -> Local
APIC support on uniprocessors) or CONFIG_X86_UP_IOAPIC (Processor type and
features -> IO-APIC support on uniprocessors) in your kernel config.
CONFIG_X86_UP_APIC is for uniprocessor machines without an IO-APIC.
CONFIG_X86_UP_IOAPIC is for uniprocessor with an IO-APIC. [Note: certain
kernel debugging options, such as Kernel Stack Meter or Kernel Tracer,
may implicitly disable the NMI watchdog.]

For x86-64, the needed APIC is always compiled in, and the NMI watchdog is
always enabled with I/O-APIC mode (nmi_watchdog=1).

Using local APIC (nmi_watchdog=2) needs the first performance register, so
you can't use it for other purposes (such as high precision performance
profiling.) However, at least oprofile and the perfctr driver disable the
local APIC NMI watchdog automatically.

To actually enable the NMI watchdog, use the 'nmi_watchdog=N' boot
parameter.  Eg. the relevant lilo.conf entry:

        append="nmi_watchdog=1"

For SMP machines and UP machines with an IO-APIC use nmi_watchdog=1.
For UP machines without an IO-APIC use nmi_watchdog=2, this only works
for some processor types.  If in doubt, boot with nmi_watchdog=1 and
check the NMI count in /proc/interrupts; if the count is zero then
reboot with nmi_watchdog=2 and check the NMI count.  If it is still
zero then log a problem, you probably have a processor that needs to be
added to the nmi code.

A 'lockup' is the following scenario: if any CPU in the system does not
execute the period local timer interrupt for more than 5 seconds, then
the NMI handler generates an oops and kills the process. This
'controlled crash' (and the resulting kernel messages) can be used to
debug the lockup. Thus whenever the lockup happens, wait 5 seconds and
the oops will show up automatically. If the kernel produces no messages
then the system has crashed so hard (eg. hardware-wise) that either it
cannot even accept NMI interrupts, or the crash has made the kernel
unable to print messages.

Be aware that when using local APIC, the frequency of NMI interrupts
it generates, depends on the system load. The local APIC NMI watchdog,
lacking a better source, uses the "cycles unhalted" event. As you may
guess it doesn't tick when the CPU is in the halted state (which happens
when the system is idle), but if your system locks up on anything but the
"hlt" processor instruction, the watchdog will trigger very soon as the
"cycles unhalted" event will happen every clock tick. If it locks up on
"hlt", then you are out of luck -- the event will not happen at all and the
watchdog won't trigger. This is a shortcoming of the local APIC watchdog
-- unfortunately there is no "clock ticks" event that would work all the
time. The I/O APIC watchdog is driven externally and has no such shortcoming.  
But its NMI frequency is much higher, resulting in a more significant hit
to the overall system performance.

NOTE: starting with 2.4.2-ac18 the NMI-oopser is disabled by default,
you have to enable it with a boot time parameter.  Prior to 2.4.2-ac18
the NMI-oopser is enabled unconditionally on x86 SMP boxes.

On x86-64 the NMI oopser is on by default. On 64bit Intel CPUs
it uses IO-APIC by default and on AMD it uses local APIC.

[ feel free to send bug reports, suggestions and patches to
  Ingo Molnar <mingo@redhat.com> or the Linux SMP mailing
  list at <linux-smp@vger.kernel.org> ]
Commit	Line	Data
1da177e4 LT	1
	2	[NMI watchdog is available for x86 and x86-64 architectures]
	3
	4	Is your system locking up unpredictably? No keyboard activity, just
	5	a frustrating complete hard lockup? Do you want to help us debugging
	6	such lockups? If all yes then this document is definitely for you.
	7
	8	On many x86/x86-64 type hardware there is a feature that enables
	9	us to generate 'watchdog NMI interrupts'. (NMI: Non Maskable Interrupt
	10	which get executed even if the system is otherwise locked up hard).
	11	This can be used to debug hard kernel lockups. By executing periodic
	12	NMI interrupts, the kernel can monitor whether any CPU has locked up,
	13	and print out debugging messages if so.
	14
	15	In order to use the NMI watchdog, you need to have APIC support in your
	16	kernel. For SMP kernels, APIC support gets compiled in automatically. For
	17	UP, enable either CONFIG_X86_UP_APIC (Processor type and features -> Local
	18	APIC support on uniprocessors) or CONFIG_X86_UP_IOAPIC (Processor type and
	19	features -> IO-APIC support on uniprocessors) in your kernel config.
	20	CONFIG_X86_UP_APIC is for uniprocessor machines without an IO-APIC.
	21	CONFIG_X86_UP_IOAPIC is for uniprocessor with an IO-APIC. [Note: certain
	22	kernel debugging options, such as Kernel Stack Meter or Kernel Tracer,
	23	may implicitly disable the NMI watchdog.]
	24
	25	For x86-64, the needed APIC is always compiled in, and the NMI watchdog is
5abbcf29	26	always enabled with I/O-APIC mode (nmi_watchdog=1).
1da177e4 LT	27
	28	Using local APIC (nmi_watchdog=2) needs the first performance register, so
	29	you can't use it for other purposes (such as high precision performance
	30	profiling.) However, at least oprofile and the perfctr driver disable the
	31	local APIC NMI watchdog automatically.
	32
	33	To actually enable the NMI watchdog, use the 'nmi_watchdog=N' boot
	34	parameter. Eg. the relevant lilo.conf entry:
	35
	36	append="nmi_watchdog=1"
	37
	38	For SMP machines and UP machines with an IO-APIC use nmi_watchdog=1.
	39	For UP machines without an IO-APIC use nmi_watchdog=2, this only works
	40	for some processor types. If in doubt, boot with nmi_watchdog=1 and
	41	check the NMI count in /proc/interrupts; if the count is zero then
	42	reboot with nmi_watchdog=2 and check the NMI count. If it is still
	43	zero then log a problem, you probably have a processor that needs to be
	44	added to the nmi code.
	45
	46	A 'lockup' is the following scenario: if any CPU in the system does not
	47	execute the period local timer interrupt for more than 5 seconds, then
	48	the NMI handler generates an oops and kills the process. This
	49	'controlled crash' (and the resulting kernel messages) can be used to
	50	debug the lockup. Thus whenever the lockup happens, wait 5 seconds and
	51	the oops will show up automatically. If the kernel produces no messages
	52	then the system has crashed so hard (eg. hardware-wise) that either it
	53	cannot even accept NMI interrupts, or the crash has made the kernel
	54	unable to print messages.
	55
	56	Be aware that when using local APIC, the frequency of NMI interrupts
	57	it generates, depends on the system load. The local APIC NMI watchdog,
	58	lacking a better source, uses the "cycles unhalted" event. As you may
	59	guess it doesn't tick when the CPU is in the halted state (which happens
	60	when the system is idle), but if your system locks up on anything but the
	61	"hlt" processor instruction, the watchdog will trigger very soon as the
	62	"cycles unhalted" event will happen every clock tick. If it locks up on
	63	"hlt", then you are out of luck -- the event will not happen at all and the
	64	watchdog won't trigger. This is a shortcoming of the local APIC watchdog
	65	-- unfortunately there is no "clock ticks" event that would work all the
	66	time. The I/O APIC watchdog is driven externally and has no such shortcoming.
	67	But its NMI frequency is much higher, resulting in a more significant hit
	68	to the overall system performance.
	69
	70	NOTE: starting with 2.4.2-ac18 the NMI-oopser is disabled by default,
	71	you have to enable it with a boot time parameter. Prior to 2.4.2-ac18
	72	the NMI-oopser is enabled unconditionally on x86 SMP boxes.
	73
	74	On x86-64 the NMI oopser is on by default. On 64bit Intel CPUs
	75	it uses IO-APIC by default and on AMD it uses local APIC.
	76
	77	[ feel free to send bug reports, suggestions and patches to
	78	Ingo Molnar <mingo@redhat.com> or the Linux SMP mailing
	79	list at <linux-smp@vger.kernel.org> ]
	80