Documentation/ramoops.txt - kernel/common - Git at Google

 Ramoops oops/panic logger
 =========================

 Sergiu Iordache <[email protected]>

 Updated: 17 November 2011

 0. Introduction

 Ramoops is an oops/panic logger that writes its logs to RAM before the system
 crashes. It works by logging oopses and panics in a circular buffer. Ramoops
 needs a system with persistent RAM so that the content of that area can
 survive after a restart.

 1. Ramoops concepts

 Ramoops uses a predefined memory area to store the dump. The start and size of
 the memory area are set using two variables:
   * "mem_address" for the start
   * "mem_size" for the size. The memory size will be rounded down to a
   power of two.

 The memory area is divided into "record_size" chunks (also rounded down to
 power of two) and each oops/panic writes a "record_size" chunk of
 information.

 Dumping both oopses and panics can be done by setting 1 in the "dump_oops"
 variable while setting 0 in that variable dumps only the panics.

 The module uses a counter to record multiple dumps but the counter gets reset
 on restart (i.e. new dumps after the restart will overwrite old ones).

 Ramoops also supports software ECC protection of persistent memory regions.
 This might be useful when a hardware reset was used to bring the machine back
 to life (i.e. a watchdog triggered). In such cases, RAM may be somewhat
 corrupt, but usually it is restorable.

 2. Setting the parameters

 Setting the ramoops parameters can be done in 2 different manners:
  1. Use the module parameters (which have the names of the variables described
  as before).
  For quick debugging, you can also reserve parts of memory during boot
  and then use the reserved memory for ramoops. For example, assuming a machine
  with > 128 MB of memory, the following kernel command line will tell the
  kernel to use only the first 128 MB of memory, and place ECC-protected ramoops
  region at 128 MB boundary:
  "mem=128M ramoops.mem_address=0x8000000 ramoops.ecc=1"
  2. Use a platform device and set the platform data. The parameters can then
  be set through that platform data. An example of doing that is:

 #include <linux/pstore_ram.h>
 [...]

 static struct ramoops_platform_data ramoops_data = {
         .mem_size               = <...>,
         .mem_address            = <...>,
         .record_size            = <...>,
         .dump_oops              = <...>,
         .ecc                    = <...>,
 };

 static struct platform_device ramoops_dev = {
         .name = "ramoops",
         .dev = {
                 .platform_data = &ramoops_data,
         },
 };

 [... inside a function ...]
 int ret;

 ret = platform_device_register(&ramoops_dev);
 if (ret) {
 	printk(KERN_ERR "unable to register platform device\n");
 	return ret;
 }

 You can specify either RAM memory or peripheral devices' memory. However, when
 specifying RAM, be sure to reserve the memory by issuing memblock_reserve()
 very early in the architecture code, e.g.:

 #include <linux/memblock.h>

 memblock_reserve(ramoops_data.mem_address, ramoops_data.mem_size);

 3. Dump format

 The data dump begins with a header, currently defined as "====" followed by a
 timestamp and a new line. The dump then continues with the actual data.

 4. Reading the data

 The dump data can be read from the pstore filesystem. The format for these
 files is "dmesg-ramoops-N", where N is the record number in memory. To delete
 a stored record from RAM, simply unlink the respective pstore file.

 5. Persistent function tracing

 Persistent function tracing might be useful for debugging software or hardware
 related hangs. The functions call chain log is stored in a "ftrace-ramoops"
 file. Here is an example of usage:

  # mount -t debugfs debugfs /sys/kernel/debug/
  # echo 1 > /sys/kernel/debug/pstore/record_ftrace
  # reboot -f
  [...]
  # mount -t pstore pstore /mnt/
  # tail /mnt/ftrace-ramoops
  0 ffffffff8101ea64  ffffffff8101bcda  native_apic_mem_read <- disconnect_bsp_APIC+0x6a/0xc0
  0 ffffffff8101ea44  ffffffff8101bcf6  native_apic_mem_write <- disconnect_bsp_APIC+0x86/0xc0
  0 ffffffff81020084  ffffffff8101a4b5  hpet_disable <- native_machine_shutdown+0x75/0x90
  0 ffffffff81005f94  ffffffff8101a4bb  iommu_shutdown_noop <- native_machine_shutdown+0x7b/0x90
  0 ffffffff8101a6a1  ffffffff8101a437  native_machine_emergency_restart <- native_machine_restart+0x37/0x40
  0 ffffffff811f9876  ffffffff8101a73a  acpi_reboot <- native_machine_emergency_restart+0xaa/0x1e0
  0 ffffffff8101a514  ffffffff8101a772  mach_reboot_fixups <- native_machine_emergency_restart+0xe2/0x1e0
  0 ffffffff811d9c54  ffffffff8101a7a0  __const_udelay <- native_machine_emergency_restart+0x110/0x1e0
  0 ffffffff811d9c34  ffffffff811d9c80  __delay <- __const_udelay+0x30/0x40
  0 ffffffff811d9d14  ffffffff811d9c3f  delay_tsc <- __delay+0xf/0x20
	Ramoops oops/panic logger
	=========================

	Sergiu Iordache <[email protected]>

	Updated: 17 November 2011

	0. Introduction

	Ramoops is an oops/panic logger that writes its logs to RAM before the system
	crashes. It works by logging oopses and panics in a circular buffer. Ramoops
	needs a system with persistent RAM so that the content of that area can
	survive after a restart.

	1. Ramoops concepts

	Ramoops uses a predefined memory area to store the dump. The start and size of
	the memory area are set using two variables:
	* "mem_address" for the start
	* "mem_size" for the size. The memory size will be rounded down to a
	power of two.

	The memory area is divided into "record_size" chunks (also rounded down to
	power of two) and each oops/panic writes a "record_size" chunk of
	information.

	Dumping both oopses and panics can be done by setting 1 in the "dump_oops"
	variable while setting 0 in that variable dumps only the panics.

	The module uses a counter to record multiple dumps but the counter gets reset
	on restart (i.e. new dumps after the restart will overwrite old ones).

	Ramoops also supports software ECC protection of persistent memory regions.
	This might be useful when a hardware reset was used to bring the machine back
	to life (i.e. a watchdog triggered). In such cases, RAM may be somewhat
	corrupt, but usually it is restorable.

	2. Setting the parameters

	Setting the ramoops parameters can be done in 2 different manners:
	1. Use the module parameters (which have the names of the variables described
	as before).
	For quick debugging, you can also reserve parts of memory during boot
	and then use the reserved memory for ramoops. For example, assuming a machine
	with > 128 MB of memory, the following kernel command line will tell the
	kernel to use only the first 128 MB of memory, and place ECC-protected ramoops
	region at 128 MB boundary:
	"mem=128M ramoops.mem_address=0x8000000 ramoops.ecc=1"
	2. Use a platform device and set the platform data. The parameters can then
	be set through that platform data. An example of doing that is:

	#include <linux/pstore_ram.h>
	[...]

	static struct ramoops_platform_data ramoops_data = {
	.mem_size = <...>,
	.mem_address = <...>,
	.record_size = <...>,
	.dump_oops = <...>,
	.ecc = <...>,
	};

	static struct platform_device ramoops_dev = {
	.name = "ramoops",
	.dev = {
	.platform_data = &ramoops_data,
	},
	};

	[... inside a function ...]
	int ret;

	ret = platform_device_register(&ramoops_dev);
	if (ret) {
	printk(KERN_ERR "unable to register platform device\n");
	return ret;
	}

	You can specify either RAM memory or peripheral devices' memory. However, when
	specifying RAM, be sure to reserve the memory by issuing memblock_reserve()
	very early in the architecture code, e.g.:

	#include <linux/memblock.h>

	memblock_reserve(ramoops_data.mem_address, ramoops_data.mem_size);

	3. Dump format

	The data dump begins with a header, currently defined as "====" followed by a
	timestamp and a new line. The dump then continues with the actual data.

	4. Reading the data

	The dump data can be read from the pstore filesystem. The format for these
	files is "dmesg-ramoops-N", where N is the record number in memory. To delete
	a stored record from RAM, simply unlink the respective pstore file.

	5. Persistent function tracing

	Persistent function tracing might be useful for debugging software or hardware
	related hangs. The functions call chain log is stored in a "ftrace-ramoops"
	file. Here is an example of usage:

	# mount -t debugfs debugfs /sys/kernel/debug/
	# echo 1 > /sys/kernel/debug/pstore/record_ftrace
	# reboot -f
	[...]
	# mount -t pstore pstore /mnt/
	# tail /mnt/ftrace-ramoops
	0 ffffffff8101ea64 ffffffff8101bcda native_apic_mem_read <- disconnect_bsp_APIC+0x6a/0xc0
	0 ffffffff8101ea44 ffffffff8101bcf6 native_apic_mem_write <- disconnect_bsp_APIC+0x86/0xc0
	0 ffffffff81020084 ffffffff8101a4b5 hpet_disable <- native_machine_shutdown+0x75/0x90
	0 ffffffff81005f94 ffffffff8101a4bb iommu_shutdown_noop <- native_machine_shutdown+0x7b/0x90
	0 ffffffff8101a6a1 ffffffff8101a437 native_machine_emergency_restart <- native_machine_restart+0x37/0x40
	0 ffffffff811f9876 ffffffff8101a73a acpi_reboot <- native_machine_emergency_restart+0xaa/0x1e0
	0 ffffffff8101a514 ffffffff8101a772 mach_reboot_fixups <- native_machine_emergency_restart+0xe2/0x1e0
	0 ffffffff811d9c54 ffffffff8101a7a0 __const_udelay <- native_machine_emergency_restart+0x110/0x1e0
	0 ffffffff811d9c34 ffffffff811d9c80 __delay <- __const_udelay+0x30/0x40
	0 ffffffff811d9d14 ffffffff811d9c3f delay_tsc <- __delay+0xf/0x20