This extension will create PELs for every OpenBMC event log. It is also possible to point to the raw PEL to use in the OpenBMC event, and then that will be used instead of creating one.
An error log creator can pass in data that is relevant to a PEL by using certain keywords in the AdditionalData property of the event log.
This keyword is used to point to an existing PEL in a binary file that should be associated with this event log. The syntax is:
RAWPEL=<path to PEL File> e.g. RAWPEL="/tmp/pels/pel.5"
The code will assign its own error log ID to this PEL, and also update the commit timestamp field to the current time.
This keyword's data contains a full PEL in string format. This is how hostboot sends down PELs when it is configured in IPMI communication mode. The PEL is handled just like the PEL obtained using the RAWPEL keyword.
The syntax is:
ESEL= "00 00 df 00 00 00 00 20 00 04 12 01 6f aa 00 00 50 48 00 30 01 00 33 00 00..."
Note that there are 16 bytes of IPMI SEL data before the PEL data starts.
This keyword that contains the application's PID is added automatically by the phosphor-logging daemon when the commit
or report
APIs are used to create an event log, but not when the Create
D-Bus method is used. If a caller of the Create
API wishes to have their PID captured in the PEL this should be used.
This will be added to the PEL in a section of type User Data (UD), along with the application name it corresponds to.
The syntax is:
_PID=<PID of application> e.g. _PID="12345"
This is used to pass in an inventory item to use as a callout. See here for details
This is used to pass in a device path to create callouts from. See here for details
This is used to pass in an I2C bus and address to create callouts from. See here for details
When one needs to add FFDC into the PEL UserData sections, the CreateWithFFDCFiles
D-Bus method on the xyz.openbmc_project.Logging.Create
interface must be used when creating a new event log. This method takes a list of files to store in the PEL UserData sections.
That API is the same as the 'Create' one, except it has a new parameter:
std::vector<std::tuple<enum[FFDCFormat], uint8_t, uint8_t, sdbusplus::message::unix_fd>>
Each entry in the vector contains a file descriptor for a file that will be stored in a unique UserData section. The tuple's arguments are:
An example of saving JSON data to a file and getting its file descriptor is:
nlohmann::json json = ...; auto jsonString = json.dump(); FILE* fp = fopen(filename, "w"); fwrite(jsonString.data(), 1, jsonString.size(), fp); int fd = fileno(fp);
Alternatively, 'open()' can be used to obtain the file descriptor of the file.
Upon receiving this data, the PEL code will create UserData sections for each entry in that vector with the following UserData fields:
If there is a peltool parser registered for the custom type (method is TBD), that will be used by peltool to print the data, otherwise it will be hexdumped.
Before adding each of these UserData sections, a check will be done to see if the PEL size will remain under the maximum size of 16KB. If not, the UserData section will be truncated down enough so that it will fit into the 16KB.
The extension code that creates PELs will add these UserData sections to every PEL:
The AdditionalData property contents
System information
The PEL message registry is used to create PELs from OpenBMC event logs. Documentation can be found here.
A callout points to a FRU, a symbolic FRU, or an isolation procedure. There can be from zero to ten of them in each PEL, where they are located in the SRC section.
There are a few different ways to add callouts to a PEL:
The PEL code can add callouts based on the values of special entries in the AdditionalData event log property. They are:
CALLOUT_INVENTORY_PATH
This keyword is used to call out a single FRU by passing in its D-Bus inventory path. When the PEL code sees this, it will create a single high priority FRU callout, using the VPD properties (location code, FN, CCIN) from that inventory item. If that item is not a FRU itself and does not have a location code, it will keep searching its parents until it finds one that is.
CALLOUT_INVENTORY_PATH= "/xyz/openbmc_project/inventory/system/chassis/motherboard"
CALLOUT_DEVICE_PATH with CALLOUT_ERRNO
These keywords are required as a pair to indicate faulty device communication, usually detected by a failure accessing a device at that sysfs path. The PEL code will use a data table generated by the MRW to map these device paths to FRU callout lists. The errno value may influence the callout.
TBD: Which exact types of device paths are supported.
CALLOUT_DEVICE_PATH="/sys/bus/i2c/devices/3-0069" CALLOUT_ERRNO="2"
CALLOUT_IIC_BUS with CALLOUT_IIC_ADDR and CALLOUT_ERRNO
These 3 keywords can be used to callout a failing I2C device path when the full device path isn't known. It is similar to CALLOUT_DEVICE_PATH in that it will use data tables generated by the MRW to create the callouts.
CALLOUT_IIC_BUS is in the form "/dev/i2c-X" where X is the bus number. CALLOUT_IIC_ADDR is the 7 bit address either as a decimal or a hex number if preceded with a "0x".
CALLOUT_IIC_BUS="/dev/i2c-7" CALLOUT_IIC_ADDR="81" CALLOUT_ERRNO=62
Callouts can be completely defined inside that error's definition in the PEL message registry. This method allows the callouts to vary based on the system type or on any AdditionalData item.
At a high level, this involves defining a callout section inside the registry entry that contain the location codes or procedure names to use, along with their priority. If these can vary based on system type, the type provided by the entity manager will be one of the keys. If they can also depend on an AdditionalData entry, then that will also be a key.
See the message registry README and schema for the details.
If the message registry entry contains a callout definition and the event log also contains one of aforementioned CALLOUT keys in the AdditionalData property, then the PEL code will first add the callouts stemming from the CALLOUT items, followed by the callouts from the message registry.
Some applications, such as the code from the openpower-hw-diags repository, have their own callout tables that contain the callouts to use for the errors they generate.
TODO: The best way to pass these callouts in to the PEL creation code.
Action Flags
and Event Type
RulesThe Action Flags
and Event Type
PEL fields are optional in the message registry, and if not present the code will set them based on certain rules layed out in the PEL spec. In fact, even if they were specified, the checks are still done to ensure consistency across all the logs.
These rules are:
Report
flag, unless the Do Not Report
flag is already on.SP Call Home
flag, as that feature isn't supported.Non-error Event
:Service Action
flag.Call Home
flag.Event Type
field is Not Applicable
, change it to Information Only
.Event Type
field is Information Only
or Tracing
, set the Hidden
flag.Recovered
:Hidden
flag.Service Action
flag.Call Home
flag.Hidden
flag.Service Action
flag.Call Home
flag.Additional rules may be added in the future if necessary.
See the org.open_power.Logging.PEL interface definition for the most up to date information.