1# Callouts 2 3## Introduction 4 5A callout is typically an indication of a faulty hardware component in a system. 6In OpenBMC, a callout is defined as any other error, via a YAML file. An example 7would be `xyz.openbmc_project.Error.Callout.IIC`, to indicate an IIC callout. 8 9The goal is to have applications post callouts using hardware terminology which 10is familiar to them, such as a sysfs entry, or an IIC address. It would be up to 11the OpenBMC error handling component to map such a callout to actual field 12replaceable units (FRUs) on the system. 13 14## Architecture and usage 15 16An OpenBMC error has associated metadata, the same is true for a callout. Such 17metadata would be defined in the callout YAML interface. Here is an example (for 18xyz.openbmc_project.Error.Callout.IIC) : 19 20```yaml 21- name: IIC 22 meta: 23 - str: "CALLOUT_IIC_BUS=%s" 24 type: string 25 - str: "CALLOUT_IIC_ADDR=%hu" 26 type: uint16 27``` 28 29An application wanting to add an IIC callout will have to provide values for the 30metadata fields above. These fields will also let the error handling component 31figure out that this is in fact an IIC callout. 32 33A callout is typically associated with an error log. For eg, 34`xyz.openbmc_project.Error.Foo` may want to add an IIC callout. This is 35indicated in Foo's YAML interface as follows : 36 37```yaml 38- name: Foo 39 description: this is the error Foo 40 inherits: 41 - xyz.openbmc_project.Error.Callout.IIC 42``` 43 44The way this inheritance will be implemented is that, Foo's metadata will 45include Callout.IIC's as well, so an application wanting to add an IIC callout 46will have to provide values for Foo and IIC metadata. Like mentioned before, due 47to the presence of the Callout.IIC metadata, the error handling component can 48figure out that the error Foo includes an IIC callout. 49 50Currently, defined callout interfaces in turn inherit 51`xyz.openbmc_project.Error.Callout.Device`, which has metadata common to 52callouts : 53 54```yaml 55- name: Device 56 meta: 57 - str: "CALLOUT_ERRNO=%d" 58 type: int32 59 - str: "CALLOUT_DEVICE_PATH=%s" 60 type: string 61``` 62 63This way, say an application wants to express an IIC callout in terms of a 64device path, for lack of IIC information. The application can add the callout 65metadata fields for both Callout.Device and Callout.IIC, but provide values only 66for Callout.Callout. That way the error handling component can still decipher 67this as an IIC callout. 68 69## Creation of a callout 70 71This section talks about creation of a callout, once callout related metadata is 72already in the journal. 73 74Taking an example of a generic device callout here, but this would be the flow 75in general : 76 77- An application commits an error that has associated callout metadata. This 78 will cause the error-log server to create a d-bus object for the error. 79 80- The error-log server will detect that callout metadata is present, will 81 extract the same and hand it over to a sub-module which will map callout 82 metadata to one or more inventory object paths, and will create an association 83 between the error object and the inventory object(s). The mapping from callout 84 metadata to inventory objects is mostly done via the aid of code generated by 85 the system MRW parsers. 86 87- Generated code : consider a case where an application wants to callout an 88 EEPROM on the BMC planar, via a device path, such as 89 /sys/devices/platform/ahb/ahb:apb/1e78a000.i2c/i2c-11/i2c-11/11-0051/eeprom. 90 This would have to be mapped to the BMC planar as the FRU to be called out. 91 MRW parser(s) could be written which, for every device in the IIC subsystem, 92 can provide a corresponding inventory object path. The error-log server, in 93 this case, has to, by looking at the device path, determine that the device is 94 on an IIC bus, and make use of the code generated to map the device to 95 inventory objects. Similar MRW parsers could be written for other device 96 subsystems. 97