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gerrit.openbmc.org / openbmc / entity-manager / 04b0b013e5020f43258e05116ddd49f80cbfecfc
commit04b0b013e5020f43258e05116ddd49f80cbfecfc[log] [tgz]
authorChris Cain <cjcain@us.ibm.com>Tue Dec 14 16:19:05 2021 -0600
committerChris Cain <cjcain@us.ibm.com>Wed Jun 07 14:25:23 2023 -0500
tree30eb971bcffca115568cead7c9ff6f521b7ae51b
parentffe7df4301d1658fafab0e3838bf7e218fdb8f83 [diff]
schema: ibm: add default power mode props. schema

Add PowerModeProperties schema to define the factory default power mode
properties of a system:
- Power Mode
- Idle Power Saver Parameters

All of these parameters are part of the version 2021.2 Redfish Schema
Supplement under the ComputerSystem 1.16.0 schema:
For details on the values and descriptions, see the PowerMode and
IdlePowerSaver schemas in the Redfish documentation:
https://www.dmtf.org/sites/default/files/standards/documents/DSP0268_2021.2.pdf

These are the factory default values as defined by the system architect.
All of these parameters are system-wide parameters and are used to
define the operation of that system as it relates to power.

These are the values will be used the first time a system is powered on.
They can also be used if the customer wants to restore these settings to
their factory defaults.

Signed-off-by: Chris Cain <cjcain@us.ibm.com>
Change-Id: Ie2f3ca74db0c898c6a4f3beed29eda674dfcf5c6
6 files changed
tree: 30eb971bcffca115568cead7c9ff6f521b7ae51b
  1. configurations/
  2. docs/
  3. schemas/
  4. scripts/
  5. service_files/
  6. src/
  7. subprojects/
  8. test/
  9. .clang-format
  10. .clang-tidy
  11. .gitignore
  12. .markdownlint.yaml
  13. .prettierignore
  14. .prettierrc.yaml
  15. .shellcheck
  16. blacklist.json
  17. CONFIG_FORMAT.md
  18. Doxyfile
  19. format-code
  20. LICENCE
  21. meson.build
  22. meson_options.txt
  23. OWNERS
  24. README.md
README.md

Entity Manager

Entity manager is a design for managing physical system components, and mapping them to software resources within the BMC. Said resources are designed to allow the flexible adjustment of the system at runtime, as well as the reduction in the number of independent system configurations one needs to create.

Definitions

Entity

A server component that is physically separate, detectable through some means, and can be added or removed from a given OpenBMC system. Said component can, and likely does contain multiple sub-components, but the component itself as a whole is referred to as an entity.

Note, this term is needed because most other terms that could've been used (Component, Field Replaceable Unit, or Assembly) are already overloaded in the industry, and have a distinct definition already, which is a subset of what an entity encompasses.

Exposes

A particular feature of an Entity. An Entity generally will have multiple Exposes records for the various features that component supports. Some examples of features include, LM75 sensors, PID control parameters, or CPU information.

Probe

A set of rules for detecting a given entity. Said rules generally take the form of a D-Bus interface definition.

Goals

Entity manager has the following goals (unless you can think of better ones):

  1. Minimize the time and debugging required to "port" OpenBMC to new systems
  2. Reduce the amount of code that is different between platforms
  3. Create system level maintainability in the long term, across hundreds of platforms and components, such that components interoperate as much as physically possible.

Implementation

A full BMC setup using Entity Manager consists of a few parts:

  1. A detection daemon This is something that can be used to detect components at runtime. The most common of these, fru-device, is included in the Entity-Manager repo, and scans all available I2C buses for IPMI FRU EEPROM devices. Other examples of detection daemons include: peci-pcie: A daemon that utilizes the CPU bus to read in a list of PCIe devices from the processor. smbios-mdr: A daemon that utilizes the x86 SMBIOS table specification to detect the available systems dependencies from BIOS.

    In many cases, the existing detection daemons are sufficient for a single system, but in cases where there is a superseding inventory control system in place (such as in a large datacenter) they can be replaced with application specific daemons that speak the protocol information of their controller, and expose the inventory information, such that failing devices can be detected more readily, and system configurations can be "verified" rather than detected.

  2. An entity manager configuration file Entity manager configuration files are located in the ./configurations directory in the entity manager repository, and include one file per device supported. Entities are detected based on the "Probe" key in the json file. The intention is that this folder contains all hardware configurations that OpenBMC supports, to allows an easy answer to "Is X device supported". An EM configuration contains a number of Exposes records that specify the specific features that this Entity supports. Once a component is detected, entity manager will publish these Exposes records to D-Bus.

  3. A reactor The reactors are things that take the entity manager configurations, and use them to execute and enable the features that they describe. One example of this is dbus-sensors, which contains a suite of applications that input the Exposes records for sensor devices, then connect to the filesystem to create the sensors and scan loops to scan sensors for those devices. Other examples of reactors could include: CPU management daemons and Hot swap backplane management daemons, or drive daemons.

note: In some cases, a given daemon could be both a detection daemon and a reactor when architectures are multi-tiered. An example of this might include a hot swap backplane daemon, which both reacts to the hot swap being detected, and also creates detection records of what drives are present.

Requirements

  1. Entity manager shall support the dynamic discovery of hardware at runtime, using inventory interfaces. The types of devices include, but are not limited to hard drives, hot swap backplanes, baseboards, power supplies, CPUs, and PCIe Add-in-cards.

  2. Entity manager shall support the ability to add or remove support for particular devices in a given binary image. By default, entity manager will support all available and known working devices for all platforms.

  3. Entity manager shall provide data to D-Bus about a particular device such that other daemons can create instances of the features being exposed.

  4. Entity manager shall support multiple detection runs, and shall do the minimal number of changes necessary when new components are detected or no longer detected. Some examples of re-detection events might include host power on, drive plug/unplug, PSU plug/unplug.

  5. Entity manager shall have exactly one configuration file per supported device model. In some cases this will cause duplicated information between files, but the ability to list and see all supported device models in a single place, as well as maintenance when devices do differ in the future is determined to be more important than duplication of configuration files.

Explicitly out of scope

  1. Entity manager shall not directly participate in the detection of devices, and instead will rely on other D-Bus applications to publish interfaces that can be detected.
  2. Entity manager shall not directly participate in management of any specific device. This is requirement is intended to intentionally limit the size and feature set of entity manager, to ensure it remains small, and effective to all users.

Entity Manager Compatible Software

bmcweb A webserver implementation that uses the inventory information from entity-manager to produce a Redfish compliant REST API. intel-ipmi-oem An implementation of the IPMI SDR, FRU, and Storage commands that utilize Entity Manager as the source of information.

Additional Documentation

  1. Entity Manager DBus API
  2. My First Sensor Example
  3. Configuration File Schema