docs/components/fconf/index.rst - filogic/atf - Gitiles

 Firmware Configuration Framework
 ================================

 This document provides an overview of the |FCONF| framework.

 Introduction
 ~~~~~~~~~~~~

 The Firmware CONfiguration Framework (|FCONF|) is an abstraction layer for
 platform specific data, allowing a "property" to be queried and a value
 retrieved without the requesting entity knowing what backing store is being used
 to hold the data.

 It is used to bridge new and old ways of providing platform-specific data.
 Today, information like the Chain of Trust is held within several, nested
 platform-defined tables. In the future, it may be provided as part of a device
 blob, along with the rest of the information about images to load.
 Introducing this abstraction layer will make migration easier and will preserve
 functionality for platforms that cannot / don't want to use device tree.

 Accessing properties
 ~~~~~~~~~~~~~~~~~~~~

 Properties defined in the |FCONF| are grouped around namespaces and
 sub-namespaces: a.b.property.
 Examples namespace can be:

 - (|TBBR|) Chain of Trust data: tbbr.cot.trusted_boot_fw_cert
 - (|TBBR|) dynamic configuration info: tbbr.dyn_config.disable_auth
 - Arm io policies: arm.io_policies.bl2_image
 - GICv3 properties: hw_config.gicv3_config.gicr_base

 Properties can be accessed with the ``FCONF_GET_PROPERTY(a,b,property)`` macro.

 Defining properties
 ~~~~~~~~~~~~~~~~~~~

 Properties composing the |FCONF| have to be stored in C structures. If
 properties originate from a different backend source such as a device tree,
 then the platform has to provide a ``populate()`` function which essentially
 captures the property and stores them into a corresponding |FCONF| based C
 structure.

 Such a ``populate()`` function is usually platform specific and is associated
 with a specific backend source. For example, a populator function which
 captures the hardware topology of the platform from the HW_CONFIG device tree.
 Hence each ``populate()`` function must be registered with a specific
 ``config_type`` identifier. It broadly represents a logical grouping of
 configuration properties which is usually a device tree file.

 Example:
  - FW_CONFIG: properties related to base address, maximum size and image id
    of other DTBs etc.
  - TB_FW: properties related to trusted firmware such as IO policies,
    mbedtls heap info etc.
  - HW_CONFIG: properties related to hardware configuration of the SoC
    such as topology, GIC controller, PSCI hooks, CPU ID etc.

 Hence the ``populate()`` callback must be registered to the (|FCONF|) framework
 with the ``FCONF_REGISTER_POPULATOR()`` macro. This ensures that the function
 would be called inside the generic ``fconf_populate()`` function during
 initialization.

 ::

     int fconf_populate_topology(uintptr_t config)
     {
         /* read hw config dtb and fill soc_topology struct */
     }

     FCONF_REGISTER_POPULATOR(HW_CONFIG, topology, fconf_populate_topology);

 Then, a wrapper has to be provided to match the ``FCONF_GET_PROPERTY()`` macro:

 ::

     /* generic getter */
     #define FCONF_GET_PROPERTY(a,b,property)	a##__##b##_getter(property)

     /* my specific getter */
     #define hw_config__topology_getter(prop) soc_topology.prop

 This second level wrapper can be used to remap the ``FCONF_GET_PROPERTY()`` to
 anything appropriate: structure, array, function, etc..

 To ensure a good interpretation of the properties, this documentation must
 explain how the properties are described for a specific backend. Refer to the
 :ref:`binding-document` section for more information and example.

 Loading the property device tree
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

 The ``fconf_load_config(image_id)`` must be called to load fw_config and
 tb_fw_config devices tree containing the properties' values. This must be done
 after the io layer is initialized, as the |DTB| is stored on an external
 device (FIP).

 .. uml:: ../../resources/diagrams/plantuml/fconf_bl1_load_config.puml

 Populating the properties
 ~~~~~~~~~~~~~~~~~~~~~~~~~

 Once a valid device tree is available, the ``fconf_populate(config)`` function
 can be used to fill the C data structure with the data from the config |DTB|.
 This function will call all the ``populate()`` callbacks which have been
 registered with ``FCONF_REGISTER_POPULATOR()`` as described above.

 .. uml:: ../../resources/diagrams/plantuml/fconf_bl2_populate.puml

 Namespace guidance
 ~~~~~~~~~~~~~~~~~~

 As mentioned above, properties are logically grouped around namespaces and
 sub-namespaces. The following concepts should be considered when adding new
 properties/namespaces.
 The framework differentiates two types of properties:

  - Properties used inside common code.
  - Properties used inside platform specific code.

 The first category applies to properties being part of the firmware and shared
 across multiple platforms. They should be globally accessible and defined
 inside the ``lib/fconf`` directory. The namespace must be chosen to reflect the
 feature/data abstracted.

 Example:
  - |TBBR| related properties: tbbr.cot.bl2_id
  - Dynamic configuration information: dyn_cfg.dtb_info.hw_config_id

 The second category should represent the majority of the properties defined
 within the framework: Platform specific properties. They must be accessed only
 within the platform API and are defined only inside the platform scope. The
 namespace must contain the platform name under which the properties defined
 belong.

 Example:
  - Arm io framework: arm.io_policies.bl31_id

 .. _binding-document:

 Properties binding information
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

 .. toctree::
   :maxdepth: 1

   fconf_properties
   amu-bindings
   mpmm-bindings
	Firmware Configuration Framework
	================================

	This document provides an overview of the \|FCONF\| framework.

	Introduction
	~~~~~~~~~~~~

	The Firmware CONfiguration Framework (\|FCONF\|) is an abstraction layer for
	platform specific data, allowing a "property" to be queried and a value
	retrieved without the requesting entity knowing what backing store is being used
	to hold the data.

	It is used to bridge new and old ways of providing platform-specific data.
	Today, information like the Chain of Trust is held within several, nested
	platform-defined tables. In the future, it may be provided as part of a device
	blob, along with the rest of the information about images to load.
	Introducing this abstraction layer will make migration easier and will preserve
	functionality for platforms that cannot / don't want to use device tree.

	Accessing properties
	~~~~~~~~~~~~~~~~~~~~

	Properties defined in the \|FCONF\| are grouped around namespaces and
	sub-namespaces: a.b.property.
	Examples namespace can be:

	- (\|TBBR\|) Chain of Trust data: tbbr.cot.trusted_boot_fw_cert
	- (\|TBBR\|) dynamic configuration info: tbbr.dyn_config.disable_auth
	- Arm io policies: arm.io_policies.bl2_image
	- GICv3 properties: hw_config.gicv3_config.gicr_base

	Properties can be accessed with the ``FCONF_GET_PROPERTY(a,b,property)`` macro.

	Defining properties
	~~~~~~~~~~~~~~~~~~~

	Properties composing the \|FCONF\| have to be stored in C structures. If
	properties originate from a different backend source such as a device tree,
	then the platform has to provide a ``populate()`` function which essentially
	captures the property and stores them into a corresponding \|FCONF\| based C
	structure.

	Such a ``populate()`` function is usually platform specific and is associated
	with a specific backend source. For example, a populator function which
	captures the hardware topology of the platform from the HW_CONFIG device tree.
	Hence each ``populate()`` function must be registered with a specific
	``config_type`` identifier. It broadly represents a logical grouping of
	configuration properties which is usually a device tree file.

	Example:
	- FW_CONFIG: properties related to base address, maximum size and image id
	of other DTBs etc.
	- TB_FW: properties related to trusted firmware such as IO policies,
	mbedtls heap info etc.
	- HW_CONFIG: properties related to hardware configuration of the SoC
	such as topology, GIC controller, PSCI hooks, CPU ID etc.

	Hence the ``populate()`` callback must be registered to the (\|FCONF\|) framework
	with the ``FCONF_REGISTER_POPULATOR()`` macro. This ensures that the function
	would be called inside the generic ``fconf_populate()`` function during
	initialization.

	::

	int fconf_populate_topology(uintptr_t config)
	{
	/* read hw config dtb and fill soc_topology struct */
	}

	FCONF_REGISTER_POPULATOR(HW_CONFIG, topology, fconf_populate_topology);

	Then, a wrapper has to be provided to match the ``FCONF_GET_PROPERTY()`` macro:

	::

	/* generic getter */
	#define FCONF_GET_PROPERTY(a,b,property) a##__##b##_getter(property)

	/* my specific getter */
	#define hw_config__topology_getter(prop) soc_topology.prop

	This second level wrapper can be used to remap the ``FCONF_GET_PROPERTY()`` to
	anything appropriate: structure, array, function, etc..

	To ensure a good interpretation of the properties, this documentation must
	explain how the properties are described for a specific backend. Refer to the
	:ref:`binding-document` section for more information and example.

	Loading the property device tree
	~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

	The ``fconf_load_config(image_id)`` must be called to load fw_config and
	tb_fw_config devices tree containing the properties' values. This must be done
	after the io layer is initialized, as the \|DTB\| is stored on an external
	device (FIP).

	.. uml:: ../../resources/diagrams/plantuml/fconf_bl1_load_config.puml

	Populating the properties
	~~~~~~~~~~~~~~~~~~~~~~~~~

	Once a valid device tree is available, the ``fconf_populate(config)`` function
	can be used to fill the C data structure with the data from the config \|DTB\|.
	This function will call all the ``populate()`` callbacks which have been
	registered with ``FCONF_REGISTER_POPULATOR()`` as described above.

	.. uml:: ../../resources/diagrams/plantuml/fconf_bl2_populate.puml

	Namespace guidance
	~~~~~~~~~~~~~~~~~~

	As mentioned above, properties are logically grouped around namespaces and
	sub-namespaces. The following concepts should be considered when adding new
	properties/namespaces.
	The framework differentiates two types of properties:

	- Properties used inside common code.
	- Properties used inside platform specific code.

	The first category applies to properties being part of the firmware and shared
	across multiple platforms. They should be globally accessible and defined
	inside the ``lib/fconf`` directory. The namespace must be chosen to reflect the
	feature/data abstracted.

	Example:
	- \|TBBR\| related properties: tbbr.cot.bl2_id
	- Dynamic configuration information: dyn_cfg.dtb_info.hw_config_id

	The second category should represent the majority of the properties defined
	within the framework: Platform specific properties. They must be accessed only
	within the platform API and are defined only inside the platform scope. The
	namespace must contain the platform name under which the properties defined
	belong.

	Example:
	- Arm io framework: arm.io_policies.bl31_id

	.. _binding-document:

	Properties binding information
	~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

	.. toctree::
	:maxdepth: 1

	fconf_properties
	amu-bindings
	mpmm-bindings