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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:
- TB_FW: properties related to trusted firmware such as IO policies,
base address of other DTBs, 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..
Loading the property device tree
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The ``fconf_load_config()`` must be called to load the device 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