The objective of using Kconfig in RIOT is to configure software modules at compile-time. This means having a standard way of:
Modules in RIOT expose their configurable parameters via Kconfig files (for more information on Kconfig syntax check the specification). In these files documentation, restrictions, default values and dependencies can be expressed.
Kconfig files are structured through the file system mirroring the current module distribution. In time, all modules will have Kconfig files to make themselves configurable through this system.
The user can assign values to the exposed parameters, either by manually writing '.config' files or using an interface such as Menuconfig. Parameters with no assigned values will take the default ones. For a detailed distinction between Kconfig and '.config' files see Appendix B.
Using '.config' and Kconfig files the build system takes care of doing the necessary checks on the values according to the parameter definition. After that, the autoconf.h
header file is generated, it contains all the configurations in the form of (CONFIG_
prefixed) macros.
In order to use the graphical interface menuconfig to configure the application, run make menuconfig
in the application's folder. All available configurations (based on the used modules) for the particular platform will be presented. By default, the configuration of a module via Kconfig is not enabled. In order to activate the configuration via Kconfig the corresponding option should be selected. That will enable the configuration of all inner options, if available.
Once the desired configuration is achieved save the configuration to the default proposed path and exit. The saved configuration will be applied when the code is compiled (make all
).
If the current configuration will be used in the future it can be saved in the application's folder as user.config
, using the 'Save' option in menuconfig. This way it will be persistent after cleaning the application directory (make clean
).
The second way to configure the application is by directly writing '.config' files. Two files will be sources of configuration during the generation of the final header file: app.config
and user.config
, which should be placed inside the application's folder. app.config
sets default configuration values for the particular application, the user can override them by setting them in user.config
. Additionally, further .config
files can be added to the variable KCONFIG_ADD_CONFIG
, which will be applied after default CPU and board configurations, app.config
and user.config
. This means that they will have priority.
Let's say that the SOCK_UTIL_SCHEME_MAXLEN
symbol in sock_util
module needs to be configured. The user.config
file could look like:
In this case, there is no need for using menuconfig. It's enough just to call make all
in the application folder, as this configuration will be read and applied. Note that if any dependency issue occurs, warnings will be generated (e.g. not enabling the configuration of a module via Kconfig).
To expose application-specific configuration options a Kconfig
file can be placed in the application's folder. For an example of this you can check the tests/build_system/kconfig application.
For easy debugging of configuration or testing new modules by compiling them into existing applications, one can also use environment variables prefixed by RIOT_CONFIG_
. To achieve the same configuration exemplified in Configure using '.config' files, e.g., you could also use
All the checks that apply for .config
files also are done with this approach.
Mind that this is only meant to be used during development. In production, please set the configuration via .config
files.
When a certain module is being configured via Kconfig the configuration macro will no longer be overridable by means of CFLAGS (e.g. set on the compilation command or on a Makefile). Consider this if you are getting a 'redefined warning'.
The integration of Kconfig into the build system is mainly done in makefiles/kconfig.mk
.
The resolution of module dependencies is performed by the build system where all the used modules and packages end up listed in the USEMODULE
or USEPKG
make variables.
USEMODULE
and USEPKG
variables.The list of modules needed for the particular build is dumped into the $ (GENERATED_DIR)/Kconfig.dep
file, where each module is translated into a Kconfig symbol as documented in Appendix A.
USEMODULE
and USEPKG
variables$ (GENERATED_DIR)/Kconfig.dep
fileIn this step configuration values are taken from multiple sources and merged into a single out.config
configuration file. This file is temporary and is removed on clean. If the user needs to save a particular configuration set, a backup has to be saved (this can be done using the menuconfig interface) so it can be loaded later in this step.
To accomplish merging of multiple input files, the genconfig
script is used. Note that the order matters: existing configuration values are merged in the order expressed in the input section, where the last value assigned to a parameter has the highest priority. If no configuration files are available all default values will be applied.
out.config
is the only configuration input for the autoconf.h
in the generation step.
Additionally this step generates a file out.config.d
which holds the information of all the used Kconfig files in Makefile format. This file is included by the build system and allows to re-trigger the generation of out.conf
whenever a Kconfig file is modified.
$ (APPDIR)/app.config
: Application specific default configurations.$ (APPDIR)/user.config
: Configurations saved by user.$ (GENERATED_DIR)/out.config
file.Menuconfig is a graphical interface for software configuration. It is used for the configuration of the Linux kernel. This section explains the process that occurs when RIOT is being configured using the menuconfig interface.
The main Kconfig
file is used in this step to show the configurable parameters of the system. Kconfig will filter inapplicable parameters (i.e. parameters exposed by modules that are not being used) based on the file $ (GENERATED_DIR)/Kconfig.dep
generated in step 1.
Note that if Kconfig is not used to configure a module, the corresponding header files default values will be used.
out.config
is one of the inputs for menuconfig. This means that any configuration that the application defines in the app.config
or a backup configuration from the user in user.config
are taken into account on the first run (see Appendix C).
In this step the user chooses configuration values (or selects the minimal configuration) and saves it to the out.config
file. Here the user can choose to save a backup configuration file for later at a different location (e.g. a user.config
file in the application folder).
If any changes occur to out.config
, the generation of autoconf.h is executed automatically.
/Kconfig
file.$ (APPDIR)/app.config
$ (APPDIR)/user.config
$ (GENERATED_DIR)/out.config
$ (GENERATED_DIR)/out.config
file.$ (GENERATED_DIR)/out.config.old
backup file.With the addition of Kconfig a dependency has been added to the build process: the $ (GENERATED_DIR)/autoconf.h
header file. This header file is the main output from the Kconfig configuration system. It holds all the macros that should be used to configure modules in RIOT: CONFIG_<module>_<parameter>
.
In order to generate the autoconf.h
file the genconfig
script is used. Inputs for this script are the main Kconfig
file and out.config
configuration file, which holds the selected values for the exposed parameters.
$ (GENERATED_DIR)/out.config
file.Kconfig
file exposing configuration of modules.$ (GENERATED_DIR)/autoconf.h
configuration header file.$ (GENERATED_DIR)/deps/*/*.h
header files that allow incremental buildsThese files are defined in kconfig.mk
.
File | Description |
---|---|
Kconfig | Defines configuration options of modules. |
Kconfig.dep | Holds a list of the modules that are being compiled. |
app.config | Holds default application configuration values. |
user.config | Holds configuration values applied by the user. |
out.config | Configuration file containing all the symbols defined in autoconf.h . |
out.config.d | Dependency file of out.config containing the list of Kconfig files used to generate it. |
autoconf.h | Header file containing the macros that applied the selected configuration. |
As '.config' files have Makefile syntax they can be included when building, which allows to access the applied configuration from the build system.
During migration this is also useful, as it gives the ability to check if a parameter is being configured via Kconfig or a default value via CFLAGS
could be injected. For example:
Symbols will have the same name as the configuration macros (thus will always have the CONFIG_
prefix). As the configuration file is loaded in Makefile.include
care should be taken when performing checks in the application's Makefile. The symbols will not be defined until after including Makefile.include
.
During transition to the usage of Kconfig as the main configuration tool for RIOT, the default behavior will be the traditional one: expose configuration options in header files and use CFLAGS as inputs. To allow optional configuration via Kconfig, a convention will be used when writing Kconfig files.
Modules should be contained in their own menu
entries, this way the user can choose to enable the configuration via Kconfig for an specific module. These entries should define a dependency on the module they configure (see Appendix A to see how to check if a module is being used).
The module configuration must be enabled either via make dependency modelling.
CPUs and boards are being modelled in Kconfig. The following is a guide on how to organize and name the symbols.
The proposed hierarchy for the classification of CPUs is as follows:
Where each hierarchy is defined as:
CPU_MODEL
: The specific identifier of the used CPU, used for some CPU implementations to differentiate between different memory layouts.CPU_FAM
: An intermediate identifier between CPU and CPU_MODEL that represents a sub-group of a Manufacturers CPU's.CPU_CORE
: The specific identifier of the core present in the CPU.CPU_ARCH
: The specific identifier of the architecture of the core defined in CPU_CORE
.In order to model the hierarchies, a hidden boolean symbol must be declared for each. The name of the symbol must begin with the correspondent prefix and must be followed by the specific value. For instance, the 'samd21' family symbol is named CPU_FAM_SAMD21
.
In addition, a default value to the correspondent common symbol must be defined. The default value must be guarded by the boolean symbol correspondent to the hierarchy.
Features may be provided by any hierarchy symbol. Usually symbols are selected from more specific to less specific. This means that a CPU_MODEL_<model>
symbol usually would select the correspondent CPU_FAM_<family>
symbol, which would in turn select the CPU_CORE_<core>
. This may change in some cases where CPU_COMMON_
symbols are defined to avoid repetition. For convenience and if it makes sense within a CPU vendor family, it's also allowed to use intermediate grouping levels, like CPU_LINE_<xxx>
used for STM32.
In addition to the symbols of the hierarchy described above, a default value to the CPU
symbol should be assigned, which will match the value of the CPU
Makefile variable in the build system.
The declaration of the symbols should be placed in a Kconfig
file in the folder that corresponds to the hierarchy. When the symbols are scattered into multiple files, it is responsibility of file containing the most specific symbols to source
the less specific. Keep in mind that only the file located in /cpu/<CPU>/Kconfig
will be included by the root /Kconfig
file.
Boards must be modelled as hidden boolean symbols with the prefix BOARD_
which default to y
and are placed in /boards/<BOARD>/Kconfig
. This file will be source
d from the main /Kconfig
file. The board symbol must select the CPU_MODEL_<model>
symbol that corresponds to the CPU model present on the board. The board symbol must also select the symbols that correspond to the features it provides.
In the same Kconfig
file a default value must be assigned to the common BOARD
symbol. It must be guarded by the board's symbol, so it only applies in that case.
There are cases when grouping common code for multiple boards helps to avoid unnecessary repetition. In the case features are provided in a common board folder (e.g. /boards/common/arduino-atmega
) a symbol should be declared to model this in Kconfig. Symbols for common boards must have the BOARD_COMMON_
prefix, and must select the common provided features.
The samr21-xpro has a samr21g18a
CPU and provides multiple features. Its symbol is modelled as following:
Boards, common board directories, CPUs and common CPU directories may need to override default configuration values. Visible configuration symbols are configurable by the user and show on the menuconfig interface. .config
files are used to set their values. To allow multiple sources of .config
files, there are two Makefile variables developers should use: KCONFIG_CPU_CONFIG
for sources added by the CPU or common CPU directories, and KCONFIG_BOARD_CONFIG
for sources added by the board or common board directories. This ensures the correct priority of the configurations.
The Makefile.features
infrastructure is used to populate the configuration sources. As the order in which .config
files are merged matters, configuration sources should be ordered from more generic to more specific. Because board's Makefile.features
is included before CPU's Makefile.features
it is important to utilize two different lists of configuration sources. For instance, if cpu/cortexm_common
adds its configuration, cpu/stm32
should add its configuration after it, and boards/stm32f769i-disco
after it.
The following symbol prefixes have been assigned particular semantics and are reserved for the cases described below:
Prefix | Description |
---|---|
BOARD_ | Models a board |
BOARD_COMMON_ | Used for common symbols used by multiple boards |
CPU_ARCH_ | Models a CPU architecture |
CPU_COMMON_ | Used for common symbols used by multiple CPUs |
CPU_CORE_ | Models a CPU core |
CPU_FAM_ | Models a family of CPUs |
CPU_MODEL_ | Models a particular model of CPU |
USEMODULE_ | Models a RIOT module. Generated from USEMODULE variable |
USEPKG_ | Models an external package. Generated from USEPKG variable |
In order to show only the relevant configuration parameters to the user with respect to a given application and board selection, Kconfig needs knowledge about all modules and packages to be used for a compilation. The dependency handling among modules is performed by the build system (via Makefile.dep
files). The interface defined to declared the used modules and packages is the $ (GENERATED_DIR)/Kconfig.dep
file.
There will be a symbol for every used module (i.e. every module in USEMODULE
make variable) and package. The names in the symbols will be uppercase and separated by _
. Based on these symbols configurability is decided.
The following is an example of how to use these symbols in Kconfig files to configure compile-time configurations with USEMODULE
dependencies:
Kconfig files describe a configuration database, which is a collection of configuration options organized in a tree structure. Configuration options may have dependencies (among other attributes), which are used to determine their visibility.
Kconfig files are written in Kconfig language defined in the Linux kernel. Configuration options have attributes such as types, prompts and default values.
On the other hand configuration files contain assignment of values to configuration options and use Makefile syntax. They can also be used to save a set of configuration values as backup.
In other words: Kconfig files describe configuration options and '.config' files assign their values.
In the current configuration flow the user can choose to configure RIOT using the menuconfig graphical interface or writing '.config' files by hand.
As explained in the 'Configuration sources merging step' of the configuration process, configuration from multiple sources are loaded to create a single out.config
file, and the order of merging matters: last file has priority.
While editing values directly via '.config' files out.config
will be re-built. The user can also use menuconfig interface to modify the configuration file (this is the recommended way, as it gives access to much more information regarding dependencies and default values of the symbols). Menuconfig will change out.config
directly (a backup file out.config.old
will be kept).
It is recommended to save backups of the configurations, as any change on the configuration sources would re-trigger the merging process and overwrite out.config
.
A macro that holds a 0 or 1 is modelled in Kconfig as a bool
symbol. References to this macro can then make use of IS_ACTIVE macro from kernel_defines.h with C conditionals for conditional compilation. FXOS8700 driver exposure to Kconfig can be considered as an example. If the macro is defined as TRUE
by default, a new symbol gets introduced to invert the semantics. The recommended practice is to add a new symbol and expose it to Kconfig while the old one is tagged to be deprecated. The process is documented in this commit
There may be cases where a macro is expected to hold only specific values, e.g. 'GNRC_IPV6_MSG_QUEUE_SIZE' expressed as the power of two. These may be modelled in such a way that a new macro is introduced to hold the restricted figures while operators are added to arrive at the desired value. The process is documented in this pull request.