doc/guides/build/index.rst - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 .. _build_overview:

 Build and Configuration Systems
 ###############################


 .. _cmake-details:

 Build System (CMake)
 ********************


 CMake is used to build your application together with the Zephyr kernel. A
 CMake build is done in two stages. The first stage is called
 **configuration**. During configuration, the CMakeLists.txt build scripts are
 executed. After configuration is finished, CMake has an internal model of the
 Zephyr build, and can generate build scripts that are native to the host
 platform.

 CMake supports generating scripts for several build systems, but only Ninja and
 Make are tested and supported by Zephyr. After configuration, you begin the
 **build** stage by executing the generated build scripts. These build scripts
 can recompile the application without involving CMake following
 most code changes. However, after certain changes, the configuration step must
 be executed again before building. The build scripts can detect some of these
 situations and reconfigure automatically, but there are cases when this must be
 done manually.

 Zephyr uses CMake's concept of a 'target' to organize the build. A
 target can be an executable, a library, or a generated file. For
 application developers, the library target is the most important to
 understand. All source code that goes into a Zephyr build does so by
 being included in a library target, even application code.

 Library targets have source code, that is added through CMakeLists.txt
 build scripts like this:

 .. code-block:: cmake

    target_sources(app PRIVATE src/main.c)

 In the above :file:`CMakeLists.txt`, an existing library target named ``app``
 is configured to include the source file :file:`src/main.c`. The ``PRIVATE``
 keyword indicates that we are modifying the internals of how the library is
 being built. Using the keyword ``PUBLIC`` would modify how other
 libraries that link with app are built. In this case, using ``PUBLIC``
 would cause libraries that link with ``app`` to also include the
 source file :file:`src/main.c`, behavior that we surely do not want. The
 ``PUBLIC`` keyword could however be useful when modifying the include
 paths of a target library.


 Build and Configuration Phases
 ==============================

 The Zephyr build process can be divided into two main phases: a configuration
 phase (driven by CMake) and a build phase (driven by Make or Ninja).

 .. _build_configuration_phase:

 Configuration Phase
 -------------------

 The configuration phase begins when the user invokes *CMake* to generate a
 build system, specifying a source application directory and a board target.

 .. figure:: build-config-phase.svg
     :align: center
     :alt: Zephyr's build configuration phase
     :figclass: align-center
     :width: 80%

 CMake begins by processing the :file:`CMakeLists.txt` file in the application
 directory, which refers to the :file:`CMakeLists.txt` file in the Zephyr
 top-level directory, which in turn refers to :file:`CMakeLists.txt` files
 throughout the build tree (directly and indirectly). Its primary output is a
 set of Makefiles or Ninja files to drive the build process, but the CMake
 scripts also do some processing of their own, which is explained here.

 Note that paths beginning with :file:`build/` below refer to the build
 directory you create when running CMake.

 Devicetree
    :file:`*.dts` (*devicetree source*) and :file:`*.dtsi` (*devicetree source
    include*) files are collected from the target's architecture, SoC, board,
    and application directories.

    :file:`*.dtsi` files are included by :file:`*.dts` files via the C
    preprocessor (often abbreviated *cpp*, which should not be confused with
    C++). The C preprocessor is also used to merge in any devicetree
    :file:`*.overlay` files, and to expand macros in :file:`*.dts`,
    :file:`*.dtsi`, and :file:`*.overlay` files. The preprocessor output is
    placed in :file:`build/zephyr/zephyr.dts.pre`.

    The preprocessed devicetree sources are parsed by
    :zephyr_file:`gen_defines.py <scripts/dts/gen_defines.py>` to generate a
    :file:`build/zephyr/include/generated/devicetree_unfixed.h` header with
    preprocessor macros.

    Source code should access preprocessor macros generated from devicetree by
    including the :zephyr_file:`devicetree.h <include/devicetree.h>` header,
    which includes :file:`devicetree_unfixed.h`.

    :file:`gen_defines.py` also writes the final devicetree to
    :file:`build/zephyr/zephyr.dts` in the build directory. This file's contents
    may be useful for debugging.

    If the devicetree compiler ``dtc`` is installed, it is run on
    :file:`build/zephyr/zephyr.dts` to catch any extra warnings and errors
    generated by this tool. The output from ``dtc`` is unused otherwise, and
    this step is skipped if ``dtc`` is not installed.

    The above is just a brief overview. For more information on devicetree, see
    :ref:`dt-guide`.

 Devicetree fixups
    Files named :file:`dts_fixup.h` from the target’s architecture, SoC, board,
    and application directories are concatenated into a single
    :file:`devicetree_fixups.h` file. :file:`dts_fixup.h` files are a legacy
    feature which should not be used in new code.

 Kconfig
    :file:`Kconfig` files define available configuration options for for the
    target architecture, SoC, board, and application, as well as dependencies
    between options.

    Kconfig configurations are stored in *configuration files*. The initial
    configuration is generated by merging configuration fragments from the board
    and application (e.g. :file:`prj.conf`).

    The output from Kconfig is an :file:`autoconf.h` header with preprocessor
    assignments, and a :file:`.config` file that acts both as a saved
    configuration and as configuration output (used by CMake). The definitions in
    :file:`autoconf.h` are automatically exposed at compile time, so there is no
    need to include this header.

    Information from devicetree is available to Kconfig, through the functions
    defined in :zephyr_file:`kconfigfunctions.py
    <scripts/kconfig/kconfigfunctions.py>`.

    See :ref:`the Kconfig section of the manual <kconfig>` for more information.

 Build Phase
 -----------

 The build phase begins when the user invokes ``make`` or ``ninja``. Its
 ultimate output is a complete Zephyr application in a format suitable for
 loading/flashing on the desired target board (:file:`zephyr.elf`,
 :file:`zephyr.hex`, etc.) The build phase can be broken down, conceptually,
 into four stages: the pre-build, first-pass binary, final binary, and
 post-processing.

 Pre-build
 +++++++++

 Pre-build occurs before any source files are compiled, because during
 this phase header files used by the source files are generated.

 Offset generation
    Access to high-level data structures and members is sometimes
    required when the definitions of those structures is not
    immediately accessible (e.g., assembly language). The generation of
    *offsets.h* (by *gen_offset_header.py*) facilitates this.

 System call boilerplate
    The *gen_syscall.py* and *parse_syscalls.py*  scripts work
    together to bind potential system call functions with their
    implementations.

 .. figure:: build-build-phase-1.svg
     :align: center
     :alt: Zephyr's build stage I
     :figclass: align-center
     :width: 80%

 Intermediate binaries
 +++++++++++++++++++++

 Compilation proper begins with the first intermediate binary. Source files (C
 and assembly) are collected from various subsystems (which ones is
 decided during the configuration phase), and compiled into archives
 (with reference to header files in the tree, as well as those
 generated during the configuration phase and the pre-build stage(s)).

 .. figure:: build-build-phase-2.svg
     :align: center
     :alt: Zephyr's build stage II
     :figclass: align-center
     :width: 80%

 The exact number of intermediate binaries is decided during the configuration
 phase.

 If memory protection is enabled, then:

 Partition grouping
    The *gen_app_partitions.py* script scans all the
    generated archives and outputs linker scripts to ensure that
    application partitions are properly grouped and aligned for the
    target’s memory protection hardware.

 Then *cpp* is used to combine linker script fragments from the target’s
 architecture/SoC, the kernel tree, optionally the partition output if
 memory protection is enabled, and any other fragments selected during
 the configuration process, into a *linker.cmd* file. The compiled
 archives are then linked with *ld* as specified in the
 *linker.cmd*.

 Unfixed size binary
    The unfixed size intermediate binary is produced when :ref:`usermode_api`
    is enabled or :ref:`devicetree` is in use.
    It produces a binary where sizes are not fixed and thus it may be used
    by post-process steps that will impact the size of the final binary.

 .. figure:: build-build-phase-3.svg
     :align: center
     :alt: Zephyr's build stage III
     :figclass: align-center
     :width: 80%

 Fixed size binary
    The fixed size intermediate binary is produced when :ref:`usermode_api`
    is enabled or when generated IRQ tables are used,
    :kconfig:option:`CONFIG_GEN_ISR_TABLES`
    It produces a binary where sizes are fixed and thus the size must not change
    between the intermediate binary and the final binary.

 .. figure:: build-build-phase-4.svg
     :align: center
     :alt: Zephyr's build stage IV
     :figclass: align-center
     :width: 80%

 Intermediate binaries post-processing
 +++++++++++++++++++++++++++++++++++++

 The binaries from the previous stage are incomplete, with empty and/or
 placeholder sections that must be filled in by, essentially, reflection.

 To complete the build procedure the following scripts are executed on the
 intermediate binaries to produce the missing pieces needed for the final
 binary.

 When :ref:`usermode_api` is enabled:

 Partition alignment
    The *gen_app_partitions.py* script scans the unfixed size binary and
    generates an app shared memory aligned linker script snippet where the
    partitions are sorted in descending order.

 .. figure:: build-postprocess-1.svg
     :align: center
     :alt: Zephyr's intermediate binary post-process I
     :figclass: align-center
     :width: 80%

 When :ref:`devicetree` is used:

 Device dependencies
    The *gen_handles.py* script scans the unfixed size binary to determine
    relationships between devices that were recorded from devicetree data,
    and replaces the encoded relationships with values that are optimized to
    locate the devices actually present in the application.

 .. figure:: build-postprocess-2.svg
     :align: center
     :alt: Zephyr's intermediate binary post-process II
     :figclass: align-center
     :width: 80%

 When :kconfig:option:`CONFIG_GEN_ISR_TABLES` is enabled:
    The *gen_isr_tables.py* script scant the fixed size binary and creates
    an isr_tables.c source file with a hardware vector table and/or software
    IRQ table.

 .. figure:: build-postprocess-3.svg
     :align: center
     :alt: Zephyr's intermediate binary post-process III
     :figclass: align-center
     :width: 80%

 When :ref:`usermode_api` is enabled:

 Kernel object hashing
    The *gen_kobject_list.py* scans the *ELF DWARF*
    debug data to find the address of the all kernel objects. This
    list is passed to *gperf*, which generates a perfect hash function and
    table of those addresses, then that output is optimized by
    *process_gperf.py*, using known properties of our special case.

 .. figure:: build-postprocess-4.svg
     :align: center
     :alt: Zephyr's intermediate binary post-process IV
     :figclass: align-center
     :width: 80%

 When no intermediate binary post-processing is required then the first
 intermediate binary will be directly used as the final binary.

 Final binary
 ++++++++++++

 The binary from the previous stage is incomplete, with empty and/or
 placeholder sections that must be filled in by, essentially, reflection.

 The link from the previous stage is repeated, this time with the missing
 pieces populated.

 .. figure:: build-build-phase-5.svg
     :align: center
     :alt: Zephyr's build final stage
     :figclass: align-center
     :width: 80%

 Post processing
 +++++++++++++++

 Finally, if necessary, the completed kernel is converted from *ELF* to
 the format expected by the loader and/or flash tool required by the
 target. This is accomplished in a straightforward manner with *objdump*.

 .. figure:: build-build-phase-6.svg
     :align: center
     :alt: Zephyr's build final stage post-process
     :figclass: align-center
     :width: 80%


 .. _build_system_scripts:

 Supporting Scripts and Tools
 ============================

 The following is a detailed description of the scripts used during the build process.

 .. _gen_syscalls.py:

 :zephyr_file:`scripts/gen_syscalls.py`
 --------------------------------------

 .. include:: ../../../scripts/gen_syscalls.py
    :start-after: """
    :end-before: """

 .. _gen_handles.py:

 :zephyr_file:`scripts/gen_handles.py`
 --------------------------------------

 .. include:: ../../../scripts/gen_handles.py
    :start-after: """
    :end-before: """

 .. _gen_kobject_list.py:

 :zephyr_file:`scripts/gen_kobject_list.py`
 ------------------------------------------

 .. include:: ../../../scripts/gen_kobject_list.py
    :start-after: """
    :end-before: """

 .. _gen_offset_header.py:

 :zephyr_file:`scripts/gen_offset_header.py`
 -------------------------------------------

 .. include:: ../../../scripts/gen_offset_header.py
    :start-after: """
    :end-before: """

 .. _parse_syscalls.py:

 :zephyr_file:`scripts/parse_syscalls.py`
 ----------------------------------------


 .. include:: ../../../scripts/parse_syscalls.py
    :start-after: """
    :end-before: """

 .. _gen_idt.py:

 :zephyr_file:`arch/x86/gen_idt.py`
 ----------------------------------

 .. include:: ../../../arch/x86/gen_idt.py
    :start-after: """
    :end-before: """

 .. _gen_gdt.py:

 :zephyr_file:`arch/x86/gen_gdt.py`
 ----------------------------------

 .. include:: ../../../arch/x86/gen_gdt.py
    :start-after: """
    :end-before: """

 .. _gen_relocate_app.py:

 :zephyr_file:`scripts/gen_relocate_app.py`
 -------------------------------------------

 .. include:: ../../../scripts/gen_relocate_app.py
    :start-after: """
    :end-before: """

 .. _process_gperf.py:

 :zephyr_file:`scripts/process_gperf.py`
 ---------------------------------------

 .. include:: ../../../scripts/process_gperf.py
    :start-after: """
    :end-before: """

 :zephyr_file:`scripts/gen_app_partitions.py`
 --------------------------------------------

 .. include:: ../../../scripts/gen_app_partitions.py
    :start-after: """
    :end-before: """

 .. _kconfig:

 Configuration System (Kconfig)
 *******************************

 The Zephyr kernel and subsystems can be configured at build time to adapt them
 for specific application and platform needs. Configuration is handled through
 Kconfig, which is the same configuration system used by the Linux kernel. The
 goal is to support configuration without having to change any source code.

 Configuration options (often called *symbols*) are defined in :file:`Kconfig`
 files, which also specify dependencies between symbols that determine what
 configurations are valid. Symbols can be grouped into menus and sub-menus to
 keep the interactive configuration interfaces organized.

 The output from Kconfig is a header file :file:`autoconf.h` with macros that
 can be tested at build time. Code for unused features can be compiled out to
 save space.

 The following sections explain how to set Kconfig configuration options, go
 into detail on how Kconfig is used within the Zephyr project, and have some
 tips and best practices for writing :file:`Kconfig` files.

 .. toctree::
    :maxdepth: 1

    kconfig/menuconfig.rst
    kconfig/setting.rst
    kconfig/tips.rst
    kconfig/preprocessor-functions.rst
    kconfig/extensions.rst

 Users interested in optimizing their configuration for security should refer
 to the Zephyr Security Guide's section on the :ref:`hardening`.
	.. _build_overview:

	Build and Configuration Systems
	###############################


	.. _cmake-details:

	Build System (CMake)
	********************


	CMake is used to build your application together with the Zephyr kernel. A
	CMake build is done in two stages. The first stage is called
	configuration. During configuration, the CMakeLists.txt build scripts are
	executed. After configuration is finished, CMake has an internal model of the
	Zephyr build, and can generate build scripts that are native to the host
	platform.

	CMake supports generating scripts for several build systems, but only Ninja and
	Make are tested and supported by Zephyr. After configuration, you begin the
	build stage by executing the generated build scripts. These build scripts
	can recompile the application without involving CMake following
	most code changes. However, after certain changes, the configuration step must
	be executed again before building. The build scripts can detect some of these
	situations and reconfigure automatically, but there are cases when this must be
	done manually.

	Zephyr uses CMake's concept of a 'target' to organize the build. A
	target can be an executable, a library, or a generated file. For
	application developers, the library target is the most important to
	understand. All source code that goes into a Zephyr build does so by
	being included in a library target, even application code.

	Library targets have source code, that is added through CMakeLists.txt
	build scripts like this:

	.. code-block:: cmake

	target_sources(app PRIVATE src/main.c)

	In the above :file:`CMakeLists.txt`, an existing library target named ``app``
	is configured to include the source file :file:`src/main.c`. The ``PRIVATE``
	keyword indicates that we are modifying the internals of how the library is
	being built. Using the keyword ``PUBLIC`` would modify how other
	libraries that link with app are built. In this case, using ``PUBLIC``
	would cause libraries that link with ``app`` to also include the
	source file :file:`src/main.c`, behavior that we surely do not want. The
	``PUBLIC`` keyword could however be useful when modifying the include
	paths of a target library.


	Build and Configuration Phases
	==============================

	The Zephyr build process can be divided into two main phases: a configuration
	phase (driven by CMake) and a build phase (driven by Make or Ninja).

	.. _build_configuration_phase:

	Configuration Phase
	-------------------

	The configuration phase begins when the user invokes CMake to generate a
	build system, specifying a source application directory and a board target.

	.. figure:: build-config-phase.svg
	:align: center
	:alt: Zephyr's build configuration phase
	:figclass: align-center
	:width: 80%

	CMake begins by processing the :file:`CMakeLists.txt` file in the application
	directory, which refers to the :file:`CMakeLists.txt` file in the Zephyr
	top-level directory, which in turn refers to :file:`CMakeLists.txt` files
	throughout the build tree (directly and indirectly). Its primary output is a
	set of Makefiles or Ninja files to drive the build process, but the CMake
	scripts also do some processing of their own, which is explained here.

	Note that paths beginning with :file:`build/` below refer to the build
	directory you create when running CMake.

	Devicetree
	:file:`.dts` (devicetree source) and :file:`.dtsi` (*devicetree source
	include*) files are collected from the target's architecture, SoC, board,
	and application directories.

	:file:`.dtsi` files are included by :file:`.dts` files via the C
	preprocessor (often abbreviated cpp, which should not be confused with
	C++). The C preprocessor is also used to merge in any devicetree
	:file:`.overlay` files, and to expand macros in :file:`.dts`,
	:file:`.dtsi`, and :file:`.overlay` files. The preprocessor output is
	placed in :file:`build/zephyr/zephyr.dts.pre`.

	The preprocessed devicetree sources are parsed by
	:zephyr_file:`gen_defines.py <scripts/dts/gen_defines.py>` to generate a
	:file:`build/zephyr/include/generated/devicetree_unfixed.h` header with
	preprocessor macros.

	Source code should access preprocessor macros generated from devicetree by
	including the :zephyr_file:`devicetree.h <include/devicetree.h>` header,
	which includes :file:`devicetree_unfixed.h`.

	:file:`gen_defines.py` also writes the final devicetree to
	:file:`build/zephyr/zephyr.dts` in the build directory. This file's contents
	may be useful for debugging.

	If the devicetree compiler ``dtc`` is installed, it is run on
	:file:`build/zephyr/zephyr.dts` to catch any extra warnings and errors
	generated by this tool. The output from ``dtc`` is unused otherwise, and
	this step is skipped if ``dtc`` is not installed.

	The above is just a brief overview. For more information on devicetree, see
	:ref:`dt-guide`.

	Devicetree fixups
	Files named :file:`dts_fixup.h` from the target’s architecture, SoC, board,
	and application directories are concatenated into a single
	:file:`devicetree_fixups.h` file. :file:`dts_fixup.h` files are a legacy
	feature which should not be used in new code.

	Kconfig
	:file:`Kconfig` files define available configuration options for for the
	target architecture, SoC, board, and application, as well as dependencies
	between options.

	Kconfig configurations are stored in configuration files. The initial
	configuration is generated by merging configuration fragments from the board
	and application (e.g. :file:`prj.conf`).

	The output from Kconfig is an :file:`autoconf.h` header with preprocessor
	assignments, and a :file:`.config` file that acts both as a saved
	configuration and as configuration output (used by CMake). The definitions in
	:file:`autoconf.h` are automatically exposed at compile time, so there is no
	need to include this header.

	Information from devicetree is available to Kconfig, through the functions
	defined in :zephyr_file:`kconfigfunctions.py
	<scripts/kconfig/kconfigfunctions.py>`.

	See :ref:`the Kconfig section of the manual <kconfig>` for more information.

	Build Phase
	-----------

	The build phase begins when the user invokes ``make`` or ``ninja``. Its
	ultimate output is a complete Zephyr application in a format suitable for
	loading/flashing on the desired target board (:file:`zephyr.elf`,
	:file:`zephyr.hex`, etc.) The build phase can be broken down, conceptually,
	into four stages: the pre-build, first-pass binary, final binary, and
	post-processing.

	Pre-build
	+++++++++

	Pre-build occurs before any source files are compiled, because during
	this phase header files used by the source files are generated.

	Offset generation
	Access to high-level data structures and members is sometimes
	required when the definitions of those structures is not
	immediately accessible (e.g., assembly language). The generation of
	offsets.h (by gen_offset_header.py) facilitates this.

	System call boilerplate
	The gen_syscall.py and parse_syscalls.py scripts work
	together to bind potential system call functions with their
	implementations.

	.. figure:: build-build-phase-1.svg
	:align: center
	:alt: Zephyr's build stage I
	:figclass: align-center
	:width: 80%

	Intermediate binaries
	+++++++++++++++++++++

	Compilation proper begins with the first intermediate binary. Source files (C
	and assembly) are collected from various subsystems (which ones is
	decided during the configuration phase), and compiled into archives
	(with reference to header files in the tree, as well as those
	generated during the configuration phase and the pre-build stage(s)).

	.. figure:: build-build-phase-2.svg
	:align: center
	:alt: Zephyr's build stage II
	:figclass: align-center
	:width: 80%

	The exact number of intermediate binaries is decided during the configuration
	phase.

	If memory protection is enabled, then:

	Partition grouping
	The gen_app_partitions.py script scans all the
	generated archives and outputs linker scripts to ensure that
	application partitions are properly grouped and aligned for the
	target’s memory protection hardware.

	Then cpp is used to combine linker script fragments from the target’s
	architecture/SoC, the kernel tree, optionally the partition output if
	memory protection is enabled, and any other fragments selected during
	the configuration process, into a linker.cmd file. The compiled
	archives are then linked with ld as specified in the
	linker.cmd.

	Unfixed size binary
	The unfixed size intermediate binary is produced when :ref:`usermode_api`
	is enabled or :ref:`devicetree` is in use.
	It produces a binary where sizes are not fixed and thus it may be used
	by post-process steps that will impact the size of the final binary.

	.. figure:: build-build-phase-3.svg
	:align: center
	:alt: Zephyr's build stage III
	:figclass: align-center
	:width: 80%

	Fixed size binary
	The fixed size intermediate binary is produced when :ref:`usermode_api`
	is enabled or when generated IRQ tables are used,
	:kconfig:option:`CONFIG_GEN_ISR_TABLES`
	It produces a binary where sizes are fixed and thus the size must not change
	between the intermediate binary and the final binary.

	.. figure:: build-build-phase-4.svg
	:align: center
	:alt: Zephyr's build stage IV
	:figclass: align-center
	:width: 80%

	Intermediate binaries post-processing
	+++++++++++++++++++++++++++++++++++++

	The binaries from the previous stage are incomplete, with empty and/or
	placeholder sections that must be filled in by, essentially, reflection.

	To complete the build procedure the following scripts are executed on the
	intermediate binaries to produce the missing pieces needed for the final
	binary.

	When :ref:`usermode_api` is enabled:

	Partition alignment
	The gen_app_partitions.py script scans the unfixed size binary and
	generates an app shared memory aligned linker script snippet where the
	partitions are sorted in descending order.

	.. figure:: build-postprocess-1.svg
	:align: center
	:alt: Zephyr's intermediate binary post-process I
	:figclass: align-center
	:width: 80%

	When :ref:`devicetree` is used:

	Device dependencies
	The gen_handles.py script scans the unfixed size binary to determine
	relationships between devices that were recorded from devicetree data,
	and replaces the encoded relationships with values that are optimized to
	locate the devices actually present in the application.

	.. figure:: build-postprocess-2.svg
	:align: center
	:alt: Zephyr's intermediate binary post-process II
	:figclass: align-center
	:width: 80%

	When :kconfig:option:`CONFIG_GEN_ISR_TABLES` is enabled:
	The gen_isr_tables.py script scant the fixed size binary and creates
	an isr_tables.c source file with a hardware vector table and/or software
	IRQ table.

	.. figure:: build-postprocess-3.svg
	:align: center
	:alt: Zephyr's intermediate binary post-process III
	:figclass: align-center
	:width: 80%

	When :ref:`usermode_api` is enabled:

	Kernel object hashing
	The gen_kobject_list.py scans the ELF DWARF
	debug data to find the address of the all kernel objects. This
	list is passed to gperf, which generates a perfect hash function and
	table of those addresses, then that output is optimized by
	process_gperf.py, using known properties of our special case.

	.. figure:: build-postprocess-4.svg
	:align: center
	:alt: Zephyr's intermediate binary post-process IV
	:figclass: align-center
	:width: 80%

	When no intermediate binary post-processing is required then the first
	intermediate binary will be directly used as the final binary.

	Final binary
	++++++++++++

	The binary from the previous stage is incomplete, with empty and/or
	placeholder sections that must be filled in by, essentially, reflection.

	The link from the previous stage is repeated, this time with the missing
	pieces populated.

	.. figure:: build-build-phase-5.svg
	:align: center
	:alt: Zephyr's build final stage
	:figclass: align-center
	:width: 80%

	Post processing
	+++++++++++++++

	Finally, if necessary, the completed kernel is converted from ELF to
	the format expected by the loader and/or flash tool required by the
	target. This is accomplished in a straightforward manner with objdump.

	.. figure:: build-build-phase-6.svg
	:align: center
	:alt: Zephyr's build final stage post-process
	:figclass: align-center
	:width: 80%


	.. _build_system_scripts:

	Supporting Scripts and Tools
	============================

	The following is a detailed description of the scripts used during the build process.

	.. _gen_syscalls.py:

	:zephyr_file:`scripts/gen_syscalls.py`
	--------------------------------------

	.. include:: ../../../scripts/gen_syscalls.py
	:start-after: """
	:end-before: """

	.. _gen_handles.py:

	:zephyr_file:`scripts/gen_handles.py`
	--------------------------------------

	.. include:: ../../../scripts/gen_handles.py
	:start-after: """
	:end-before: """

	.. _gen_kobject_list.py:

	:zephyr_file:`scripts/gen_kobject_list.py`
	------------------------------------------

	.. include:: ../../../scripts/gen_kobject_list.py
	:start-after: """
	:end-before: """

	.. _gen_offset_header.py:

	:zephyr_file:`scripts/gen_offset_header.py`
	-------------------------------------------

	.. include:: ../../../scripts/gen_offset_header.py
	:start-after: """
	:end-before: """

	.. _parse_syscalls.py:

	:zephyr_file:`scripts/parse_syscalls.py`
	----------------------------------------


	.. include:: ../../../scripts/parse_syscalls.py
	:start-after: """
	:end-before: """

	.. _gen_idt.py:

	:zephyr_file:`arch/x86/gen_idt.py`
	----------------------------------

	.. include:: ../../../arch/x86/gen_idt.py
	:start-after: """
	:end-before: """

	.. _gen_gdt.py:

	:zephyr_file:`arch/x86/gen_gdt.py`
	----------------------------------

	.. include:: ../../../arch/x86/gen_gdt.py
	:start-after: """
	:end-before: """

	.. _gen_relocate_app.py:

	:zephyr_file:`scripts/gen_relocate_app.py`
	-------------------------------------------

	.. include:: ../../../scripts/gen_relocate_app.py
	:start-after: """
	:end-before: """

	.. _process_gperf.py:

	:zephyr_file:`scripts/process_gperf.py`
	---------------------------------------

	.. include:: ../../../scripts/process_gperf.py
	:start-after: """
	:end-before: """

	:zephyr_file:`scripts/gen_app_partitions.py`
	--------------------------------------------

	.. include:: ../../../scripts/gen_app_partitions.py
	:start-after: """
	:end-before: """

	.. _kconfig:

	Configuration System (Kconfig)
	*******************************

	The Zephyr kernel and subsystems can be configured at build time to adapt them
	for specific application and platform needs. Configuration is handled through
	Kconfig, which is the same configuration system used by the Linux kernel. The
	goal is to support configuration without having to change any source code.

	Configuration options (often called symbols) are defined in :file:`Kconfig`
	files, which also specify dependencies between symbols that determine what
	configurations are valid. Symbols can be grouped into menus and sub-menus to
	keep the interactive configuration interfaces organized.

	The output from Kconfig is a header file :file:`autoconf.h` with macros that
	can be tested at build time. Code for unused features can be compiled out to
	save space.

	The following sections explain how to set Kconfig configuration options, go
	into detail on how Kconfig is used within the Zephyr project, and have some
	tips and best practices for writing :file:`Kconfig` files.

	.. toctree::
	:maxdepth: 1

	kconfig/menuconfig.rst
	kconfig/setting.rst
	kconfig/tips.rst
	kconfig/preprocessor-functions.rst
	kconfig/extensions.rst

	Users interested in optimizing their configuration for security should refer
	to the Zephyr Security Guide's section on the :ref:`hardening`.