doc/porting/board_porting.rst - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 .. _board_porting_guide:

 Board Porting Guide
 ###################

 When building an application you must specify the target hardware and
 the exact board or model. Specifying the board name results in a binary that
 is suited for the target hardware by selecting the right Zephyr features and
 components and setting the right Zephyr configuration for that specific target
 hardware.

 A board is defined as a special configuration of an SoC with possible additional
 components.
 For example, a board might have sensors and flash memory implemented as
 additional features on top of what the SoC provides. Such additional hardware is
 configured and referenced in the Zephyr board configuration.

 The board implements at least one SoC and thus inherits all of the features
 that are provided by the SoC. When porting a board to Zephyr, you should
 first make sure the SoC is implemented in Zephyr.

 Hardware Configuration Hierarchy
 ********************************

 Hardware definitions in Zephyr follow a well-defined hierarchy of configurations
 and layers, below are the layers from top to bottom:

 - Board
 - SoC
 - SoC Series
 - SoC Family
 - CPU Core
 - Architecture

 This design contributes to code reuse and implementation of device drivers and
 features at the bottom of the hierarchy making a board configuration as simple
 as a selection of features that are implemented by the underlying layers. The
 figures below shows this hierarchy with a few example of boards currently
 available in the source tree:

 .. figure:: board/hierarchy.png
    :width: 500px
    :align: center
    :alt: Configuration Hierarchy

    Configuration Hierarchy


 Hierarchy Example

 +------------+-----------+--------------+------------+--------------+---------+
 |Board       |FRDM K64F  |nRF52 NITROGEN|nRF51XX     |Quark SE C1000|Arduino  |
 |            |           |              |            |Devboard      |101      |
 +============+===========+==============+============+==============+=========+
 |SOC         |MK64F12    |nRF52832      |nRF51XX     |Quark SE C1000|Curie    |
 +------------+-----------+--------------+------------+--------------+---------+
 |SOC Series  |Kinetis K6x|Nordic NRF52  |Nordic NRF51|Quark SE      |Quark SE |
 |            |Series     |              |            |              |         |
 +------------+-----------+--------------+------------+--------------+---------+
 |SOC Family  |NXP Kinetis|Nordic NRF5   |Nordic NRF5 |Quark         |Quark    |
 +------------+-----------+--------------+------------+--------------+---------+
 |CPU Core    |Cortex-M4  |Cortex-M4     |Cortex-M0+  |Lakemont      |Lakemont |
 +------------+-----------+--------------+------------+--------------+---------+
 |Architecture|ARM        |ARM           |ARM         |x86           |x86      |
 +------------+-----------+--------------+------------+--------------+---------+


 Architecture
 ============
 If your CPU architecture is already supported by Zephyr, there is no
 architecture work involved in porting to your board.  If your CPU architecture
 is not supported by the Zephyr kernel, you can add support by following the
 instructions available at :ref:`architecture_porting_guide`.

 CPU Core
 ========

 Some OS code depends on the CPU core that your board is using. For
 example, a given CPU core has a specific assembly language instruction set, and
 may require special cross compiler or compiler settings to use the appropriate
 instruction set.

 If your CPU architecture is already supported by Zephyr, there is no CPU core
 work involved in porting to your platform or board. You need only to select the
 appropriate CPU in your configuration and the rest will be taken care of by the
 configuration system in Zephyr which will select the features implemented
 by the corresponding CPU.

 Platform
 ========

 This layer implements most of the features that need porting and is split into
 three layers to allow for code reuse when dealing with implementations with
 slight differences.

 SoC Family
 ----------

 This layer is a container of all SoCs of the same class that, for example
 implement one single type of CPU core but differ in peripherals and features.
 The base hardware will in most cases be the same across all SoCs and MCUs of
 this family.

 SoC Series
 ----------

 Moving closer to the SoC, the series is derived from an SoC family. A series is
 defined by a feature set that serves the purpose of distinguishing different
 SoCs belonging to the same family.

 SoC
 ---

 Finally, an SoC is actual hardware component that is physically available on a
 board.

 Board
 =====

 A board implements an SoC with all its features, together with peripherals
 available on the board that differentiates the board with additional interfaces
 and features not available in the SoC.

 While adding your board support, make sure to add it to the list of
 ``platforms`` in the appropriate architecture ``.ini`` file in
 ``scripts/sanity_chk/arches/``.
	.. _board_porting_guide:

	Board Porting Guide
	###################

	When building an application you must specify the target hardware and
	the exact board or model. Specifying the board name results in a binary that
	is suited for the target hardware by selecting the right Zephyr features and
	components and setting the right Zephyr configuration for that specific target
	hardware.

	A board is defined as a special configuration of an SoC with possible additional
	components.
	For example, a board might have sensors and flash memory implemented as
	additional features on top of what the SoC provides. Such additional hardware is
	configured and referenced in the Zephyr board configuration.

	The board implements at least one SoC and thus inherits all of the features
	that are provided by the SoC. When porting a board to Zephyr, you should
	first make sure the SoC is implemented in Zephyr.

	Hardware Configuration Hierarchy
	********************************

	Hardware definitions in Zephyr follow a well-defined hierarchy of configurations
	and layers, below are the layers from top to bottom:

	- Board
	- SoC
	- SoC Series
	- SoC Family
	- CPU Core
	- Architecture

	This design contributes to code reuse and implementation of device drivers and
	features at the bottom of the hierarchy making a board configuration as simple
	as a selection of features that are implemented by the underlying layers. The
	figures below shows this hierarchy with a few example of boards currently
	available in the source tree:

	.. figure:: board/hierarchy.png
	:width: 500px
	:align: center
	:alt: Configuration Hierarchy

	Configuration Hierarchy


	Hierarchy Example

	+------------+-----------+--------------+------------+--------------+---------+
	\|Board \|FRDM K64F \|nRF52 NITROGEN\|nRF51XX \|Quark SE C1000\|Arduino \|
	\| \| \| \| \|Devboard \|101 \|
	+============+===========+==============+============+==============+=========+
	\|SOC \|MK64F12 \|nRF52832 \|nRF51XX \|Quark SE C1000\|Curie \|
	+------------+-----------+--------------+------------+--------------+---------+
	\|SOC Series \|Kinetis K6x\|Nordic NRF52 \|Nordic NRF51\|Quark SE \|Quark SE \|
	\| \|Series \| \| \| \| \|
	+------------+-----------+--------------+------------+--------------+---------+
	\|SOC Family \|NXP Kinetis\|Nordic NRF5 \|Nordic NRF5 \|Quark \|Quark \|
	+------------+-----------+--------------+------------+--------------+---------+
	\|CPU Core \|Cortex-M4 \|Cortex-M4 \|Cortex-M0+ \|Lakemont \|Lakemont \|
	+------------+-----------+--------------+------------+--------------+---------+
	\|Architecture\|ARM \|ARM \|ARM \|x86 \|x86 \|
	+------------+-----------+--------------+------------+--------------+---------+


	Architecture
	============
	If your CPU architecture is already supported by Zephyr, there is no
	architecture work involved in porting to your board. If your CPU architecture
	is not supported by the Zephyr kernel, you can add support by following the
	instructions available at :ref:`architecture_porting_guide`.

	CPU Core
	========

	Some OS code depends on the CPU core that your board is using. For
	example, a given CPU core has a specific assembly language instruction set, and
	may require special cross compiler or compiler settings to use the appropriate
	instruction set.

	If your CPU architecture is already supported by Zephyr, there is no CPU core
	work involved in porting to your platform or board. You need only to select the
	appropriate CPU in your configuration and the rest will be taken care of by the
	configuration system in Zephyr which will select the features implemented
	by the corresponding CPU.

	Platform
	========

	This layer implements most of the features that need porting and is split into
	three layers to allow for code reuse when dealing with implementations with
	slight differences.

	SoC Family
	----------

	This layer is a container of all SoCs of the same class that, for example
	implement one single type of CPU core but differ in peripherals and features.
	The base hardware will in most cases be the same across all SoCs and MCUs of
	this family.

	SoC Series
	----------

	Moving closer to the SoC, the series is derived from an SoC family. A series is
	defined by a feature set that serves the purpose of distinguishing different
	SoCs belonging to the same family.

	SoC
	---

	Finally, an SoC is actual hardware component that is physically available on a
	board.

	Board
	=====

	A board implements an SoC with all its features, together with peripherals
	available on the board that differentiates the board with additional interfaces
	and features not available in the SoC.

	While adding your board support, make sure to add it to the list of
	``platforms`` in the appropriate architecture ``.ini`` file in
	``scripts/sanity_chk/arches/``.