doc/contribute/conventions.rst - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 .. _naming_conventions:

 Coding Style and Conventions
 #################################

 Naming Conventions
 ******************

 Unlike desktop operating systems, where applications are written in user-space
 and drivers are used to cross the boundary between kernel and user space, *all*
 applications in the Zephyr Kernel are written in kernel space. Applications are
 linked with the kernel, creating a shared and common namespace.

 To ensure proper execution of both kernel and applications, it makes sense to
 divide the namespace into kernel and application subspaces. This is achieved
 by restricting the kernel’s global symbols and macros to a well-defined set of
 name prefixes. These prefixes apply both to public symbols, which applications
 can reference, and to private symbols, which only the kernel itself is
 permitted to reference. Symbols that do not begin with a kernel namespace
 prefix are available to applications with a few exceptions. See `Exceptions
 to the Namespace`_ for details.

 +----------+--------------------------------------+------------------------+
 | Prefix   | Description                          | Example                |
 +==========+======================================+========================+
 | \_       | Denotes a private symbol.            | ``_k_signal_event``    |
 +----------+--------------------------------------+------------------------+
 | atomic\_ | Denotes an atomic operation.         | ``atomic_inc``         |
 +----------+--------------------------------------+------------------------+
 | device\_ | Denotes an API relating to devices   | ``device_get_binding`` |
 |          | and their initialization.            |                        |
 +----------+--------------------------------------+------------------------+
 | fiber\_  | Denotes an operation invoked by a    | ``fiber_event_send``   |
 |          | fiber; typically a microkernel       |                        |
 |          | operation.                           |                        |
 +----------+--------------------------------------+------------------------+
 | irq\_    | Denotes an IRQ management operation. | ``irq_disable``        |
 +----------+--------------------------------------+------------------------+
 | isr\_    | Denotes an operation called by an    | ``isr_event_send``     |
 |          | Interrupt Service Routine; typically |                        |
 |          | a microkernel operation.             |                        |
 +----------+--------------------------------------+------------------------+
 | k\_      | Microkernel-specific function.       | ``k_memcpy``           |
 +----------+--------------------------------------+------------------------+
 | k_do\_   | Microkernel-specific functions       | ``k_do_event_signal``  |
 |          | indicating essential operation       |                        |
 |          | within the kernel space. Do not use  |                        |
 |          | these functions unless absolutely    |                        |
 |          | necessary.                           |                        |
 +----------+--------------------------------------+------------------------+
 | nano\_   | Denotes an operation provided by the | ``nano_fifo_put``      |
 |          | nanokernel; typically used in a      |                        |
 |          | microkernel system, not just a       |                        |
 |          | nanokernel system.                   |                        |
 +----------+--------------------------------------+------------------------+
 | sys\_    | Catch-all for APIs that do not fit   | ``sys_write32``        |
 |          | into the other namespaces.           |                        |
 +----------+--------------------------------------+------------------------+
 | task\_   | Denotes an operation invoked by a    | ``task_send_event``    |
 |          | task; typically a microkernel        |                        |
 |          | operation.                           |                        |
 +----------+--------------------------------------+------------------------+


 If your additional symbol does not fall into the above classification, consider
 renaming it.

 Exceptions to the Namespace
 ===========================

 Some kernel APIs use well-known names that lack prefixes. A few examples are:

 * :code:`ntohl`

 * :code:`open`

 * :code:`close`

 * :code:`read`

 * :code:`write`

 * :code:`ioctl`

 In rare cases a few global symbols do not use the normal kernel prefixes;
  :cpp:func:`kernel_version_get()` is one such example.

 Subsystem Naming Conventions
 ============================

 Generally, any sub-system can define its own naming conventions for symbols.
 However, these should be implemented with their own namespace prefix (for
 example, ``bt\_`` for BlueTooth, or ``net\_`` for IP). This limits possible
 clashes with applications. Following this prefix convention with subsystems
 keeps a consistent interface for all users.

 Minimize Include Paths
 ======================

 The current build system uses a series of :file:`defs.objs` files to define the
 common pieces for a given subsystem. For example, common defines for x86
 architecture are located under :file:`$ROOT/arch/x86`, with platform-specific
 defines underneath it, like :file:`$ROOT/arch/x86/platform/ia32`.
 Be careful to not add all possible :literal:`include` paths to the
 :file:`defs.obj` files. Too many default paths can cause problems when more than
 one file has the same name. The only :literal:`include paths` into
 :file:`${vBASE}/include` should be :file:`${vBASE}/include` itself, and the header
 files should be included with:

 .. code-block:: c

    #include <subdirectory/header.h>.

 For example, if you have two files, :file:`include/pci.h` and
 :file:`include/drvers/pci.h`, and have set both :option:`-Iinclude/drivers`
 and :option:`-Iinclude` for your compile, then any code using

 .. code-block:: c

    #include <pci.h> becomes ambiguous, while
    #include <drivers/pci.h>

 is not. Not having :option:`-Iinclude/drivers` forces users to use the second
 form which is more explicit.

 .. include:: error_code_conventions.rst

 .. include:: coding_style.rst
	.. _naming_conventions:

	Coding Style and Conventions
	#################################

	Naming Conventions
	******************

	Unlike desktop operating systems, where applications are written in user-space
	and drivers are used to cross the boundary between kernel and user space, all
	applications in the Zephyr Kernel are written in kernel space. Applications are
	linked with the kernel, creating a shared and common namespace.

	To ensure proper execution of both kernel and applications, it makes sense to
	divide the namespace into kernel and application subspaces. This is achieved
	by restricting the kernel’s global symbols and macros to a well-defined set of
	name prefixes. These prefixes apply both to public symbols, which applications
	can reference, and to private symbols, which only the kernel itself is
	permitted to reference. Symbols that do not begin with a kernel namespace
	prefix are available to applications with a few exceptions. See `Exceptions
	to the Namespace`_ for details.

	+----------+--------------------------------------+------------------------+
	\| Prefix \| Description \| Example \|
	+==========+======================================+========================+
	\| \_ \| Denotes a private symbol. \| ``_k_signal_event`` \|
	+----------+--------------------------------------+------------------------+
	\| atomic\_ \| Denotes an atomic operation. \| ``atomic_inc`` \|
	+----------+--------------------------------------+------------------------+
	\| device\_ \| Denotes an API relating to devices \| ``device_get_binding`` \|
	\| \| and their initialization. \| \|
	+----------+--------------------------------------+------------------------+
	\| fiber\_ \| Denotes an operation invoked by a \| ``fiber_event_send`` \|
	\| \| fiber; typically a microkernel \| \|
	\| \| operation. \| \|
	+----------+--------------------------------------+------------------------+
	\| irq\_ \| Denotes an IRQ management operation. \| ``irq_disable`` \|
	+----------+--------------------------------------+------------------------+
	\| isr\_ \| Denotes an operation called by an \| ``isr_event_send`` \|
	\| \| Interrupt Service Routine; typically \| \|
	\| \| a microkernel operation. \| \|
	+----------+--------------------------------------+------------------------+
	\| k\_ \| Microkernel-specific function. \| ``k_memcpy`` \|
	+----------+--------------------------------------+------------------------+
	\| k_do\_ \| Microkernel-specific functions \| ``k_do_event_signal`` \|
	\| \| indicating essential operation \| \|
	\| \| within the kernel space. Do not use \| \|
	\| \| these functions unless absolutely \| \|
	\| \| necessary. \| \|
	+----------+--------------------------------------+------------------------+
	\| nano\_ \| Denotes an operation provided by the \| ``nano_fifo_put`` \|
	\| \| nanokernel; typically used in a \| \|
	\| \| microkernel system, not just a \| \|
	\| \| nanokernel system. \| \|
	+----------+--------------------------------------+------------------------+
	\| sys\_ \| Catch-all for APIs that do not fit \| ``sys_write32`` \|
	\| \| into the other namespaces. \| \|
	+----------+--------------------------------------+------------------------+
	\| task\_ \| Denotes an operation invoked by a \| ``task_send_event`` \|
	\| \| task; typically a microkernel \| \|
	\| \| operation. \| \|
	+----------+--------------------------------------+------------------------+


	If your additional symbol does not fall into the above classification, consider
	renaming it.

	Exceptions to the Namespace
	===========================

	Some kernel APIs use well-known names that lack prefixes. A few examples are:

	* :code:`ntohl`

	* :code:`open`

	* :code:`close`

	* :code:`read`

	* :code:`write`

	* :code:`ioctl`

	In rare cases a few global symbols do not use the normal kernel prefixes;
	:cpp:func:`kernel_version_get()` is one such example.

	Subsystem Naming Conventions
	============================

	Generally, any sub-system can define its own naming conventions for symbols.
	However, these should be implemented with their own namespace prefix (for
	example, ``bt\_`` for BlueTooth, or ``net\_`` for IP). This limits possible
	clashes with applications. Following this prefix convention with subsystems
	keeps a consistent interface for all users.

	Minimize Include Paths
	======================

	The current build system uses a series of :file:`defs.objs` files to define the
	common pieces for a given subsystem. For example, common defines for x86
	architecture are located under :file:`$ROOT/arch/x86`, with platform-specific
	defines underneath it, like :file:`$ROOT/arch/x86/platform/ia32`.
	Be careful to not add all possible :literal:`include` paths to the
	:file:`defs.obj` files. Too many default paths can cause problems when more than
	one file has the same name. The only :literal:`include paths` into
	:file:`${vBASE}/include` should be :file:`${vBASE}/include` itself, and the header
	files should be included with:

	.. code-block:: c

	#include <subdirectory/header.h>.

	For example, if you have two files, :file:`include/pci.h` and
	:file:`include/drvers/pci.h`, and have set both :option:`-Iinclude/drivers`
	and :option:`-Iinclude` for your compile, then any code using

	.. code-block:: c

	#include <pci.h> becomes ambiguous, while
	#include <drivers/pci.h>

	is not. Not having :option:`-Iinclude/drivers` forces users to use the second
	form which is more explicit.

	.. include:: error_code_conventions.rst

	.. include:: coding_style.rst