doc/connectivity/networking/api/net_buf.rst - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 .. _net_buf_interface:

 Network Buffer
 ##############

 .. contents::
     :local:
     :depth: 2


 Overview
 ********

 Network buffers are a core concept of how the networking stack
 (as well as the Bluetooth stack) pass data around. The API for them is
 defined in :zephyr_file:`include/zephyr/net/buf.h`:.

 Creating buffers
 ****************

 Network buffers are created by first defining a pool of them:

 .. code-block:: c

    NET_BUF_POOL_DEFINE(pool_name, buf_count, buf_size, user_data_size, NULL);

 The pool is a static variable, so if it's needed to be exported to
 another module a separate pointer is needed.

 Once the pool has been defined, buffers can be allocated from it with:

 .. code-block:: c

    buf = net_buf_alloc(&pool_name, timeout);

 There is no explicit initialization function for the pool or its
 buffers, rather this is done implicitly as :c:func:`net_buf_alloc` gets
 called.

 If there is a need to reserve space in the buffer for protocol headers
 to be prepended later, it's possible to reserve this headroom with:

 .. code-block:: c

    net_buf_reserve(buf, headroom);

 In addition to actual protocol data and generic parsing context, network
 buffers may also contain protocol-specific context, known as user data.
 Both the maximum data and user data capacity of the buffers is
 compile-time defined when declaring the buffer pool.

 The buffers have native support for being passed through k_fifo kernel
 objects. This is a very practical feature when the buffers need to be
 passed from one thread to another. However, since a net_buf may have a
 fragment chain attached to it, instead of using the :c:func:`k_fifo_put`
 and :c:func:`k_fifo_get` APIs, special :c:func:`net_buf_put` and
 :c:func:`net_buf_get` APIs must be used when passing buffers through
 FIFOs. These APIs ensure that the buffer chains stay intact. The same
 applies for passing buffers through a singly linked list, in which case
 the :c:func:`net_buf_slist_put` and :c:func:`net_buf_slist_get`
 functions must be used instead of :c:func:`sys_slist_append` and
 :c:func:`sys_slist_get`.

 Common Operations
 *****************

 The network buffer API provides some useful helpers for encoding and
 decoding data in the buffers. To fully understand these helpers it's
 good to understand the basic names of operations used with them:

 Add
   Add data to the end of the buffer. Modifies the data length value
   while leaving the actual data pointer intact. Requires that there is
   enough tailroom in the buffer. Some examples of APIs for adding data:

   .. code-block:: c

      void *net_buf_add(struct net_buf *buf, size_t len);
      void *net_buf_add_mem(struct net_buf *buf, const void *mem, size_t len);
      uint8_t *net_buf_add_u8(struct net_buf *buf, uint8_t value);
      void net_buf_add_le16(struct net_buf *buf, uint16_t value);
      void net_buf_add_le32(struct net_buf *buf, uint32_t value);

 Remove
   Remove data from the end of the buffer. Modifies the data length value
   while leaving the actual data pointer intact. Some examples of APIs for
   removing data:

   .. code-block:: c

      void *net_buf_remove_mem(struct net_buf *buf, size_t len);
      uint8_t net_buf_remove_u8(struct net_buf *buf);
      uint16_t net_buf_remove_le16(struct net_buf *buf);
      uint32_t net_buf_remove_le32(struct net_buf *buf);

 Push
   Prepend data to the beginning of the buffer. Modifies both the data
   length value as well as the data pointer. Requires that there is
   enough headroom in the buffer. Some examples of APIs for pushing data:

   .. code-block:: c

      void *net_buf_push(struct net_buf *buf, size_t len);
      void *net_buf_push_mem(struct net_buf *buf, const void *mem, size_t len);
      void net_buf_push_u8(struct net_buf *buf, uint8_t value);
      void net_buf_push_le16(struct net_buf *buf, uint16_t value);

 Pull
   Remove data from the beginning of the buffer. Modifies both the data
   length value as well as the data pointer. Some examples of APIs for
   pulling data:

   .. code-block:: c

      void *net_buf_pull(struct net_buf *buf, size_t len);
      void *net_buf_pull_mem(struct net_buf *buf, size_t len);
      uint8_t net_buf_pull_u8(struct net_buf *buf);
      uint16_t net_buf_pull_le16(struct net_buf *buf);
      uint32_t net_buf_pull_le32(struct net_buf *buf);

 The Add and Push operations are used when encoding data into the buffer,
 whereas the Remove and Pull operations are used when decoding data from a
 buffer.

 Reference Counting
 ******************

 Each network buffer is reference counted. The buffer is initially
 acquired from a free buffers pool by calling :c:func:`net_buf_alloc()`,
 resulting in a buffer with reference count 1. The reference count can be
 incremented with :c:func:`net_buf_ref()` or decremented with
 :c:func:`net_buf_unref()`. When the count drops to zero the buffer is
 automatically placed back to the free buffers pool.


 API Reference
 *************

 .. doxygengroup:: net_buf
	.. _net_buf_interface:

	Network Buffer
	##############

	.. contents::
	:local:
	:depth: 2


	Overview
	********

	Network buffers are a core concept of how the networking stack
	(as well as the Bluetooth stack) pass data around. The API for them is
	defined in :zephyr_file:`include/zephyr/net/buf.h`:.

	Creating buffers
	****************

	Network buffers are created by first defining a pool of them:

	.. code-block:: c

	NET_BUF_POOL_DEFINE(pool_name, buf_count, buf_size, user_data_size, NULL);

	The pool is a static variable, so if it's needed to be exported to
	another module a separate pointer is needed.

	Once the pool has been defined, buffers can be allocated from it with:

	.. code-block:: c

	buf = net_buf_alloc(&pool_name, timeout);

	There is no explicit initialization function for the pool or its
	buffers, rather this is done implicitly as :c:func:`net_buf_alloc` gets
	called.

	If there is a need to reserve space in the buffer for protocol headers
	to be prepended later, it's possible to reserve this headroom with:

	.. code-block:: c

	net_buf_reserve(buf, headroom);

	In addition to actual protocol data and generic parsing context, network
	buffers may also contain protocol-specific context, known as user data.
	Both the maximum data and user data capacity of the buffers is
	compile-time defined when declaring the buffer pool.

	The buffers have native support for being passed through k_fifo kernel
	objects. This is a very practical feature when the buffers need to be
	passed from one thread to another. However, since a net_buf may have a
	fragment chain attached to it, instead of using the :c:func:`k_fifo_put`
	and :c:func:`k_fifo_get` APIs, special :c:func:`net_buf_put` and
	:c:func:`net_buf_get` APIs must be used when passing buffers through
	FIFOs. These APIs ensure that the buffer chains stay intact. The same
	applies for passing buffers through a singly linked list, in which case
	the :c:func:`net_buf_slist_put` and :c:func:`net_buf_slist_get`
	functions must be used instead of :c:func:`sys_slist_append` and
	:c:func:`sys_slist_get`.

	Common Operations
	*****************

	The network buffer API provides some useful helpers for encoding and
	decoding data in the buffers. To fully understand these helpers it's
	good to understand the basic names of operations used with them:

	Add
	Add data to the end of the buffer. Modifies the data length value
	while leaving the actual data pointer intact. Requires that there is
	enough tailroom in the buffer. Some examples of APIs for adding data:

	.. code-block:: c

	void net_buf_add(struct net_buf buf, size_t len);
	void net_buf_add_mem(struct net_buf buf, const void *mem, size_t len);
	uint8_t net_buf_add_u8(struct net_buf buf, uint8_t value);
	void net_buf_add_le16(struct net_buf *buf, uint16_t value);
	void net_buf_add_le32(struct net_buf *buf, uint32_t value);

	Remove
	Remove data from the end of the buffer. Modifies the data length value
	while leaving the actual data pointer intact. Some examples of APIs for
	removing data:

	.. code-block:: c

	void net_buf_remove_mem(struct net_buf buf, size_t len);
	uint8_t net_buf_remove_u8(struct net_buf *buf);
	uint16_t net_buf_remove_le16(struct net_buf *buf);
	uint32_t net_buf_remove_le32(struct net_buf *buf);

	Push
	Prepend data to the beginning of the buffer. Modifies both the data
	length value as well as the data pointer. Requires that there is
	enough headroom in the buffer. Some examples of APIs for pushing data:

	.. code-block:: c

	void net_buf_push(struct net_buf buf, size_t len);
	void net_buf_push_mem(struct net_buf buf, const void *mem, size_t len);
	void net_buf_push_u8(struct net_buf *buf, uint8_t value);
	void net_buf_push_le16(struct net_buf *buf, uint16_t value);

	Pull
	Remove data from the beginning of the buffer. Modifies both the data
	length value as well as the data pointer. Some examples of APIs for
	pulling data:

	.. code-block:: c

	void net_buf_pull(struct net_buf buf, size_t len);
	void net_buf_pull_mem(struct net_buf buf, size_t len);
	uint8_t net_buf_pull_u8(struct net_buf *buf);
	uint16_t net_buf_pull_le16(struct net_buf *buf);
	uint32_t net_buf_pull_le32(struct net_buf *buf);

	The Add and Push operations are used when encoding data into the buffer,
	whereas the Remove and Pull operations are used when decoding data from a
	buffer.

	Reference Counting
	******************

	Each network buffer is reference counted. The buffer is initially
	acquired from a free buffers pool by calling :c:func:`net_buf_alloc()`,
	resulting in a buffer with reference count 1. The reference count can be
	incremented with :c:func:`net_buf_ref()` or decremented with
	:c:func:`net_buf_unref()`. When the count drops to zero the buffer is
	automatically placed back to the free buffers pool.


	API Reference
	*************

	.. doxygengroup:: net_buf