doc/subsystems/networking/ip-stack-architecture.rst - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 .. _ip_stack_architecture:

 IP Stack Architecture
 #####################

 High level overview of the IP stack
 ***********************************

 .. figure:: ip-stack-architecture.svg
     :align: center
     :alt: Overview of the IP stack architecture
     :figclass: align-center

     Network stack overview

 *The IP stack is layered and it consists of the following parts:*

 * **Networking Application.** This application uses the connectivity API to
   manipulate a network connection, and management API to set network
   related parameters such as starting a scan (when applicable),
   setting IP address to a network interface, etc.

 * **Core IP stack.** This provides implementations for
   various protocols such as IPv6, IPv4, UDP, TCP, ICMPv4 and ICMPv6.

 * **Network interface abstraction layer.** This provides functionality
   that is common in all the network interfaces, such as acquiring
   an IP address, etc.

 * **Generic L2 layer.** This provides common API for sending and receiving
   data to and from an actual network device.

 * **L2 network technology component.** These components include Ethernet,
   IEEE 802.15.4, Bluetooth, etc. Some of these technologies support IPv6
   header compression (6LoWPAN), which is done in its own layer. For
   example ARP for IPv4 is done in the Ethernet component.

 * **Network device driver.** The actual low-level device driver handles the
   physical sending or receiving of a network packet.


 Network data flow
 *****************

 .. figure:: ip-stack-data-flow.svg
     :align: center
     :alt: Network data flow
     :figclass: align-center

     Network data flow

 The application typically consists of one or more tasks or threads
 that execute the application logic. When using the network
 connectivity APIs, following things will happen.

 *Data receiving (RX):*

 1) A network data packet is received by a device driver.

 2) The device driver allocates enough network buffers to store the received
    data. The network buffers are then passed to the RX FIFO
    for further processing. The RX FIFO is used as a way to separate
    the data processing pipeline (bottom-half) as the device driver is
    running in interrupt context and it must do its processing very fast.

 3) The RX thread reads the RX FIFO and passes the data to the correct
    L2 driver. After the L2 driver has checked the packet, the packet is
    passed to L3 processing. The L3 layer checks if the packet is a proper
    IPv6 or IPv4 packet. If the packet contains UDP or TCP data, it
    is then sent to correct application via a function callback.
    This also means that the application data processing in that callback
    is run in thread context even if the actual application is running
    in task context. The data processing in the application callback should
    be done fast in order not to block the system too long.
    There is only one RX thread in the system. The stack size of the RX
    thread can be tweaked via Kconfig option but it should be kept as
    small as possible. This also means that stack utilization in the
    data processing callback should be minimized in order to avoid stack
    overflow.

 4) The application will then receive the data, which is stored inside a chain
    of net_bufs. The application now owns the data. After it has finished working
    with it, the application should release the net_bufs data by calling
    `net_pkt_unref()`.

 *Data sending (TX):*

 1) The application should use the connectivity API when the application is
    ready to send data. The sent data is checked by the correct L2 layer module
    and if everything is ok, the data is placed into the network interface TX
    queue. The network interface is typically selected to be the same interface
    for reply data packets or the interface is selected according to the routing
    algorithm. The application should not free the data packet if it was
    correctly placed into TX queue; the network driver will release the packet
    after it is sent. If the connectivity API sending function returns an error
    to the application, that means the packet was not sent correctly and the
    application needs to free the packet.

 2) Each network interface has a dedicated TX queue used to send data to that
    interface. A TX thread in the system reads all the TX queues and passes
    that data to the correct L2 driver, for sending via the device driver.

 3) If the device driver is able to inject the network packet into the
    network, then it will release the packet. Typically there are no
    retransmits at this lower level so usually the packet is released
    even if not sent correctly. This depends on the technology being used.
	.. _ip_stack_architecture:

	IP Stack Architecture
	#####################

	High level overview of the IP stack
	***********************************

	.. figure:: ip-stack-architecture.svg
	:align: center
	:alt: Overview of the IP stack architecture
	:figclass: align-center

	Network stack overview

	The IP stack is layered and it consists of the following parts:

	* Networking Application. This application uses the connectivity API to
	manipulate a network connection, and management API to set network
	related parameters such as starting a scan (when applicable),
	setting IP address to a network interface, etc.

	* Core IP stack. This provides implementations for
	various protocols such as IPv6, IPv4, UDP, TCP, ICMPv4 and ICMPv6.

	* Network interface abstraction layer. This provides functionality
	that is common in all the network interfaces, such as acquiring
	an IP address, etc.

	* Generic L2 layer. This provides common API for sending and receiving
	data to and from an actual network device.

	* L2 network technology component. These components include Ethernet,
	IEEE 802.15.4, Bluetooth, etc. Some of these technologies support IPv6
	header compression (6LoWPAN), which is done in its own layer. For
	example ARP for IPv4 is done in the Ethernet component.

	* Network device driver. The actual low-level device driver handles the
	physical sending or receiving of a network packet.


	Network data flow
	*****************

	.. figure:: ip-stack-data-flow.svg
	:align: center
	:alt: Network data flow
	:figclass: align-center

	Network data flow

	The application typically consists of one or more tasks or threads
	that execute the application logic. When using the network
	connectivity APIs, following things will happen.

	Data receiving (RX):

	1) A network data packet is received by a device driver.

	2) The device driver allocates enough network buffers to store the received
	data. The network buffers are then passed to the RX FIFO
	for further processing. The RX FIFO is used as a way to separate
	the data processing pipeline (bottom-half) as the device driver is
	running in interrupt context and it must do its processing very fast.

	3) The RX thread reads the RX FIFO and passes the data to the correct
	L2 driver. After the L2 driver has checked the packet, the packet is
	passed to L3 processing. The L3 layer checks if the packet is a proper
	IPv6 or IPv4 packet. If the packet contains UDP or TCP data, it
	is then sent to correct application via a function callback.
	This also means that the application data processing in that callback
	is run in thread context even if the actual application is running
	in task context. The data processing in the application callback should
	be done fast in order not to block the system too long.
	There is only one RX thread in the system. The stack size of the RX
	thread can be tweaked via Kconfig option but it should be kept as
	small as possible. This also means that stack utilization in the
	data processing callback should be minimized in order to avoid stack
	overflow.

	4) The application will then receive the data, which is stored inside a chain
	of net_bufs. The application now owns the data. After it has finished working
	with it, the application should release the net_bufs data by calling
	`net_pkt_unref()`.

	Data sending (TX):

	1) The application should use the connectivity API when the application is
	ready to send data. The sent data is checked by the correct L2 layer module
	and if everything is ok, the data is placed into the network interface TX
	queue. The network interface is typically selected to be the same interface
	for reply data packets or the interface is selected according to the routing
	algorithm. The application should not free the data packet if it was
	correctly placed into TX queue; the network driver will release the packet
	after it is sent. If the connectivity API sending function returns an error
	to the application, that means the packet was not sent correctly and the
	application needs to free the packet.

	2) Each network interface has a dedicated TX queue used to send data to that
	interface. A TX thread in the system reads all the TX queues and passes
	that data to the correct L2 driver, for sending via the device driver.

	3) If the device driver is able to inject the network packet into the
	network, then it will release the packet. Typically there are no
	retransmits at this lower level so usually the packet is released
	even if not sent correctly. This depends on the technology being used.