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The Subnetwork Access Protocol (SNAP) is a mechanism for multiplexing, on networks using IEEE 802.2 LLC, more protocols than can be distinguished by the eight-bit 802.2 Service Access Point (SAP) fields. SNAP supports identifying protocols by EtherType field values; it also supports vendor-private protocol identifier spaces. It is used with IEEE 802.3, IEEE 802.4, IEEE 802.5, IEEE 802.11 and other IEEE 802 physical network layers, as well as with non-IEEE 802 physical network layers such as FDDI that use 802.2 LLC.

The SNAP and LSAP fields are added to the packets at the transmitting node in order to allow the receiving node to pass each received frame to an appropriate device driver which understands the given protocol.

Background

The OSI model uses a Service Access Point (SAP) to define the communication between layers (like Network, Transport, Session, and the other layers of the seven-layer model), that is to identify which protocol should process an incoming message. Within a given layer, programs can exchange data by a mutually agreed-upon protocol mechanism. A pair of programs that do not support a common protocol cannot communicate with each other. Thus for multiple protocols to coexist within a layer, it is necessary to determine which protocol is invoked to process a service data unit delivered by the lower layer.

The most common reference to SAP, including a Source Service Access Point (SSAP) and a Destination Service Access Point (DSAP) refers to the boundary between the Data Link Layer and the Network Layer. It is common to think of SAP only in terms of its use at Layer 2, specifically in its Logical Link Control (LLC) sub-layer as defined in the IEEE 802.2 standards. Link Service Access Point (LSAP) includes both Destination Service Access Point (DSAP) and Source Service Access Point (SSAP). It enables a MAC station to communicate with upper layers via different protocols.

Standard Network layer protocols have been assigned reserved LLC addresses, as recorded in ISO/IEC TR 11802-1. One half of the LLC address space is reserved for such assignment. Other protocols are accommodated in two ways. One way is by local assignment of LSAPs, for which the other half of the LLC address space is available. The second way is to use a particular reserved LLC address value that has been assigned for use in conjunction with the Sub-network Access Protocol (SNAP) is called the SNAP address. The SNAP address identifies, at each MAC SAP, a single LSAP. Thus, each protocol using SNAP must employ a protocol identifier. Thus, the Subnetwork Access Protocol (SNAP) is a mechanism for multiplexing, on networks using IEEE 802.2 LLC, more protocols than can be distinguished by the 8-bit 802.2 Service Access Point (SAP) fields. SNAP supports identifying protocols by Ethernet type field values; it also supports vendor-private protocol identifier spaces. It is used with IEEE 802.3, IEEE 802.4, IEEE 802.5, IEEE 802.11 and other IEEE 802 physical network layers, as well as with non-IEEE 802 physical network layers such as FDDI that use 802.2 LLC.

Use

The SNAP is an extension of the 802.2 LLC specified in the IEEE 802 Overview and Architecture document.[1] The 5-octet SNAP header follows the 802.2 LLC header if the destination SAP (DSAP) and the source SAP (SSAP) contain hexadecimal values of AA or AB:

802.2 LLC Header SNAP extension
DSAP SSAP Control OUI Protocol ID
1 octet 1 octet 1 or 2 octets 3 octets 2 octets

The SNAP header consists of a 3-octet IEEE organizationally unique identifier (OUI) followed by a 2-octet protocol ID. If the OUI is zero, the protocol ID is the registered EtherType value for the protocol running on top of SNAP. If the OUI is an OUI for a particular organization, the protocol ID is a value assigned by that organization to the protocol running on top of SNAP.

SNAP is usually used with Unnumbered Information 802.2 protocol data units (PDUs), with a control field value of 3, and the LSAP values are usually hexadecimal AA, so the 802.2 LLC header for a SNAP packet is usually AA AA 03; however, SNAP can be used with other PDU types as well.

On Ethernet, the 8 octets occupied by the LLC and SNAP headers reduce the size of the available payload for protocols such as the Internet Protocol to 1492 bytes, compared to the use of the Ethernet II framing; therefore, for protocols that have EtherType values, packets are usually transmitted with Ethernet II headers rather than with LLC and SNAP headers. On other network types, the LLC and SNAP headers are required in order to multiplex different protocols on the link layer, as the MAC layer doesn't itself have an EtherType field, so there's no alternative framing that would have a larger available payload.

One might ask, "why is a separate sub-network header necessary?". The answer is that it was to augment a decision made during the layout of the LLC header. At the time that the LLC header was being designed, it was thought that a single octet (256 possible values) in the header would be enough to specify all the protocol values that vendors would want to register. As the values began to be reserved, it was discovered that the LLC header would soon run out of open values. The hexadecimal AA and AB values were reserved, and an additional header—the SNAP header—was developed; it can support all EtherType values and multiple spaces of private protocol values.

IP datagrams and ARP datagrams are transmitted over IEEE 802 networks using LLC and SNAP headers,[2] except on Ethernet/IEEE 802.3, where they are transmitted with Ethernet II headers.[3]

References

  1. ^ IEEE 802 Overview and Architecture, IEEE, archived from the original on November 29, 2010, retrieved 2014-08-02
  2. ^ J. Postel; J. Reynolds (February 1988). A Standard for the Transmission of IP Datagrams over IEEE 802 Networks. Network Working Group. doi:10.17487/RFC1042. STD 43. RFC 1042. Internet Standard 43. Obsoletes RFC 948.
  3. ^ C. Hornig (April 1984). A Standard for the Transmission of IP Datagrams over Ethernet Networks. Network Working Group. doi:10.17487/RFC0894. STD 41. RFC 894. Internet Standard 41.