Editing Systems Network Architecture

{{Short description|Proprietary networking architecture created by IBM}}
{{Use American English|date=September 2022}}
{{Use MDY dates|date=September 2022}}
'''Systems Network Architecture'''<ref name=SNAunOrange>{{cite news |newspaper=[[The New York Times]] |title=A Link for All Operating Systems |author=Peter H. Lewis |date=May 14, 1989 |url=https://www.nytimes.com/1989/05/14/business/the-executive-computer-a-link-for-all-operating-systems.html |access-date=September 15, 2022}}</ref> ('''SNA''') is [[IBM]]'s proprietary [[computer network|networking]] architecture, created in 1974.<ref>{{harv|Schatt|1991|p=227}}.</ref> It is a complete [[protocol stack]] for interconnecting [[computer]]s and their resources. SNA describes formats and protocols but, in itself, is not a piece of software. The implementation of SNA takes the form of various communications packages, most notably [[Virtual Telecommunications Access Method]] (VTAM), the [[mainframe computer|mainframe]] software package for SNA communications.

==History==
[[File:Tapes and IBM 3745-170 (13889447458).jpg|thumb|IBM 3745-170]]
SNA was made public as part of IBM's "Advanced Function for Communications" announcement in September, 1974,<ref>{{cite web |last1=IBM Corporation |title=IBM Highlights, 1970-1984 |website=[[IBM]] |url=https://www.ibm.com/ibm/history/documents/pdf/1970-1984.pdf |access-date=Apr 19, 2019}}</ref> which included the implementation of the SNA/SDLC ([[Synchronous Data Link Control]]) protocols on new communications products:
*[[IBM 3767]] communication terminal (printer)
*[[IBM 3770]] [[data communication]] system
They were supported by [[IBM 3705 Communications Controller|IBM 3704/3705]] communication controllers and their [[IBM Network Control Program|Network Control Program]] (NCP), and by System/370 and their VTAM and other software such as CICS and IMS. This announcement was followed by another announcement in July, 1975, which introduced the [[IBM 3760]] data entry station, the [[IBM 3790]] communication system, and the new models of the [[IBM 3270]] display system.<ref name=newIBMin1975>{{cite report |quote=and the 3790/3760 data entry/data communications ... |title=IBM 3770 Family Batch Communications Terminal |publisher=Datapro |url=https://bitsavers.org/pdf/datapro/programmable_terminals/Datapro_C21_IBM.pdf}}</ref>

SNA was designed in the era when the computer industry had not fully adopted the concept of layered communication. Applications, databases, and communication functions were mingled into the same protocol or product, which made it difficult to maintain and manage.<ref name=NotProCon.DBxDatamation>{{cite news |magazine=[[Datamation]] |title=Bridge your legacy systems to the Web |url=https://www.datamation.com/applications/bridge-your-legacy-systems-to-the-web/}}</ref><ref>{{cite news |newspaper=[[Computerworld]] |title=Fujitsu Net Architecture |page=99 |date=November 15, 1976 |url=https://books.google.com/books?id=kuEuAAAAIBAJ&pg=PA99}}</ref> SNA was mainly designed by the IBM Systems Development Division laboratory in [[Research Triangle Park]], [[North Carolina]], USA,<ref name=TriParkSNA>{{citation |chapter=SNA: Recent advances and additional requirements |publisher=[[Springer Publishing]] |author=RJ Sundstrom |title=Networking in Open Systems |series=Lecture Notes in Computer Science |year=1987|volume=248 |pages=107–116 |isbn=3-540-17707-8 |doi=10.1007/BFb0026957 |chapter-url=https://link.springer.com/chapter/10.1007/BFb0026957}}</ref> helped by other laboratories that implemented SNA/SDLC. IBM later made the details public in its System Reference Library manuals and [[IBM Research#Publications|IBM Systems Journal]].

It is still used extensively in banks and other financial transaction networks, as well as in many government agencies. In 1999 there were an estimated 3,500 companies "with 11,000 SNA mainframes."<ref>{{cite news |newspaper=[[Informationweek]] |title=AT&T Outlines VPN Migration Plan |date=May 12, 1999 |url=https://www.informationweek.com/atandt-outlines-vpn-migration-plan/d/d-id/1007133?piddl_msgorder=asc |access-date=September 16, 2022}}</ref> One of the primary pieces of hardware, the [[IBM 3745|3745]]/3746 communications controller, has been withdrawn{{efn|However, the 3745 simulator [[Communications Controller for Linux]] (CCL) is still available.}} from the market by IBM. IBM continues to provide hardware maintenance service and microcode features to support users. A robust market of smaller companies continues to provide the 3745/3746, features, parts, and service. VTAM is also supported by IBM, as is the NCP required by the 3745/3746 controllers.

In 2008 an IBM publication said:
{{Blockquote|with the popularity and growth of TCP/IP, SNA is changing from being a true network architecture to being what could be termed an "application and application access architecture." In other words, there are many applications that still need to communicate in SNA, but the required SNA protocols are carried over the network by IP.<ref>{{cite book |title=Networking on z/OS |year=2010 |page=31 |publisher=IBM Corporation |url=https://www.ibm.com/docs/en/zosbasics/com.ibm.zos.znetwork/znetwork_book.pdf#page=41}}<br>{{cite web |title=Networking on z/OS (web document) |publisher=IBM Corporation |url=https://www.ibm.com/docs/en/zos-basic-skills?topic=review-systems-network-architecture-sna}}</ref>}}

==Objectives of SNA==
{{No footnotes|section|date=September 2022}}

IBM in the mid-1970s saw itself mainly as a hardware vendor and hence all its innovations in that period aimed to increase hardware sales. SNA's objective was to reduce the costs of operating large numbers of terminals and thus induce customers to develop or expand [[interactive]] terminal-based systems as opposed to [[batch processing|batch]] systems. An expansion of interactive terminal-based systems would increase sales of terminals and more importantly of mainframe computers and peripherals - partly because of the simple increase in the volume of work done by the systems and partly because interactive processing requires more computing power per transaction than batch processing.

Hence SNA aimed to reduce the main non-computer costs and other difficulties in operating large networks using earlier communications protocols. The difficulties included:
*Often a communications line could not be shared by terminals of different types, as they used different "dialects" of the existing communications protocols. Up to the early 1970s, computer components were so expensive and bulky that it was not feasible to include all-purpose communications interface cards in terminals. Every type of terminal had a [[hardwired control|hard-wired]] communications card which supported only the operation of one type of terminal without compatibility with other types of terminals on the same line.
*The protocols which the primitive communications cards could handle were not efficient. Each communications line used more time transmitting data than modern lines do.
*Telecommunications lines at the time were of much lower quality. For example, it was almost impossible to run a dial-up line at more than 19,200 bits per second because of the overwhelming error rate, as compared with 56,000 bits per second today on dial-up lines; and in the early 1970s few leased lines were run at more than 2400 bits per second (these low speeds are a consequence of [[Shannon–Hartley theorem|Shannon's Law]] in a relatively low-technology environment).

As a result, running a large number of terminals required a lot more communications lines than the number required today, especially if different types of terminals needed to be supported, or the users wanted to use different types of applications (.e.g. under CICS or TSO) from the same location. In purely financial terms SNA's objectives were to increase customers' spending on terminal-based systems and at the same time to increase IBM's share of that spending, mainly at the expense of the telecommunications companies.

SNA also aimed to overcome a limitation of the architecture which IBM's [[System/370]] mainframes inherited from [[System/360]]. Each CPU could connect to at most 16 [[Channel I/O|I/O channels]]<ref>devices that acted as DMA controllers for control units, which in turn attached peripherals such as tape and disk drives, printers, card-readers</ref> and each channel could handle up to 256 peripherals - i.e. there was a maximum of 4096 peripherals per CPU. At the time when SNA was designed, each communications line counted as a peripheral. Thus the number of terminals with which powerful mainframes could otherwise communicate was limited.

==Principal components and technologies==
Improvements in computer component technology made it feasible to build terminals that included more powerful communications cards which could operate a single standard [[communications protocol]] rather than a very stripped-down protocol which suited only a specific type of terminal. As a result, several [[list of network protocols|multi-layer communications protocols]] were proposed in the 1970s, of which IBM's SNA and [[ITU-T]]'s [[X.25]] became dominant later.

The most important elements of SNA include:
*[[IBM Network Control Program]] (NCP)<ref>{{cite web |publisher=Microsoft |title=SNA Functional Layers |website=[[Microsoft Docs]] |date=September 11, 2008 |url=https://learn.microsoft.com/en-us/previous-versions/windows/it-pro/windows-2000-server/cc977037(v=technet.10) |access-date=September 16, 2022}}</ref><ref>{{cite journal |author=W. S. Hobgood |title=The role of the Network Control Program in Systems Network Architecture |journal=[[IBM Systems Journal]] |year=1976 |volume=15 |issue=1 |pages=39–52 |doi=10.1147/sj.151.0039 |url=http://www.research.ibm.com/journal/sj/151/ibmsj1501E.pdf |access-date=August 26, 2006 |url-status=dead |archive-url=https://web.archive.org/web/20070316233256/http://www.research.ibm.com/journal/sj/151/ibmsj1501E.pdf |archive-date=March 16, 2007}}</ref> is a communications program running on the [[IBM 3705|3705]] and subsequent [[IBM 37xx|37xx]] communications processors that, among other things, implements the packet switching protocol defined by SNA. The protocol performed two main functions:
**It is a packet forwarding protocol, acting like modern [[switch]] - forwarding data packages to the next node, which might be a mainframe, a terminal or another 3705. The communications processors supported only hierarchical networks with a mainframe at the center, unlike modern routers which support [[peer-to-peer]] networks in which a machine at the end of the line can be both a [[client (computing)|client]] and a [[server (computing)|server]] at the same time.
**It is a multiplexer that connected multiple terminals into one communication line to the CPU, thus relieved the constraints on the maximum number of communication lines per CPU. A 3705 could support a larger number of lines (352 initially) but only counted as one peripheral by the CPUs and channels. Since the launch of SNA IBM has introduced improved communications processors, of which the latest is the [[IBM 3745|3745]].
*[[Synchronous Data Link Control]]<ref>{{cite manual |title=Synchronous Data Link Control Concepts |edition=Fifth |id=GA27-3093-4 |publisher=IBM |date=May 1992 |url=https://bitsavers.org/pdf/ibm/datacomm/GA27-3093-4_SDLC_Concepts_May1992.pdf}}</ref> (SDLC), a protocol which greatly improved the efficiency of data transfer over a single link:<ref>{{harv|Pooch|Greene|Moss|1983|p=310}}.</ref>
**It is a [[sliding window protocol]], which enables terminals and 3705 communications processors to send frames of data one after the other without waiting for an acknowledgement of the previous frame – the communications cards had sufficient memory and processing capacity to remember the last 7 frames sent or received, request re-transmission of only those frames which contained errors, and slot the re-transmitted frames into the right place in the sequence before forwarding them to the next stage.
**These frames all had the same type of envelope (frame header and trailer)<ref>{{harv|Pooch|Greene|Moss|1983|p=313}}.</ref> which contained enough information for data packages from different types of terminal to be sent along the same communications line, leaving the mainframe to deal with any differences in the formatting of the content or in the rules governing dialogs with different types of terminal.
:Remote terminals (e.g., those connected to the mainframe by telephone lines) and 3705 communications processors would have SDLC-capable communications cards.
:This is the precursor of the packet communication that eventually evolved into today's TCP/IP technology{{citation needed|date=November 2011}}. SDLC itself evolved into [[HDLC]],<ref>{{harv|Friend|Fike|Baker|Bellamy|1988|p=191}}.</ref> one of the base technologies for dedicated telecommunication circuits.
*[[VTAM]],<ref>{{cite news |last=Frank |first=Ronald A |title=IBM Delays Second Virtual TP Release; SD:C Impact Expected |newspaper=[[Computerworld]] |date=October 17, 1973 |url=https://books.google.com/books?id=pWBoOXVjuZ0C&dq=vtam+announced+intitle%3Acomputerworld&pg=PP1 |access-date=June 30, 2020}}</ref><ref>{{cite manual |publisher=IBM |title=Introduction to VTAM |id=GC27-6987-5 |date=April 1976 |url=https://bitsavers.org/pdf/ibm/sna/vtam/GC27-6987-5_Introduction_to_VTAM_Apr76.pdf}}</ref> a software package to provide log-in, session keeping, and routing services within the mainframe. A terminal user would log-in via VTAM to a specific application or application environment (e.g. [[CICS]], [[IBM Information Management System|IMS]], [[IBM DB2|DB2]], or [[Time Sharing Option|TSO]]/[[ISPF]]). A VTAM device would then route data from that terminal to the appropriate application or application environment until the user logged out and possibly logged into another application. The original versions of IBM hardware could only keep one session per terminal. In the 1980s further software (mainly from third-party vendors) made it possible for a terminal to have simultaneous sessions with different applications or application environments.

==Advantages and disadvantages==
{{procon|date=November 2012}}

SNA removed link control from the application program and placed it in the NCP. This had the following advantages and disadvantages:<!--Examine: Are these just (dis)advantages of placing LC into NCP, or is this meant to be a general comparison?-->

===Advantages===
*Localization of problems in the telecommunications network was easier because a relatively small amount of software actually dealt with communication links. There was a single error reporting system.
*Adding communication capability to an application program was much easier because the formidable area of link control software that typically requires interrupt processors and software timers was relegated to system software and [[IBM Network Control Program|NCP]].
*With the advent of [[Advanced Peer-to-Peer Networking]] (APPN), routing functionality was the responsibility of the computer as opposed to the router (as with TCP/IP networks). Each computer maintained a list of Nodes that defined the forwarding mechanisms. A centralized node type known as a Network Node maintained Global tables of all other node types. APPN stopped the need to maintain [[Advanced Program-to-Program Communication]] (APPC) routing tables that explicitly defined endpoint to endpoint connectivity. APPN sessions would route to endpoints through other allowed node types until it found the destination. This is similar to the way that routers for the [[Internet Protocol]] and the Netware [[Internetwork Packet Exchange]] protocol function. (APPN is also sometimes referred to PU2.1 or Physical Unit 2.1. APPC, also sometime referred to LU6.2 or Logical Unit 6.2, was the only protocol defined to APPN networks, but was originally one of many protocols supported by VTAM/NCP, along with LU0, LU1, LU2 (3270 Terminal), and LU3. APPC was primarily used between CICS environments, as well as database services, because it contact protocols for 2-phase commit processing). Physical Units were PU5 (VTAM), PU4 (37xx), PU2 (Cluster Controller). A PU5 was the most capable and considered the primary on all communication. Other PU devices requested a connection from the PU5 and the PU5 could establish the connection or not. The other PU types could only be secondary to the PU5. A PU2.1 added the ability to a PU2.1 to connect to another PU2.1 in a peer-to-peer environment.<ref>IBM Systems Network Architecture and APPN PU2.1 References Guides</ref>)

===Disadvantages===
*Connection to non-SNA networks was difficult. An application that needed access to some communication scheme not supported in the current version of SNA would have faced obstacles. Before IBM included [[X.25]] support (NPSI) in SNA, connecting to an X.25 network would have been awkward. Conversion between X.25 and SNA protocols could have been provided either by NCP software modifications or by an external [[protocol converter]].
*A sheaf of alternate pathways between every pair of nodes in a network had to be predesigned and stored centrally. Choice among these pathways by SNA was rigid and did not take advantage of current link loads for optimum speed.
*SNA network installation and maintenance are complicated and SNA network products are (or were) expensive. Attempts to reduce SNA network complexity by adding [[IBM Advanced Peer-to-Peer Networking]] functionality were not really successful, if only because the migration from traditional SNA to SNA/APPN was very complex, without providing much additional value, at least initially. SNA software licences (VTAM) cost as much as $10,000 a month for high-end systems. And SNA [[IBM 3745]] Communications Controllers typically cost over $100K. [[TCP/IP]] was still seen as unfit for commercial applications e.g. in the finance industry until the late 1980s, but rapidly took over in the 1990s due to its peer-to-peer networking and packet communication technology.
*SNA's connection based architecture invoked huge state machine logic to keep track of everything. APPN added a new dimension to state logic with its concept of differing node types. While it was solid when everything was running correctly, there was still a need for manual intervention. Simple things like watching the Control Point sessions had to be done manually. APPN wasn't without issues; in the early days many shops abandoned it due to issues found in APPN support. Over time, however, many of the issues were worked out but not before TCP/IP became increasingly popular in the early 1990s, which marked the beginning of the end for SNA.

==Security==
{{Blockquote|SNA at its core was designed with the ability to wrap different layers of connections with a blanket of security. To communicate within an SNA environment you would first have to connect to a node and establish and maintain a link connection into the network. You then have to negotiate a proper session and then handle the flows within the session itself. At each level there are different security controls that can govern the connections and protect the session information.<ref>{{cite book |last1=Buecker |first1=Axel |display-authors=et.al. |title=Reduce Risk and Improve Security on IBM Mainframes: Volume 2 Mainframe Communication and Networking Security |publisher=IBM Corporation |isbn=978-0738440941 |page=132 |date=2015 |url=https://books.google.com/books?id=ok2dCgAAQBAJ&pg=PA132 |access-date=April 23, 2019}}</ref>}}

==Network Addressable Units==
''Network Addressable Units'' in a SNA network are any components that can be assigned an address and can send and receive information. They are distinguished further as follows:<ref>{{citation |title=Basic SNA terms and concepts |url=https://www.ibm.com/docs/en/ztpf/2023?topic=communications-basic-sna-terms-concepts}}</ref>
* a ''System Services Control Point'' (SSCP) provides resource management and other session services (such as directory services) for users in a subarea network;<ref name="IBMSSCP">{{cite web |publisher=IBM Corporation |title=z/OS Communications Server: SNA Network Implementation Guide (6) |website=IBM Knowledge Center |url=http://www-01.ibm.com/support/knowledgecenter/#!/SSLTBW_2.1.0/com.ibm.zos.v2r1.istimp0/snnig6.htm |access-date=October 3, 2015}}</ref>
* a ''Physical Unit'' is a combination of hardware and software components that control the links to other nodes.<ref name="IBMPU">{{cite web |publisher=IBM Corporation |title=z/OS Communications Server: SNA Network Implementation Guide (11) |website=IBM Knowledge Center |date=September 11, 2014 |url=http://www-01.ibm.com/support/knowledgecenter/SSLTBW_2.1.0/com.ibm.zos.v2r1.istimp0/snnig11.htm?lang=en |access-date=October 3, 2015}}</ref>
* a ''Logical Unit'' acts as the intermediary between the user and the network.<ref name="IBMLU">{{cite web |publisher=IBM Corporation |title=z/OS Communications Server: SNA Network Implementation Guide (12) |website=IBM Knowledge Center |date=September 11, 2014 |url=http://www-01.ibm.com/support/knowledgecenter/SSLTBW_2.1.0/com.ibm.zos.v2r1.istimp0/snnig12.htm?lang=en |access-date=October 3, 2015}}</ref>

===Logical Unit (LU)===
SNA essentially offers transparent communication: equipment specifics that do not impose any constraints onto LU-LU communication. But eventually it serves a purpose to make a distinction between LU types, as the application must take the functionality of the terminal equipment into account (e.g. screen sizes and layout).

Within SNA there are three types of data stream to connect local display terminals and printers; there is SNA Character String (SCS), used for LU1 terminals and for logging on to an SNA network with Unformatted System Services (USS), there is the [[IBM 3270|3270]] [[IBM 3270#Data stream|data stream]] mainly used by mainframes such as the [[System/370]] and successors, including the [[zSeries]] family, and the [[IBM 5250|5250]] data stream mainly used by minicomputers/servers such as the [[System/34]], [[System/36]], [[System/38]], and [[AS/400]] and its successors, including System i and [[IBM Power Systems]] running [[IBM i]].

SNA defines several kinds of devices, called Logical Unit types:<ref>{{harv|Schatt|1991|p=229}}.</ref>
*LU0 provides for undefined devices, or build your own protocol. This is also used for non-SNA 3270 devices supported by [[Telecommunications Access Method|TCAM]] or VTAM.
*LU1 devices are printers or combinations of keyboards and printers.
*LU2 devices are IBM 3270 display terminals.
*LU3 devices are printers using 3270 protocols.
*LU4 devices are batch terminals.
*LU5 has never been defined.
*LU6 provides for protocols between two applications.
*LU7 provides for sessions with IBM 5250 terminals.
The primary ones in use are LU1, LU2, and [[LU6.2]] (an advanced protocol for application to application conversations).

===Physical Unit (PU)===<!-- IBM Network Control Program redirects here -->
*PU1 nodes are terminal controllers such as [[IBM 6670]] or [[IBM 3767]]
*PU2 nodes are cluster controllers running configuration support programs such as [[IBM 3270|IBM 3174]], [[IBM 3270|IBM 3274]], or the [[IBM 4701]] or [[IBM 4702]] Branch Controller
*PU2.1 nodes are [[peer-to-peer]] [[IBM Advanced Peer-to-Peer Networking|(APPN)]] nodes
*PU3 was never defined
*PU4 nodes are front-end processors running the [[IBM Network Control Program|Network Control Program]] (NCP) such as the [[IBM 37xx]] series
*PU5 nodes are host computer systems<ref>{{cite web |last=Microsoft |title=Physical Unit (PU) |url=http://msdn.microsoft.com/en-us/library/ee253218%28v=bts.10%29.aspx |access-date=September 7, 2012}}</ref>

The term [[37xx]] refers to IBM's family of SNA communications controllers. The 3745 supports up to eight high-speed [[Digital Signal 1|T1]] circuits, the 3725 is a large-scale node and [[front end processor|front-end processor]] for a host, and the [[IBM 3720|3720]] is a remote node that functions as a [[concentrator]] and [[router (computing)|router]].

==SNA over Token-Ring==
VTAM/NCP PU4 nodes attached to IBM [[Token Ring]] networks can share the same Local Area Network infrastructure with workstations and servers. NCP encapsulates SNA packets into Token-Ring frames, allowing sessions to flow over a Token-Ring network. The actual encapsulation and decapsulation takes place in the 3745.

==SNA over IP==
As mainframe-based entities looked for alternatives to their 37XX-based networks, IBM partnered with [[Cisco]] in the mid-1990s and together they developed [[Data Link Switching]], or DLSw. DLSw encapsulates SNA packets into IP datagrams, allowing sessions to flow over an IP network. The actual encapsulation and decapsulation takes place in Cisco routers at each end of a DLSw peer connection. At the local, or mainframe site, the router uses Token Ring topology to connect natively to VTAM. At the remote (user) end of the connection, a PU type 2 emulator (such as an SNA gateway server) connects to the peer router via the router's LAN interface. End user terminals are typically PCs with 3270 emulation software that is defined to the SNA gateway. The VTAM/NCP PU type 2 definition becomes a Switched Major Node that can be local to VTAM (without an NCP), and a "Line" connection can be defined using various possible solutions (such as a Token Ring interface on the 3745, a 3172 Lan Channel Station, or a Cisco [[ESCON]]-compatible Channel Interface Processor).

==Competitors==
The proprietary networking architecture for [[Honeywell Bull]] mainframes is [[Distributed Systems Architecture]] (DSA).<ref>{{cite web |title=Distributed Systems Architecture |url=http://www.feb-patrimoine.com/english/distributed_systems_arch.htm}}</ref> The Communications package for DSA is [[VIP terminal|VIP]]. DSA is also no longer supported for client access. Bull mainframes are fitted with [[Mainway]] for translating DSA to [[TCP/IP]] and VIP devices are replaced by TNVIP [[Terminal Emulations]] ([[GLink]], [[Winsurf]]). [[General Comprehensive Operating System|GCOS 8]] supports [[TNVIP SE]] over TCP/IP.

The networking architecture for [[Univac]] mainframes was the Distributed Computing Architecture (DCA), and the networking architecture for [[Burroughs Corporation|Burroughs]] mainframes was the Burroughs Network Architecture (BNA); after they merged to form [[Unisys]], both were provided by the merged company. Both were largely obsolete by 2012. [[International Computers Limited]] (ICL) provided its Information Processing Architecture (IPA).

[[DECnet]]<ref>{{cite magazine |magazine=[[Hardcopy (magazine) |Hardcopy]] |pages=62–65 |title=Giving DECnet a LAN |author1=James M. Moran |author2=Brian J. Edwards |date=February 1984}}</ref><ref>{{cite web |title=DECnet for Linux |publisher=[[SourceForge]] |url=http://sourceforge.net/apps/mediawiki/linux-decnet/index.php?title=Main_Page |access-date=June 26, 2018 |url-status=dead |archive-url=https://web.archive.org/web/20091004142729/http://sourceforge.net/apps/mediawiki/linux-decnet/index.php?title=Main_Page |archive-date=October 4, 2009}}</ref><ref>{{cite news |newspaper=[[The New York Times]] |title=Networking Products Introduced by Digital |date=August 24, 1988 |url=https://www.nytimes.com/1988/08/24/business/company-news-networking-products-introduced-by-digital.html}}</ref> is a suite of [[network protocol]]s created by [[Digital Equipment Corporation]], originally released in 1975 to connect two [[PDP-11]] [[minicomputers]]. It evolved into one of the first [[peer-to-peer]] network architectures, thus transforming DEC into a networking powerhouse in the 1980s.

SNA also competed with [[ISO]]'s [[Open Systems Interconnection]], which was an attempt to create a vendor-neutral network architecture that failed due to the problems of "[[design by committee]]".{{cn|date=January 2024}} OSI systems are very complex, and the many parties involved required extensive flexibilities that hurt the interoperability of OSI systems, which was the prime objective to start with.{{cn|date=January 2024}}

The TCP/IP suite for many years was not considered a serious alternative by IBM, due in part to the lack of control over the intellectual property.{{Citation needed|date=January 2019}} The 1988 publication of {{IETF RFC|1041}}, authored by [[Yakov Rekhter]], which defines an option to run [[IBM 3270]] sessions over [[Telnet]], explicitly recognizes the customer demand for interoperability in the data center. Subsequently, the IETF expanded on this work with multiple other RFCs. [[tn3270|TN3270]] (Telnet 3270), defined by those RFCs, supports direct client-server connections to the mainframe using a TN3270 server on the mainframe, and a TN3270 emulation package on the computer at the end user site. This protocol allows existing VTAM applications (CICS, TSO) to run with little or no change from traditional SNA by supporting traditional 3270 terminal protocol over the TCP/IP session. This protocol is widely used to replace legacy SNA connectivity more than [[Data-Link Switching]] (DLSw) and other SNA replacement technologies. A similar [[tn5250|TN5250]] (Telnet 5250) variant exists for the [[IBM 5250]].

==Non-IBM SNA implementations==
Non-IBM SNA software allowed systems other than IBM's to communicate with IBM's mainframes and [[AS/400]] midrange computers using the SNA protocols.

Some Unix system vendors, such as [[Sun Microsystems]] with its SunLink SNA product line, including PU2.1 Server,<ref>{{cite book |title=SunLink SNA 9.1 PU2.1 Server Configuration Guide |publisher=[[Sun Microsystems]] |date=1997 |url=https://docs.oracle.com/cd/E19246-01/802-2673/802-2673.pdf}}</ref> and [[Hewlett-Packard]]/[[Hewlett Packard Enterprise]], with their SNAplus2 product,<ref>{{cite web |title=HP-UX SNAplus2 Software - Overview |website=[[Hewlett Packard Enterprise |HPE]] support |url=https://support.hpe.com/hpesc/public/docDisplay?docId=emr_na-c02923531}}</ref> provided SNA software.

[[Microsoft]] introduced SNA Server for [[Windows]] in 1993;<ref>{{cite magazine |title=Microsoft, Novell, IBM target host-to-LAN links |first1=Shawn |last1=Willett |first2=Jayne |last2=Wilson |magazine=[[InfoWorld]] |volume=15 |issue=47 |page=39 |date=November 22, 1993 |url=https://books.google.com/books?id=ATsEAAAAMBAJ&pg=PA39}}</ref> it is now named [[Microsoft Host Integration Server]].

[[Digital Equipment Corporation]] had VMS/SNA for [[OpenVMS|VMS]].<ref name="vms-sna">{{cite web |title=Finding a DEC-to-IBM connection |first=Josh |last=Gonze |magazine=[[Network World]] |volume=5 |issue=17 |page=28 |quote=VMS/SNA, software that runs under VMS in conjunction with a synchronous board, in a VAX configured with a BIbus, makes a single VAX appear as a PU 2 node. |date=April 25, 1988 |url=https://books.google.com/books?id=IRIEAAAAMBAJ&pg=PA28}}</ref> Third-party SNA software packages for VMS, such as the VAX Link products from Systems Strategies, Inc.,<ref name="vms-sna" /> were also available.

Hewlett-Packard offered SNA Server and SNA Access for its [[HP 3000]] systems.<ref>{{cite magazine |title=Software offerings accompany Spectrum announcement |magazine=[[Computerworld]] |volume=20 |issue=9 |page=10 |quote=HP also unveiled IBM connection capabilities with Systems Network Architecture (SNA) Server and Server Access software. |date=March 3, 1986 |url=https://books.google.com/books?id=NeEyLTmpL_EC&pg=PA10}}</ref>

Brixton Systems developed several SNA software packages, sold under the name "{{visible anchor|Brixton}}",<ref name=RedHatBrixName>{{citation |title=Brixton SNA Server - Red Hat Certified Software |work=Red Hat Customer Portal |url=https://access.redhat.com/ecosystem/software/816733}}</ref><ref>{{cite news |magazine=[[Network World]] |title=CNT/Brixton Systems |date=July 31, 1995 |url=https://books.google.com/books?id=Fw8EAAAAMBAJ&pg=PA59}}</ref><ref>{{citation |title=Brixton PU2.1 SNA Server |url=https://www.lookupmainframesoftware.com/soft_detail/dispsoft/1929 |access-date=September 14, 2022}}</ref> such as Brixton BrxPU21, BrxPU5, BrxLU62, and BrxAPPC, for systems such as workstations from [[Hewlett-Packard]],<ref>{{cite magazine |title=Brixton turns HP workstations into mainframe alternatives |first=Michael |last=Cooney |magazine=[[Network World]] |volume=10 |issue=48 |page=15 |date=November 29, 1993 |url=https://books.google.com/books?id=2Q8EAAAAMBAJ&pg=PA15}}</ref> and [[Sun Microsystems]].<ref>{{cite magazine |title=Brixton expands IBM/Sun linkup |first=Kate |last=Orrange |magazine=[[InfoWorld]] |volume=14 |issue=10 |page=41 |date=March 9, 1992 |url=https://books.google.com/books?id=7j0EAAAAMBAJ&pg=PA41}}</ref>

IBM supported using several non-IBM software implementations of [[IBM Advanced Program-to-Program Communication|APPC/PU2.1/LU6.2]] to communicate with [[z/OS]], including SNAplus2 for systems from [[Hewlett-Packard|HP]],<ref>{{cite web |title=HP SNAplus2 Configuration Requirements |website=[[IBM]] |url=https://www.ibm.com/docs/en/connect-direct/6.0.0?topic=connections-hp-snaplus2-configuration-requirements}}</ref> Brixton 4.1 SNA for [[Oracle Solaris|Sun Solaris]],<ref name=BrixtonrefIBMcom>{{cite web |title=Brixton 4.1 SNA for Sun Solaris Requirements |website=[[IBM]] |url=https://www.ibm.com/docs/SS4PJT_6.0.0/cd_unix/cdunix_getstart/CDU_Brixton_4_1_SNA_for_Sun_Solaris_Reqs.html}}</ref> and SunLink SNA 9.1 Support for Sun Solaris.<ref>{{cite web |title=Configuring SunLink SNA 9.1 Support for Sun Solaris |website=[[IBM]] |url=https://www.ibm.com/docs/en/connect-direct/6.0.0?topic=connections-configuring-sunlink-sna-91-support-sun-solaris}}</ref>

==See also==
*[[Network Data Mover]]
*[[Protocol Wars]]
*[[TN3270]]
*[[TN5250]]
{{Clear}}

==Explanatory notes==
{{Notelist}}

==Notes==
{{Reflist|30em}}

==References==
*{{cite book |last1=Friend |first1=George E. |first2=John L. |last2=Fike |first3=H. Charles |last3=Baker |first4=John C. |last4=Bellamy |title=Understanding Data Communications |edition=2nd |year=1988 |publisher=Howard W. Sams & Company |location=Indianapolis |isbn=0-672-27270-9}}
*{{cite book |last1=Pooch |first1=Udo W. |first2=William H. |last2=Greene |first3=Gary G. |last3=Moss |title=Telecommunications and Networking |publisher=Little, Brown and Company |location=Boston |year=1983 |isbn=0-316-71498-4}}
*{{cite book |last=Schatt |first=Stan |title=Linking LANs: A Micro Manager's Guide |year=1991 |publisher=McGraw-Hill |isbn=0-8306-3755-9}}
*{{cite book |title=Systems Network Architecture General Information |version=First Edition |publisher=IBM |id=GA27-3102-0 |ref=GA27-3102-0 |date=January 1975 |url=https://bitsavers.org/pdf/ibm/sna/GA27-3102-0_SNA_General_Information_Jan75.pdf}}
*{{cite book |title=Systems Network Architecture Concepts and Products |version=Second Edition |publisher=IBM |id=GC30-3072-1 |ref=GC30-3072-1 |date=February 1984 |url=https://bitsavers.org/pdf/ibm/sna/GC30-3072-1_SNA_Concepts_and_Products_Feb84.pdf}}
*{{cite book |title=Systems Network Architecture Technical Overview |version=Fifth Edition |publisher=IBM |id=GC30-3073-04 |ref=GC30-3073-04 |date=January 1994 |url=http://publibfp.dhe.ibm.com/cgi-bin/bookmgr/BOOKS/D50D1001/CCONTENTS}}
*{{cite book |title=Systems Network Architecture Guide to SNA Publications |version=Third Edition |publisher=IBM |id=GC30-3438-02 |ref=GC30-3438-02 |date=July 1994 |url=http://publibfp.dhe.ibm.com/cgi-bin/bookmgr/FRAMESET/D50A1600/CCONTENTS}}

==External links==
*[http://docwiki.cisco.com/wiki/IBM_Systems_Network_Architecture_Protocols Cisco article on SNA]
*[http://www.networking.ibm.com/app/aiwhome.htm APPN Implementers Workshop] Architecture Document repository
*[http://www.protocols.com/pbook/sna SNA protocols] quite technical
*[http://www.sdsusa.com/resources/whitepapers/ Related whitepapers] sdsusa.com
*{{cite book |title=Advanced Function for Communications System Summary |version=Second Edition |publisher=IBM |id=GA27-3099-1 |date=July 1975 |url=https://bitsavers.org/pdf/ibm/sna/GA27-3099-1_Advanced_Functions_for_Communications_System_Summary_Jul75.pdf |access-date=May 22, 2014}}
*{{cite book |title=Systems Network Architecture Formats |version=Twenty-first Edition |publisher=IBM |id=GA27-3136-20 |date=March 2004 |url=https://publibfp.dhe.ibm.com/epubs/pdf/d50a5007.pdf}}
*{{cite book |title=Systems Network Architecture - Sessions Between Logical Units |version=Third Edition |publisher=IBM |id=GC20-1868-2 |date=April 1981 |url=https://bitsavers.org/pdf/ibm/sna/GC20-1868-2_SNA_Sessions_Between_Logical_Units_Apr81.pdf}}
*{{cite book |title=Systems Network Architecture - Introduction to Sessions between Logical Units |version=Third Edition |publisher=IBM |id=GC20-1869-2 |date=December 1979 |url=https://bitsavers.org/pdf/ibm/sna/GC20-1869-2_SNA_Introduction_to_Sessions_Between_Logical_Units_Dec79.pdf}}
*{{cite book |title=Systems Network Architecture Format and Protocol Reference Manual: Architectural Logic |version=Third Edition |publisher=IBM |id=SY20-3112-2 |date=November 1980 |url=https://bitsavers.org/pdf/ibm/sna/SY20-3112-2_System_Network_Architecture_Format_and_Protocol_Reference_Manual_Architectural_Logic_Nov1980.pdf}}
*{{cite book |title=Systems Network Architecture: Transaction Programmer's Reference Manual for LU Type 6.2 |version=Sixth Edition |publisher=IBM |id=GC30-3084-05 |date=June 1993 |url=http://publibfp.dhe.ibm.com/cgi-bin/bookmgr/FRAMESET/D50A3100/CCONTENTS}}
*{{cite book |title=Systems Network Architecture Type 2.1 Node Reference |version=Fifth Edition |publisher=IBM |id=SC30-3422-04 |date=December 1996 |url=http://publibfp.dhe.ibm.com/cgi-bin/bookmgr/BOOKS/d50l0000}}
*{{cite book |title=Systems Network Architecture LU 6.2 Reference: Peer Protocols |version=Third Edition |publisher=IBM |id=SC31-6808-02 |date=October 1996 |url=http://publibfp.dhe.ibm.com/cgi-bin/bookmgr/BOOKS/D50A3001/CCONTENTS}}

{{Authority control}}
[[Category:Systems Network Architecture| ]]
[[Category:Network protocols|IBM Systems Network Architecture]]
[[Category:IBM operating systems]]