📄 rfc1538.txt
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RFC 1538 Advanced SNA/IP October 1993 Transfer frames are shown below. ------------------------------------------------------- | IP Header | TCP Header | SNA Msg 1 len | SNA Msg 1 | ------------------------------------------------------- ---------------------------------------------- | IP Header | TCP Header | SNA Msg 1 cont'd -> ---------------------------------------------- -------------------------------- | SNA Msg 2 len | SNA Msg 2 | -------------------------------- The length field is passed in big endian format. 0 is a valid length value. The format of the SNA Message pieces are as defined by SNA [3]. Reliable and sequential delivery of data is provided by the TCP protocol [5,6].3.3.3. Connection Termination and Loss Either SNA node may, at any time, terminate the logical SNA connection by issuing a TCP-level FIN segment. Dictates of the TCP protocol apply to this termination process [5,6]. A connection is also terminated, though not as cleanly, if a TCP Reset segment is sent by either SNA node. Once a connection is terminated, a new connection may be established by the process outlined in the Connection Establishment section. For reconnections made to the LinkMaster 6200 gateway, the same UDP source port must be used by the initiating node. This implies that the same TCP port is used. This requirement stems from the fact the gateway may not always be aware that a TCP connection has been terminated. This would happen if the DSN became disabled prior to sending a FIN or Reset segment. Under these circumstances, SNA host resources remain allocated and a reconnection from a DSN, which the host believes to already be in session, is not allowed. By requiring the DSN to use the same port when reestablishing a connection, the LinkMaster 6200 is able to recognize when a reset of the host connection is required.Behl, Sterling & Teskey [Page 6]
RFC 1538 Advanced SNA/IP October 19933.3.4. Complete Session Data Flow Node 1 Node 2 Logical Null XID -------------------------> (UDP Datagram) Logical Null XID -------------------------> (UDP Datagram) <------------------------ XID Request (UDP Datagram) Logical SNA XID --------------------------> (UDP Datagram) <------------------------ TCP SYN (TCP Message) TCP SYN ACK -----------------------------> (TCP Message) <------------------------ TCP SYN (TCP Message) ****************** Connection Established ******************* <------------------------ SNA ACTPU (TCP Message) SNA ACTPU Response ---------------------> (TCP Message) <------------------------ SNA ACTLU (TCP Message) SNA ACTLU Response ---------------------> (TCP Message) . . . <------------------------ TCP FIN (TCP Message) TCP FIN ACK ------------------------> (TCP Message) <------------------------ TCP ACK (TCP Message) ******************** Connection Closed ********************* Logical Null XID -----------------------> (UDP Datagram) . . . .Behl, Sterling & Teskey [Page 7]
RFC 1538 Advanced SNA/IP October 19933.3.5. State Transition Table for the Initiating Node Transition State Given State | No Conn | Null XID Sent | SNA XID Sent | Conn Estb ------------+---------+---------------+--------------+----------- No | | Internal Act. | | Connection | | Stimulus | | | | ---> Sends | | | | 1st Null XID | | ------------+---------+---------------+--------------+----------- Null XID | | Internal | XID Request | Sent | | Timer Event | Received | | | ----> Resend | ----> Sends | | | Null XID | SNA XID | ------------+---------+---------------+--------------+----------- SNA XID | | Internal | SNA XID | Indication Sent | | Timer Event | Received | that TCP | | ----> Resend | ----> Send | connection | | Null XID | SNA XID | is estb. | | | | ------------+---------+---------------+--------------+----------- Connection | Indica- | | | SNA Established | tion | | | Session | that | | | Data | TCP conn| | | | term. | | | A gateway state transition table is not provided here because the state transitions are dependent on the nature of the SNA host interface (3172 Channel Protocol, 3174 Channel Protocol, SDLC, etc.).4. LLC to SNA/IP Conversion The use of Advanced SNA/IP to convert conventional token ring- based SNA traffic to a routable form is both conceivable and practical. While interesting, a discussion of this application falls outside the context of this RFC. Very briefly, it can be said that an SNA/IP- based "subnet SNA gateway" application could do many of the things being discussed in the context of the DLSw specification [1].5. Performance The performance of SNA sessions running over an SNA/IP connection will be affected by the bandwidth available on the network and by how much traffic is on the network. SNA/IP is poised to take full advantage of the prioritization and class of service enhancements promised in the next generation of IP. Today, SNA/IP can takeBehl, Sterling & Teskey [Page 8]
RFC 1538 Advanced SNA/IP October 1993 advantage of router packet prioritization schemes based on port number. SNA/IP also leaves intact the standard SNA class of service prioritization protocol. Performance measures taken at McDATA comparing the throughput of SNA/IP and LLC across a single token-ring segment showed approximately a 15 percent decrease in the maximum transactions per hour (1500 bytes to the DSN, 50 bytes out to the host) for SNA/IP. This decrease is well within the expected levels given the added processing requirements of TCP/IP over LLC in the LinkMaster 6200 and LinkMaster 7100 operating environments.6. VTAM Definition The host VTAM definition of SNA/IP downstream nodes is dependent on the gateway implementation. Downstream nodes may appear as switched major nodes connected to an XCA or as downstream nodes connected to a PU 2.0 controller [4].7. Acknowledgments The authors wish to acknowledge that the definition of SNA/IP was a collaborative effort involving many individuals ranging from customers to sales and marketing personnel to engineers. Particular thanks go to David Beal, Steve Cartwright, Tracey Floming, Audrey McEwen, Mark Platte, Paul Schroeder, Chuck Weil, and Marty Wright, who all played key roles in the development and testing of this protocol and also in the editing of this RFC.8. References [1] Dixon, R., and D. Kushi, "Data Link Switching: Switch-to-Switch Protocol", RFC 1434, IBM, March 1993. [2] "Token-Ring Network Architecture Reference", IBM document #SC30- 3374-02. [3] "Systems Network Architecture Formats", IBM document #GA27-3136- 12. [4] "VTAM Resource Definition Reference", IBM document #SC31-6438-1. [5] Comer, D., "Internetworking with TCP/IP Volume I", Prentice Hall 1991. [6] Postel, J., "Transmission Control Protocol - DARPA Internet Program Protocol Specification", STD 7, RFC 793, USC/Information Sciences Institute, September 1981.Behl, Sterling & Teskey [Page 9]
RFC 1538 Advanced SNA/IP October 19939. Security Considerations This RFC does not address issues of security. SNA level security procedures and protocols apply when SNA/IP is used as the transport.10. Authors' Addresses Wilfred Behl 310 Interlocken Parkway Broomfield, Colorado 80021 Phone: 303-460-4142 Email: wil@mcdata.com Barbara Sterling 310 Interlocken Parkway Broomfield, Colorado 80021 Phone: 303-460-4211 Email: bjs@mcdata.com William Teskey 2125 112th Ave. North East Suite 303 Bellevue, WA 98004 Phone: 206-450-0650 Email: wct@ioc-sea.com Note: Any questions or comments relative to the contents of this RFC should be sent to snaip@mcdata.com. This address will be used to coordinate the handling of responses.11. Disclaimer McDATA, the McDATA logo, and LinkMaster are registered trademarks of McDATA Corporation. All other product names and identifications are trademarks of their respective manufacturers, who are not affiliated with McDATA Corporation.Behl, Sterling & Teskey [Page 10]
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