IBM BC-203 Resolving Differences in LLC2 and Sdlc Frame Size, Maintaining a Dynamic RIF Cache

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Overview of IBM Networking

IBM Network Media Translation

As part of its virtual telecommunications access method (VTAM) configuration, the IBM node on the Token Ring has knowledge of the SDLLC VTRA of the serial device with which it communicates. The SDLC VTRA and the SDLLC virtual ring number are a part of the SDLLC configuration for the router’s serial interface. When the Token Ring host sends out explorer packets with the SDLLC VTRA as the destination address in the MAC headers, the router configured with that SDLLC VTRA intercepts the frame, fills in the SDLLC virtual ring number address and the bridge number in the RIF, then sends the response back to the Token Ring host. A route is then established between the Token Ring host and the router. After the Cisco IOS software performs the appropriate frame conversion, the system uses this route to forward frames to the serial device.

Resolving Differences in LLC2 and SDLC Frame Size

IBM nodes on Token Ring media normally use frame sizes greater than 1 KB, whereas the IBM nodes on serial lines normally limit frame sizes to 265 or 521 bytes. To reduce traffic on backbone networks and provide better performance, Token Ring nodes should send frames that are as large as possible. As part of the SDLLC configuration on the serial interface, the largest frame size the two media can support should be selected. The Cisco IOS software can fragment the frames it receives from the Token Ring device before forwarding them to the SDLC device, but it does not assemble the frames it receives from the serial device before forwarding them to the Token Ring device.

Maintaining a Dynamic RIF Cache

SDLLC maintains a dynamic RIF cache and caches the entire RIF; that is, the RIF from the source station to destination station. The cached entry is based on the best path at the time the session begins. SDLLC uses the RIF cache to maintain the LLC2 session between the router and the host FEP. SDLLC does not age these RIF entries. Instead, SDLLC places an entry in the RIF cache for a session when the session begins and flushes the cache when the session terminates. You cannot flush these RIFs because if you flush the RIF entries randomly, the Cisco IOS software cannot maintain the LLC2 session to the host FEP.

Other Considerations

The following are additional facts regarding SDLC and SDLLC:

As part of Cisco’s SDLC implementation, only modulus 8 Normal Response Mode (NRM) sessions are maintained for the SDLC session.

SDLC sessions are always locally acknowledged. LLC2 sessions can be optionally configured for local acknowledgment.

SDLLC does not apply to SNA subarea networks, such as 37x5 FEP-to-37x5 FEP communication.

Parameters such as the maximum number of information frames (I-frames) outstanding before acknowledgment, frequency of polls, and response time to poll frames can be modified per interface. If local acknowledgment is not enabled, these parameters are modified on the SDLC interface. If local acknowledgment is enabled, these parameters are modified on the Token Ring interface.

Local acknowledgment only applies when the remote peer is defined for RSRB using IP encapsulation over a TCP connection. If no local acknowledgment is used, the remote peer can be defined for RSRB using direct encapsulation, RSRB using IP encapsulation over an FST connection, or RSRB using IP encapsulation over a TCP connection.

Cisco IOS Bridging and IBM Networking Configuration Guide

BC-221

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Contents BC-203 Overview of IBM NetworkingBC-204 RsrbBC-205 Configuration ConsiderationsBC-206 DLSw+DLSw Version 2 Standard DLSw StandardBC-207 UDP Unicast DLSw+ FeaturesEnhanced Peer-on-Demand Routing Feature IP MulticastBC-209 Local AcknowledgmentLLC2 Session Without Local Acknowledgment BC-210BC-211 BC-212 DLSw+ Support for Other SNA FeaturesStun Networks Stun and BstunBC-213 BC-214 Stun FeaturesBC-215 Stun BC-216BC-217 Bstun FeaturesLLC2 and Sdlc Parameters Bstun NetworksBC-218 Cisco’s Implementation of LLC2Cisco’s Implementation of Sdlc IBM Network Media TranslationBC-219 Virtual Token Ring Concept Sdllc Media Translation FeaturesBC-220 BC-221 Resolving Differences in LLC2 and Sdlc Frame SizeMaintaining a Dynamic RIF Cache Other ConsiderationsBC-222 Qllc ConversionBC-223 Cisco’s Implementation of Qllc ConversionBC-224 Comparing Qllc Conversion to SdllcBC-225 Other Implementation ConsiderationsBC-226 RFC 1490 Routed Format for LLC2 BNNBC-227 RFC 1490 Bridged Format for LLC2 BANNcia BC-228Ncia Client/Server Model Ncia ServerBC-229 Ncia Server Client/Server Model BC-230BC-231 Advantages of the Client/Server ModelExtended Scalability Migration SupportAlps BC-232BC-233 Dspu and SNA Service PointRouter Acting as a Dspu Concentrator BC-234Benefits of SNASw SNA Switching ServicesBC-235 Network Design Simplicity Reduced Configuration RequirementsScalable Appn Networks IP Infrastructure SupportBranch Extender HPR Capable SNA Routing ServicesBC-237 BC-238 Enterprise Extender HPR/IPDlur Connect-Out Usability FeaturesDynamic CP Name Generation Support Dynamic SNA BTU SizeManagement Enhancements Virtual Token Ring LAN and IP-Focused Connection TypesTrap MIB Support for Advanced Network Management Awareness Token Ring, Ethernet, and FddiNative IP Data-Link Control HPR/IP DLC Switching Support for Access to Sdlc and QllcCisco Transaction Connection Virtual Data-Link ControlBC-243 Ctrc and CicsBC-244 Ctrc and DB2Benefits of Ctrc Cmcc Adapter HardwareBC-245 Channel Port Adapter Channel Interface ProcessorBC-246 BC-247 Differences between the CIP and CPAEscon Channel Port Adapter Parallel Channel Port AdapterTCP/IP Offload Cmcc Adapter Features for TCP/IP EnvironmentsCommon Link Access to Workstation Supported EnvironmentsCisco Multipath Channel+ IP Host BackupBC-249 Cisco SNA Cmcc Adapter Features for SNA EnvironmentsBC-250 TN3270 Server Cisco Multipath ChannelBC-251 Telnet Server Functions SNA FunctionsBC-252 BC-253 BC-254