IBM BC-201 manual DLSw Standard, DLSw Version 2 Standard, BC-205

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Overview of IBM Networking

DLSw+

This section contains a brief overview of DLSw+:

DLSw Standard, page 205

DLSw Version 2 Standard, page 205

DLSw+ Features, page 206

DLSw Standard

The DLSw standard, documented in RFC 1795, defines the switch-to-switch protocol between DLSw routers. The standard also defines a mechanism to terminate data-link control connections locally and multiplex the traffic from the data-link control connections to a TCP connection. The standard always calls for the transport protocol to be TCP and always requires that data-link control connections be locally terminated (the equivalent of the Cisco local acknowledgment option). The standard also requires that the SRB RIF be terminated at the DLSw router. The standard describes a means for prioritization and flow control and defines error recovery procedures that ensure data-link control connections are appropriately disabled if any part of their associated circuits breaks.

The DLSw standard does not specify when to establish TCP connections. The capabilities exchange allows compliance to the standard, but at different levels of support. The standard does not specify how to cache learned information about MAC addresses, RIFs, or NetBIOS names. It also does not describe how to track either capable or preferred DLSw partners for either backup or load-balancing purposes.The standard does not provide the specifics of media conversion, but leaves the details up to the implementation. It does not define how to map switch congestion to the flow control for data-link control. Finally, the MIB is documented under a separate RFC.

DLSw Version 2 Standard

In the Version 1 standard, a network design requires fully meshed connectivity so that all peers were connect to every other peer. This design creates unnecessary broadcast traffic because an explorer propagates to every peer for every broadcast.

The Version 2 standard is documented in RFC 2166. It includes RFC 1795 and adds the following enhancements:

IP Multicast, page 206

UDP Unicast, page 206

Enhanced Peer-on-Demand Routing Feature, page 206

Expedited TCP Connection, page 206

Users implement DLSw+ Version 2 for scalability if they are using multivendor DLSw devices with an IP multicast network. DLSw Version 2 requires complex planning because it involves configuration changes across an IP network.

 

 

Cisco IOS Bridging and IBM Networking Configuration Guide

 

 

 

 

 

 

 

78-11737-02

 

 

BC-205

 

 

 

 

 

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Contents BC-201 Overview of IBM NetworkingBC-202 RsrbBC-203 Configuration ConsiderationsBC-204 DLSw+BC-205 DLSw StandardDLSw Version 2 Standard Enhanced Peer-on-Demand Routing Feature DLSw+ FeaturesIP Multicast UDP UnicastBC-207 Local AcknowledgmentLLC2 Session Without Local Acknowledgment BC-208BC-209 BC-210 DLSw+ Support for Other SNA FeaturesBC-211 Stun and BstunStun Networks BC-212 Stun FeaturesBC-213 Stun BC-214LLC2 and Sdlc Parameters Bstun FeaturesBstun Networks BC-215BC-216 Cisco Implementation of LLC2BC-217 IBM Network Media TranslationCisco Implementation of Sdlc BC-218 Sdllc Media Translation FeaturesVirtual Token Ring Concept Maintaining a Dynamic RIF Cache Resolving Differences in LLC2 and Sdlc Frame SizeOther Considerations BC-219BC-220 Qllc ConversionBC-221 Cisco Implementation of Qllc ConversionBC-222 Comparing Qllc Conversion to SdllcBC-223 Other Implementation ConsiderationsBC-224 RFC 1490 Routed Format for LLC2 BNNBC-225 RFC 1490 Bridged Format for LLC2 BANBC-226 Ncia ServerBC-227 Ncia Client/Server ModelBC-228 Advantages of the Client/Server ModelExtended Scalability BC-229 Migration SupportBC-230 Dspu and SNA Service PointBC-231 Shows a router functioning as a Dspu concentratorBC-232 SNA Switching ServicesBenefits of SNASw Scalable Appn Networks Reduced Configuration RequirementsIP Infrastructure Support Network Design SimplicityBC-234 HPR Capable SNA Routing ServicesBranch Extender BC-235 Enterprise Extender HPR/IPResponsive Mode Adaptive Rate-Based Flow Control Usability FeaturesDynamic CP Name Generation Support Dynamic SNA BTU SizeManagement Enhancements Interprocess Signal TracingUser-Settable Port Limits Console Message ArchivingMIB Support for Advanced Network Management Awareness LAN and IP-Focused Connection TypesToken Ring, Ethernet, and Fddi Virtual Token RingNative IP Data-Link Control HPR/IP Cisco Transaction ConnectionVirtual Data-Link Control BC-240 Ctrc and CicsBC-241 Ctrc and DB2BC-242 Cmcc Adapter HardwareBenefits of Ctrc BC-243 Channel Interface ProcessorChannel Port Adapter Escon Channel Port Adapter Differences Between the CIP and CPAParallel Channel Port Adapter BC-244Common Link Access to Workstation Cmcc Adapter Features for TCP/IP EnvironmentsSupported Environments TCP/IP OffloadBC-246 IP Host BackupCisco Multipath Channel+ BC-247 Cmcc Adapter Features for SNA EnvironmentsCisco SNA BC-248 Cisco Multipath ChannelTN3270 Server BC-249 SNA FunctionsTelnet Server Functions BC-250
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