From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc2353.txt | 2691 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 2691 insertions(+) create mode 100644 doc/rfc/rfc2353.txt (limited to 'doc/rfc/rfc2353.txt') diff --git a/doc/rfc/rfc2353.txt b/doc/rfc/rfc2353.txt new file mode 100644 index 0000000..ead46fb --- /dev/null +++ b/doc/rfc/rfc2353.txt @@ -0,0 +1,2691 @@ + + + + + + +Network Working Group G. Dudley +Request for Comments: 2353 IBM +Category: Informational May 1998 + + + APPN/HPR in IP Networks + APPN Implementers' Workshop Closed Pages Document + +Status of this Memo + + This memo provides information for the Internet community. It does + not specify an Internet standard of any kind. Distribution of this + memo is unlimited. + +Copyright Notice + + Copyright (C) The Internet Society (1998). All Rights Reserved. + +Table of Contents + + 1.0 Introduction . . . . . . . . . . . . . . . . . . . . . . . 2 + 1.1 Requirements . . . . . . . . . . . . . . . . . . . . . . . 3 + 2.0 IP as a Data Link Control (DLC) for HPR . . . . . . . . . 3 + 2.1 Use of UDP and IP . . . . . . . . . . . . . . . . . . . . 4 + 2.2 Node Structure . . . . . . . . . . . . . . . . . . . . . . 5 + 2.3 Logical Link Control (LLC) Used for IP . . . . . . . . . . 8 + 2.3.1 LDLC Liveness . . . . . . . . . . . . . . . . . . . . 8 + 2.3.1.1 Option to Reduce Liveness Traffic . . . . . . . . 9 + 2.4 IP Port Activation . . . . . . . . . . . . . . . . . . . . 10 + 2.4.1 Maximum BTU Sizes for HPR/IP . . . . . . . . . . . . . 12 + 2.5 IP Transmission Groups (TGs) . . . . . . . . . . . . . . . 12 + 2.5.1 Regular TGs . . . . . . . . . . . . . . . . . . . . . 12 + 2.5.1.1 Limited Resources and Auto-Activation . . . . . . 19 + 2.5.2 IP Connection Networks . . . . . . . . . . . . . . . . 19 + 2.5.2.1 Establishing IP Connection Networks . . . . . . . 20 + 2.5.2.2 IP Connection Network Parameters . . . . . . . . . 22 + 2.5.2.3 Sharing of TGs . . . . . . . . . . . . . . . . . . 24 + 2.5.2.4 Minimizing RSCV Length . . . . . . . . . . . . . . 25 + 2.5.3 XID Changes . . . . . . . . . . . . . . . . . . . . . 26 + 2.5.4 Unsuccessful IP Link Activation . . . . . . . . . . . 30 + 2.6 IP Throughput Characteristics . . . . . . . . . . . . . . 34 + 2.6.1 IP Prioritization . . . . . . . . . . . . . . . . . . 34 + 2.6.2 APPN Transmission Priority and COS . . . . . . . . . . 36 + 2.6.3 Default TG Characteristics . . . . . . . . . . . . . . 36 + 2.6.4 SNA-Defined COS Tables . . . . . . . . . . . . . . . . 38 + 2.6.5 Route Setup over HPR/IP links . . . . . . . . . . . . 39 + 2.6.6 Access Link Queueing . . . . . . . . . . . . . . . . . 39 + 2.7 Port Link Activation Limits . . . . . . . . . . . . . . . 40 + + + +Dudley Informational [Page 1] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + 2.8 Network Management . . . . . . . . . . . . . . . . . . . . 40 + 2.9 IPv4-to-IPv6 Migration . . . . . . . . . . . . . . . . . . 41 + 3.0 References . . . . . . . . . . . . . . . . . . . . . . . . 42 + 4.0 Security Considerations . . . . . . . . . . . . . . . . . 43 + 5.0 Author's Address . . . . . . . . . . . . . . . . . . . . . 44 + 6.0 Appendix - Packet Format . . . . . . . . . . . . . . . . . 45 + 6.1 HPR Use of IP Formats . . . . . . . . . . . . . . . . . . 45 + 6.1.1 IP Format for LLC Commands and Responses . . . . . . . 45 + 6.1.2 IP Format for NLPs in UI Frames . . . . . . . . . . . 46 + 7.0 Full Copyright Statement . . . . . . . . . . . . . . . . . 48 + +1.0 Introduction + + The APPN Implementers' Workshop (AIW) is an industry-wide consortium + of networking vendors that develops Advanced Peer-to-Peer + Networking(R) (APPN(R)) standards and other standards related to + Systems Network Architecture (SNA), and facilitates high quality, + fully interoperable APPN and SNA internetworking products. The AIW + approved Closed Pages (CP) status for the architecture in this + document on December 2, 1997, and, as a result, the architecture was + added to the AIW architecture of record. A CP-level document is + sufficiently detailed that implementing products will be able to + interoperate; it contains a clear and complete specification of all + necessary changes to the architecture of record. However, the AIW + has procedures by which the architecture may be modified, and the AIW + is open to suggestions from the internet community. + + The architecture for APPN nodes is specified in "Systems Network + Architecture Advanced Peer-to-Peer Networking Architecture Reference" + [1]. A set of APPN enhancements for High Performance Routing (HPR) + is specified in "Systems Network Architecture Advanced Peer-to-Peer + Networking High Performance Routing Architecture Reference, Version + 3.0" [2]. The formats associated with these architectures are + specified in "Systems Network Architecture Formats" [3]. This memo + assumes the reader is familiar with these specifications. + + This memo defines a method with which HPR nodes can use IP networks + for communication, and the enhancements to APPN required by this + method. This memo also describes an option set that allows the use + of the APPN connection network model to allow HPR nodes to use IP + networks for communication without having to predefine link + connections. + + (R) 'Advanced Peer-to-Peer Networking' and 'APPN' are trademarks of + the IBM Corporation. + + + + + + +Dudley Informational [Page 2] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + +1.1 Requirements + + The following are the requirements for the architecture specified in + this memo: + + 1. Facilitate APPN product interoperation in IP networks by + documenting agreements such as the choice of the logical link + control (LLC). + + 2. Reduce system definition (e.g., by extending the connection + network model to IP networks) -- Connection network support is an + optional function. + + 3. Use class of service (COS) to retain existing path selection and + transmission priority services in IP networks; extend + transmission priority function to include IP networks. + + 4. Allow customers the flexibility to design their networks for low + cost and high performance. + + 5. Use HPR functions to improve both availability and scalability + over existing integration techniques such as Data Link Switching + (DLSw) which is specified in RFC 1795 [4] and RFC 2166 [5]. + +2.0 IP as a Data Link Control (DLC) for HPR + + This memo specifies the use of IP and UDP as a new DLC that can be + supported by APPN nodes with the three HPR option sets: HPR (option + set 1400), Rapid Transport Protocol (RTP) (option set 1401), and + Control Flows over RTP (option set 1402). Logical Data Link Control + (LDLC) Support (option set 2006) is also a prerequisite. + + RTP is a connection-oriented, full-duplex protocol designed to + transport data in high-speed networks. HPR uses RTP connections to + transport SNA session traffic. RTP provides reliability (i.e., error + recovery via selective retransmission), in-order delivery (i.e., a + first-in-first-out [FIFO] service provided by resequencing data that + arrives out of order), and adaptive rate-based (ARB) flow/congestion + control. Because RTP provides these functions on an end-to-end basis, + it eliminates the need for these functions on the link level along + the path of the connection. The result is improved overall + performance for HPR. For a more complete description of RTP, see + Appendix F of [2]. + + This new DLC (referred to as the native IP DLC) allows customers to + take advantage of APPN/HPR functions such as class of service (COS) + and ARB flow/congestion control in the IP environment. HPR links + established over the native IP DLC are referred to as HPR/IP links. + + + +Dudley Informational [Page 3] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + The following sections describe in detail the considerations and + enhancements associated with the native IP DLC. + +2.1 Use of UDP and IP + + The native IP DLC will use the User Datagram Protocol (UDP) defined + in RFC 768 [6] and the Internet Protocol (IP) version 4 defined in + RFC 791 [7]. + + Typically, access to UDP is provided by a sockets API. UDP provides + an unreliable connectionless delivery service using IP to transport + messages between nodes. UDP has the ability to distinguish among + multiple destinations within a given node, and allows port-number- + based prioritization in the IP network. UDP provides detection of + corrupted packets, a function required by HPR. Higher-layer + protocols such as HPR are responsible for handling problems of + message loss, duplication, delay, out-of-order delivery, and loss of + connectivity. UDP is adequate because HPR uses RTP to provide end- + to-end error recovery and in-order delivery; in addition, LDLC + detects loss of connectivity. The Transmission Control Protocol + (TCP) was not chosen for the native IP DLC because the additional + services provided by TCP such as error recovery are not needed. + Furthermore, the termination of TCP connections would require + additional node resources (control blocks, buffers, timers, and + retransmit queues) and would, thereby, reduce the scalability of the + design. + + The UDP header has four two-byte fields. The UDP Destination Port is + a 16-bit field that contains the UDP protocol port number used to + demultiplex datagrams at the destination. The UDP Source Port is a + 16-bit field that contains the UDP protocol port number that + specifies the port to which replies should be sent when other + information is not available. A zero setting indicates that no + source port number information is being provided. When used with the + native IP DLC, this field is not used to convey a port number for + replies; moreover, the zero setting is not used. IANA has registered + port numbers 12000 through 12004 for use in these two fields by the + native IP DLC; use of these port numbers allows prioritization in the + IP network. For more details of the use of these fields, see 2.6.1, + "IP Prioritization" on page 28. + + The UDP Checksum is a 16-bit optional field that provides coverage of + the UDP header and the user data; it also provides coverage of a + pseudo-header that contains the source and destination IP addresses. + The UDP checksum is used to guarantee that the data has arrived + intact at the intended receiver. When the UDP checksum is set to + + + + + +Dudley Informational [Page 4] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + zero, it indicates that the checksum was not calculated and should + not be checked by the receiver. Use of the checksum is recommended + for use with the native IP DLC. + + IP provides an unreliable, connectionless delivery mechanism. The IP + protocol defines the basic unit of data transfer through the IP + network, and performs the routing function (i.e., choosing the path + over which data will be sent). In addition, IP characterizes how + "hosts" and "gateways" should process packets, the circumstances + under which error messages are generated, and the conditions under + which packets are discarded. An IP version 4 header contains an 8- + bit Type of Service field that specifies how the datagram should be + handled. As defined in RFC 1349 [8], the type-of-service byte + contains two defined fields. The 3-bit precedence field allows + senders to indicate the priority of each datagram. The 4-bit type of + service field indicates how the network should make tradeoffs between + throughput, delay, reliability, and cost. The 8-bit Protocol field + specifies which higher-level protocol created the datagram. When + used with the native IP DLC, this field is set to 17 which indicates + the higher-layer protocol is UDP. + +2.2 Node Structure + + Figure 1 on page 6 shows a possible node functional decomposition for + transport of HPR traffic across an IP network. There will be + variations in different platforms based on platform characteristics. + + The native IP DLC includes a DLC manager, one LDLC component for each + link, and a link demultiplexor. Because UDP is a connectionless + delivery service, there is no need for HPR to activate and deactivate + lower-level connections. + + The DLC manager activates and deactivates a link demultiplexor for + each port and an instance of LDLC for each link established in an IP + network. Multiple links (e.g., one defined link and one dynamic link + for connection network traffic) may be established between a pair of + IP addresses. Each link is identified by the source and destination + IP addresses in the IP header and the source and destination service + access point (SAP) addresses in the IEEE 802.2 LLC header (see 6.0, + "Appendix - Packet Format" on page 37); the link demultiplexor passes + incoming packets to the correct instance of LDLC based on these + identifiers. Moreover, the IP address pair associated with an active + link and used in the IP header may not change. + + LDLC also provides other functions (for example, reliable delivery of + Exchange Identification [XID] commands). Error recovery for HPR RTP + packets is provided by the protocols between the RTP endpoints. + + + + +Dudley Informational [Page 5] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + The network control layer (NCL) uses the automatic network routing + (ANR) information in the HPR network header to either pass incoming + packets to RTP or an outgoing link. + + All components are shown as single entities, but the number of + logical instances of each is as follows: + + o DLC manager -- 1 per node + + o LDLC -- 1 per link + + o Link demultiplexor -- 1 per port + + o NCL -- 1 per node (or 1 per port for efficiency) + + o RTP -- 1 per RTP connection + + o UDP -- 1 per port + + o IP -- 1 per port + + Products are free to implement other structures. Products + implementing other structures will need to make the appropriate + modifications to the algorithms and protocol boundaries shown in this + document. + + + + + + + + + + + + + + + + + + + + + + + + + + +Dudley Informational [Page 6] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + -------------------------------------------------------------------- + + -* + *-------------* *-------* | + |Configuration| | Path | | + | Services | |Control| | + *-------------* *-------* | + A A A | + | | | | + | | V | + | | *-----* | APPN/HPR + | | | RTP | | + | | *-----* | + | | A | + | | | | + | | V | + | | *-----* | + | | | NCL | | + | | *-----* | + | *------------* A -* + | | | + V V V -* + *---------* *---------* | + | DLC |--->| LDLC | | + | manager | | | | + *---------* *---------* | + | A | | IP DLC + *-----------* | *----* | + V | | | + *---------* | | + | LINK | | | + | DEMUX | | | + *---------* | | + A *-* -* + | | + | V + *---------* + | UDP | + *---------* + A + | + V + *---------* + | IP | + *---------* + + -------------------------------------------------------------------- + Figure 1. HPR/IP Node Structure + + + +Dudley Informational [Page 7] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + +2.3 Logical Link Control (LLC) Used for IP + + Logical Data Link Control (LDLC) is used by the native IP DLC. LDLC + is defined in [2]. LDLC uses a subset of the services defined by + IEEE 802.2 LLC type 2 (LLC2). LDLC uses only the TEST, XID, DISC, + DM, and UI frames. + + LDLC was defined to be used in conjunction with HPR (with the HPR + Control Flows over RTP option set 1402) over reliable links that do + not require link-level error recovery. Most frame loss in IP + networks (and the underlying frame networks) is due to congestion, + not problems with the facilities. When LDLC is used on a link, no + link-level error recovery is available; as a result, only RTP traffic + is supported by the native IP DLC. Using LDLC eliminates the need + for LLC2 and its associated cost (adapter storage, longer path + length, etc.). + +2.3.1 LDLC Liveness + + LDLC liveness (using the LDLC TEST command and response) is required + when the underlying subnetwork does not provide notification of + connection outage. Because UDP is connectionless, it does not + provide outage notification; as a result, LDLC liveness is required + for HPR/IP links. + + Liveness should be sent periodically on active links except as + described in the following subsection when the option to reduce + liveness traffic is implemented. The default liveness timer period + is 10 seconds. When the defaults for the liveness timer and retry + timer (15 seconds) are used, the period between liveness tests is + smaller than the time required to detect failure (retry count + multiplied by retry timer period) and may be smaller than the time + for liveness to complete successfully (on the order of round-trip + delay). When liveness is implemented as specified in the LDLC + finite-state machine (see [2]) this is not a problem because the + liveness protocol works as follows: The liveness timer is for a + single link. The timer is started when the link is first activated + and each time a liveness test completes successfully. When the timer + expires, a liveness test is performed. When the link is operational, + the period between liveness tests is on the order of the liveness + timer period plus the round-trip delay. + + For each implementation, it is necessary to check if the liveness + protocol will work in a satisfactory manner with the default settings + for the liveness and retry timers. If, for example, the liveness + timer is restarted immediately upon expiration, then a different + default for the liveness timer should be used. + + + + +Dudley Informational [Page 8] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + +2.3.1.1 Option to Reduce Liveness Traffic + + In some environments, it is advantageous to reduce the amount of + liveness traffic when the link is otherwise idle. (For example, this + could allow underlying facilities to be temporarily deactivated when + not needed.) As an option, implementations may choose not to send + liveness when the link is idle (i.e., when data was neither sent nor + received over the link while the liveness timer was running). (If + the implementation is not aware of whether data has been received, + liveness testing may be stopped while data is not being sent.) + However, the RTP connections also have a liveness mechanism which + will generate traffic. Some implementations of RTP will allow + setting a large value for the ALIVE timer, thus reducing the amount + of RTP liveness traffic. + + If LDLC liveness is turned off while the link is idle, one side of + the link may detect a link failure much earlier than the other. This + can cause the following problems: + + o If a node that is aware of a link failure attempts to reactivate + the link, the partner node (unaware of the link failure) may + reject the activation as an unsupported parallel link between the + two ports. + + o If a node that is unaware of an earlier link failure sends data + (including new session activations) on the link, it may be + discarded by a node that detected the earlier failure and + deactivated the link. As a result, session activations would + fail. + + The mechanisms described below can be used to remedy these problems. + These mechanisms are needed only in a node not sending liveness when + the link is idle; thus, they would not be required of a node not + implementing this option that just happened to be adjacent to a node + implementing the option. + + o (Mandatory unless the node supports multiple active defined links + between a pair of HPR/IP ports and supports multiple active + dynamic links between a pair of HPR/IP ports.) Anytime a node + rejects the activation of an HPR/IP link as an unsupported + parallel link between a pair of HPR/IP ports (sense data + X'10160045' or X'10160046'), it should perform liveness on any + active link between the two ports that is using a different SAP + pair. Thus, if the activation was not for a parallel link but + rather was a reactivation because one of these active links had + failed, the failed link will be detected. (If the SAP pair for + the link being activated matches the SAP pair for an active link, + a liveness test would succeed because the adjacent node would + + + +Dudley Informational [Page 9] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + respond for the link being activated.) A simple way to implement + this function is for LDLC, upon receiving an activation XID, to + run liveness on all active links with a matching IP address pair + and a different SAP pair. + + o (Mandatory) Anytime a node receives an activation XID with an IP + address pair and a SAP pair that match those of an active link, + it should deactivate the active link and allow it to be + reestablished. A timer is required to prevent stray XIDs from + deactivating an active link. + + o (Recommended) A node should attempt to reactivate an HPR/IP link + before acting on an LDLC-detected failure. This mechanism is + helpful in preventing session activation failures in scenarios + where the other side detected a link failure earlier, but the + network has recovered. + +2.4 IP Port Activation + + The node operator (NO) creates a native IP DLC by issuing + DEFINE_DLC(RQ) (containing customer-configured parameters) and + START_DLC(RQ) commands to the node operator facility (NOF). NOF, in + turn, passes DEFINE_DLC(RQ) and START_DLC(RQ) signals to + configuration services (CS), and CS creates the DLC manager. Then, + the node operator can define a port by issuing DEFINE_PORT(RQ) (also + containing customer-configured parameters) to NOF with NOF passing + the associated signal to CS. + + A node with adapters attached to multiple IP subnetworks may + represent the multiple adapters as a single HPR/IP port. However, in + that case, the node associates a single IP address with that port. + RFC 1122 [9] requires that a node with multiple adapters be able to + use the same source IP address on outgoing UDP packets regardless of + the adapter used for transmission. + + + + + + + + + + + + + + + + + +Dudley Informational [Page 10] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + *----------------------------------------------* + | NOF CS DLC | + *----------------------------------------------* + . DEFINE_DLC(RQ) . + 1 o----------------->o + . DEFINE_DLC(RSP) | + 2 o<-----------------* + . START_DLC(RQ) . create + 3 o----------------->o------------------->o + . START_DLC(RSP) | . + 4 o<-----------------* . + . DEFINE_PORT(RQ) . . + 5 o----------------->o . + . DEFINE_PORT(RSP) | . + 6 o<-----------------* . + + Figure 2. IP Port Activation + + The following parameters are received in DEFINE_PORT(RQ): + + o Port name + + o DLC name + + o Port type (if IP connection networks are supported, set to shared + access transport facility [SATF]; otherwise, set to switched) + + o Link station role (set to negotiable) + + o Maximum receive BTU size (default is 1461 [1492 less an allowance + for the IP, UDP, and LLC headers]) + + o Maximum send BTU size (default is 1461 [1492 less an allowance + for the IP, UDP, and LLC headers]) + + o Link activation limits (total, inbound, and outbound) + + o IPv4 supported (set to yes) + + o The local IPv4 address (required if IPv4 is supported) + + o IPv6 supported (set to no; may be set to yes in the future; see + 2.9, "IPv4-to-IPv6 Migration" on page 35) + + o The local IPv6 address (required if IPv6 is supported) + + o Retry count for LDLC (default is 3) + + + + +Dudley Informational [Page 11] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + o Retry timer period for LDLC (default is 15 seconds; a smaller + value such as 10 seconds can be used for a campus network) + + o LDLC liveness timer period (default is 10 seconds; see 2.3.1, + "LDLC Liveness" on page 7) + + o IP precedence (the setting of the 3-bit field within the Type of + Service byte of the IP header for the LLC commands such as XID + and for each of the APPN transmission priorities; the defaults + are given in 2.6.1, "IP Prioritization" on page 28.) + +2.4.1 Maximum BTU Sizes for HPR/IP + + When IP datagrams are larger than the underlying physical links + support, IP performs fragmentation. When HPR/IP links are + established, the default maximum basic transmission unit (BTU) sizes + are 1461 bytes, which corresponds to the typical IP maximum + transmission unit (MTU) size of 1492 bytes supported by routers on + token-ring networks. 1461 is 1492 less 20 bytes for the IP header, 8 + bytes for the UDP header, and 3 bytes for the IEEE 802.2 LLC header. + The IP header is larger than 20 bytes when optional fields are + included; smaller maximum BTU sizes should be configured if optional + IP header fields are used in the IP network. For IPv6, the default + is reduced to 1441 bytes to allow for the typical IPv6 header size of + 40 bytes. Smaller maximum BTU sizes (but not less than 768) should + be used to avoid fragmentation when necessary. Larger BTU sizes + should be used to improve performance when the customer's IP network + supports a sufficiently large IP MTU size. The maximum receive and + send BTU sizes are passed to CS in DEFINE_PORT(RQ). These maximum + BTU sizes can be overridden in DEFINE_CN_TG(RQ) or DEFINE_LS(RQ). + + The Flags field in the IP header should be set to allow + fragmentation. Some products will not be able to control the setting + of the bit allowing fragmentation; in that case, fragmentation will + most likely be allowed. Although fragmentation is slow and prevents + prioritization based on UDP port numbers, it does allow connectivity + across paths with small MTU sizes. + +2.5 IP Transmission Groups (TGs) + +2.5.1 Regular TGs + + Regular HPR TGs may be established in IP networks using the native IP + DLC architecture. Each of these TGs is composed of one or more + HPR/IP links. Configuration services (CS) identifies the TG with the + destination control point (CP) name and TG number; the destination CP + + + + + +Dudley Informational [Page 12] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + name may be configured or learned via XID, and the TG number, which + may be configured, is negotiated via XID. For auto-activatable + links, the destination CP name and TG number must be configured. + + When multiple links (dynamic or defined) are established between a + pair of IP ports (each associated with a single IP address), an + incoming packet can be mapped to its associated link using the IP + address pair and the service access point (SAP) address pair. If a + node receives an activation XID for a defined link with an IP address + pair and a SAP pair that are the same as for an active defined link, + that node can assume that the link has failed and that the partner + node is reactivating the link. In such a case as an optimization, + the node receiving the XID can take down the active link and allow + the link to be reestablished in the IP network. Because UDP packets + can arrive out of order, implementation of this optimization requires + the use of a timer to prevent a stray XID from deactivating an active + link. + + Support for multiple defined links between a pair of HPR/IP ports is + optional. There is currently no value in defining multiple HPR/IP + links between a pair of ports. In the future if HPR/IP support for + the Resource ReSerVation Protocol (RSVP) [10] is defined, it may be + advantageous to define such parallel links to segregate traffic by + COS on RSVP "sessions." Using RSVP, HPR would be able to reserve + bandwidth in IP networks. An HPR logical link would be mapped to an + RSVP "session" that would likely be identified by either a specific + application-provided UDP port number or a dynamically-assigned UDP + port number. + + When multiple defined HPR/IP links between ports are not supported, + an incoming activation for a defined HPR/IP link may be rejected with + sense data X'10160045' if an active defined HPR/IP link already + exists between the ports. If the SAP pair in the activation XID + matches the SAP pair for the existing link, the optimization + described above may be used instead. + + If parallel defined HPR/IP links between ports are not supported, an + incoming activation XID is mapped to the defined link station (if it + exists) associated with the port on the adjacent node using the + source IP address in the incoming activation XID. This source IP + address should be the same as the destination IP address associated + with the matching defined link station. (They may not be the same if + the adjacent node has multiple IP addresses, and the configuration + was not coordinated correctly.) + + If parallel HPR/IP links between ports are supported, multiple + defined link stations may be associated with the port on the adjacent + node. In that case, predefined TG numbers (see "Partitioning the TG + + + +Dudley Informational [Page 13] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + Number Space" in Chapter 9 Configuration Services of [1]) may be used + to map the XID to a specific link station. However, because the same + TG characteristics may be used for all HPR/IP links between a given + pair of ports, all the link stations associated with the port in the + adjacent node should be equivalent; as a result, TG number + negotiation using negotiable TG numbers may be used. + + In the future, if multiple HPR/IP links with different + characteristics are defined between a pair of ports using RSVP, + defined link stations will need sufficient configured information to + be matched with incoming XIDs. (Correct matching of an incoming XID + to a defined link station allows CS to provide the correct TG + characteristics to topology and routing services (TRS).) At that + time CS will do the mapping based on both the IP address of the + adjacent node and a predefined TG number. + + The node initiating link activation knows which link it is + activating. Some parameters sent in prenegotiation XID are defined + in the regular link station configuration and not allowed to change + in following negotiation-proceeding XIDs. To allow for forward + migration to RSVP, when a regular TG is activated in an IP network, + the node receiving the first XID (i.e., the node not initiating link + activation) must also understand which defined link station is being + activated before sending a prenegotiation XID in order to correctly + set parameters that cannot change. For this reason, the node + initiating link activation will indicate the TG number in + prenegotiation XIDs by including a TG Descriptor (X'46') control + vector containing a TG Identifier (X'80') subfield. Furthermore, the + node receiving the first XID will force the node activating the link + to send the first prenegotiation XID by responding to null XIDs with + null XIDs. To prevent potential deadlocks, the node receiving the + first XID has a limit (the LDLC retry count can be used) on the + number of null XIDs it will send. Once this limit is reached, that + node will send an XID with an XID Negotiation Error (X'22') control + vector in response to a null XID; sense data X'0809003A' is included + in the control vector to indicate unexpected null XID. If the node + that received the first XID receives a prenegotiation XID without the + TG Identifier subfield, it will send an XID with an XID Negotiation + Error control vector to reject the link connection; sense data + X'088C4680' is included in the control vector to indicate the + subfield was missing. + + For a regular TG, the TG parameters are provided by the node operator + based on customer configuration in DEFINE_PORT(RQ) and DEFINE_LS(RQ). + The following parameters are supplied in DEFINE_LS(RQ) for HPR/IP + links: + + + + + +Dudley Informational [Page 14] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + o The destination IP host name (this parameter can usually be + mapped to the destination IP address): If the link is not + activated at node initialization, the IP host name should be + mapped to an IP address, and the IP address should be stored with + the link station definition. This is required to allow an + incoming link activation to be matched with the link station + definition. If the adjacent node activates the link with a + different IP address (e.g., it could have multiple ports), it + will not be possible to match the link activation with the link + station definition, and the default parameters specified in the + local port definition will be used. + + o The destination IP version (set to version 4, support for version + 6 may be required in the future; this parameter is only required + if the address and version cannot be determined using the + destination IP host name.) + + o The destination IP address (in the format specified by the + destination IP version; this parameter is only required if the + address cannot be determined using the destination IP host name.) + + o Source service access point address (SSAP) used for XID, TEST, + DISC, and DM (default is X'04'; other values may be specified + when multiple links between a pair of IP addresses are defined) + + o Destination service access point address (DSAP) used for XID, + TEST, DISC, and DM (default is X'04') + + o Source service access point address (SSAP) used for HPR network + layer packets (NLPs) (default is X'C8'; other values may be + specified when multiple links between a pair of IP addresses are + defined.) + + o Maximum receive BTU size (default is 1461; this parameter is used + to override the setting in DEFINE_PORT.) + + o Maximum send BTU size (default is 1461; this parameter is used to + override the setting in DEFINE_PORT.) + + o IP precedence (the setting of the 3-bit field within the Type of + Service byte of the IP header for LLC commands such as XID and + for each of the APPN transmission priorities; the defaults are + given in 2.6.1, "IP Prioritization" on page 28; this parameter is + used to override the settings in DEFINE_PORT) + + o Shareable with connection network traffic (default is yes for + non-RSVP links) + + + + +Dudley Informational [Page 15] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + o Retry count for LDLC (default is 3; this parameter is used to + override the setting in DEFINE_PORT) + + o Retry timer period for LDLC (default is 15 seconds; a smaller + value such as 10 seconds can be used for a campus link; this + parameter is used to override the setting in DEFINE_PORT) + + o LDLC liveness timer period (default is 10 seconds; this parameter + is to override the setting in DEFINE_PORT; see 2.3.1, "LDLC ness" + on page 7) + + o Auto-activation supported (default is no; may be set to yes when + the local node has switched access to the IP network) + + o Limited resource (default is to set in concert with auto- + activation supported) + + o Limited resource liveness timer (default is 45 sec.) + + o Port name + + o Adjacent CP name (optional) + + o Local CP-CP sessions supported + + o Defined TG number (optional) + + o TG characteristics + + The following figures show the activation and deactivation of regular + TGs. + + + + + + + + + + + + + + + + + + + + +Dudley Informational [Page 16] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + +*------------------------------------------------------------------* +|CS DLC LDLC DMUX UDP| +*------------------------------------------------------------------* + . . . . + .CONNECT_OUT(RQ) . create . . + o--------------->o-------------->o . . + . | new LDLC . . + . o----------------------------->o . + CONNECT_OUT(+RSP)| . . . + o<---------------* . . . + | XID . XID(CMD) . XID + *------------------------------->o----------------------------->o-----> + + Figure 3. Regular TG Activation (outgoing) + + In Figure 3 upon receiving START_LS(RQ) from NOF, CS starts the link + activation process by sending CONNECT_OUT(RQ) to the DLC manager. + The DLC manager creates an instance of LDLC for the link, informs the + link demultiplexor, and sends CONNECT_OUT(+RSP) to CS. Then, CS + starts the activation XID exchange. + +*------------------------------------------------------------------* +|CS DLC LDLC DMUX UDP| +*------------------------------------------------------------------* + . . . . + . CONNECT_IN(RQ) . XID(CMD) . XID . XID + o<---------------o<-----------------------------o<--------------o<----- + | CONNECT_IN(RSP). create . . + *--------------->o-------------->o . . + . | new LDLC . . + . o----------------------------->o . + . | XID(CMD) . . . + . *-------------->o . . + . XID | . . + o<-------------------------------* . . + | XID . XID(RSP) . XID + *------------------------------->o----------------------------->o-----> + + Figure 4. Regular TG Activation (incoming) + + In Figure 4, when an XID is received for a new link, it is passed to + the DLC manager. The DLC manager sends CONNECT_IN(RQ) to notify CS + of the incoming link activation, and CS sends CONNECT_IN(+RSP) + accepting the link activation. The DLC manager then creates a new + instance of LDLC, informs the link demultiplexor, and forwards the + XID to to CS via LDLC. CS then responds by sending an XID to the + adjacent node. + + + + +Dudley Informational [Page 17] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + The two following figures show normal TG deactivation (outgoing and + incoming). + +*------------------------------------------------------------------* +|CS DLC LDLC DMUX UDP| +*------------------------------------------------------------------* + . . . . . + . DEACT . DISC . DISC + o------------------------------->o----------------------------->o-----> + . DEACT . DM . DM . DM + o<-------------------------------o<-------------o<--------------o<----- + | DISCONNECT(RQ) . destroy . . . + *--------------->o-------------->o . . + DISCONNECT(RSP) | . . + o<---------------* . . + + Figure 5. Regular TG Deactivation (outgoing) + + In Figure 5 upon receiving STOP_LS(RQ) from NOF, CS sends DEACT to + notify the partner node that the HPR link is being deactivated. When + the response is received, CS sends DISCONNECT(RQ) to the DLC manager, + and the DLC manager deactivates the instance of LDLC. Upon receiving + DISCONNECT(RSP), CS sends STOP_LS(RSP) to NOF. + +*------------------------------------------------------------------* +|CS DLC LDLC DMUX UDP| +*------------------------------------------------------------------* + . . . . . + . DEACT . DISC . DISC . DISC + o<-------------------------------o<-------------o<--------------o<----- + | . | DM . DM + | . *----------------------------->o-----> + | DISCONNECT(RQ) . destroy . . . + *--------------->o-------------->o . . + .DISCONNECT(RSP) | . . + o<---------------* . . + + Figure 6. Regular TG Deactivation (incoming) + + In Figure 6, when an adjacent node deactivates a TG, the local node + receives a DISC. CS sends STOP_LS(IND) to NOF. Because IP is + connectionless, the DLC manager is not aware that the link has been + deactivated. For that reason, CS also needs to send DISCONNECT(RQ) + to the DLC manager; the DLC manager deactivates the instance of LDLC. + + + + + + + +Dudley Informational [Page 18] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + +2.5.1.1 Limited Resources and Auto-Activation + + To reduce tariff charges, the APPN architecture supports the + definition of switched links as limited resources. A limited- + resource link is deactivated when there are no sessions traversing + the link. Intermediate HPR nodes are not aware of sessions between + logical units (referred to as LU-LU sessions) carried in crossing RTP + connections; in HPR nodes, limited-resource TGs are deactivated when + no traffic is detected for some period of time. Furthermore, APPN + links may be defined as auto-activatable. Auto-activatable links are + activated when a new session has been routed across the link. + + An HPR node may have access to an IP network via a switched access + link. In such environments, it may be advisable for customers to + define regular HPR/IP links as limited resources and as being auto- + activatable. + +2.5.2 IP Connection Networks + + Connection network support for IP networks (option set 2010), is + described in this section. + + APPN architecture defines single link TGs across the point-to-point + lines connecting APPN nodes. The natural extension of this model + would be to define a TG between each pair of nodes connected to a + shared access transport facility (SATF) such as a LAN or IP network. + However, the high cost of the system definition of such a mesh of TGs + is prohibitive for a network of more than a few nodes. For that + reason, the APPN connection network model was devised to reduce the + system definition required to establish TGs between APPN nodes. + + Other TGs may be defined through the SATF which are not part of the + connection network. Such TGs (referred to as regular TGs in this + document) are required for sessions between control points (referred + to as CP-CP sessions) but may also be used for LU-LU sessions. + + In the connection network model, a virtual routing node (VRN) is + defined to represent the SATF. Each node attached to the SATF + defines a single TG to the VRN rather than TGs to all other attached + nodes. + + Topology and routing services (TRS) specifies that a session is to be + routed between two nodes across a connection network by including the + connection network TGs between each of those nodes and the VRN in the + Route Selection control vector (RSCV). When a network node has a TG + to a VRN, the network topology information associated with that TG + includes DLC signaling information required to establish connectivity + to that node across the SATF. For an end node, the DLC signaling + + + +Dudley Informational [Page 19] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + information is returned as part of the normal directory services (DS) + process. TRS includes the DLC signaling information for TGs across + connection networks in RSCVs. + + CS creates a dynamic link station when the next hop in the RSCV of an + ACTIVATE_ROUTE signal received from session services (SS) is a + connection network TG or when an adjacent node initiates link + activation upon receiving such an ACTIVATE_ROUTE signal. Dynamic + link stations are normally treated as limited resources, which means + they are deactivated when no sessions are using them. CP-CP sessions + are not supported on connections using dynamic link stations because + CP-CP sessions normally need to be kept up continuously. + + Establishment of a link across a connection network normally requires + the use of CP-CP sessions to determine the destination IP address. + Because CP-CP sessions must flow across regular TGs, the definition + of a connection network does not eliminate the need to define regular + TGs as well. + + Normally, one connection network is defined on a LAN (i.e., one VRN + is defined.) For an environment with several interconnected campus + IP networks, a single wide-area connection network can be defined; in + addition, separate connection networks can be defined between the + nodes connected to each campus IP network. + +2.5.2.1 Establishing IP Connection Networks + + Once the port is defined, a connection network can be defined on the + port. In order to support multiple TGs from a port to a VRN, the + connection network is defined by the following process: + + 1. A connection network and its associated VRN are defined on the + port. This is accomplished by the node operator issuing a + DEFINE_CONNECTION_NETWORK(RQ) command to NOF and NOF passing a + DEFINE_CN(RQ) signal to CS. + + 2. Each TG from the port to the VRN is defined by the node operator + issuing DEFINE_CONNECTION_NETWORK_TG(RQ) to NOF and NOF passing + DEFINE_CN_TG(RQ) to CS. + + Prior to implementation of Resource ReSerVation Protocol (RSVP) + support, only one connection network TG between a port and a VRN is + required. In that case, product support for the DEFINE_CN_TG(RQ) + signal is not required because a single set of port configuration + parameters for each connection network is sufficient. If a NOF + implementation does not support DEFINE_CN_TG(RQ), the parameters + listed in the following section for DEFINE_CN_TG(RQ), are provided by + DEFINE_CN(RQ) instead. Furthermore, the Connection Network TG + + + +Dudley Informational [Page 20] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + Numbers (X'81') subfield in the TG Descriptor (X'46') control vector + on an activation XID is only required to support multiple connection + network TGs to a VRN, and its use is optional. + + *-----------------------------------------------------* + | NO NOF CS | + *-----------------------------------------------------* + DEFINE_CONNECTION_NETWORK(RQ) DEFINE_CN(RQ) . + o------------------------>o----------------->o + DEFINE_CONNECTION_NETWORK(RSP) DEFINE_CN(RSP) | + o<------------------------o<-----------------* + DEFINE_CONNECTION_NETWORK_TG(RQ) DEFINE_CN_TG(RQ) . + o------------------------>o----------------->o + DEFINE_CONNECTION_NETWORK_TG(RSP) DEFINE_CN_TG(RSP)| + o<------------------------o<-----------------* + + Figure 7. IP Connection Network Definition + + An incoming dynamic link activation may be rejected with sense data + X'10160046' if there is an existing dynamic link between the two + ports over the same connection network (i.e., with the same VRN CP + name). If a node receives an activation XID for a dynamic link with + an IP address pair, a SAP pair, and a VRN CP name that are the same + as for an active dynamic link, that node can assume that the link has + failed and that the partner node is reactivating the link. In such a + case as an optimization, the node receiving the XID can take down the + active link and allow the link to be reestablished in the IP network. + Because UDP packets can arrive out of order, implementation of this + optimization requires the use of a timer to prevent a stray XID from + deactivating an active link. + + Once all the connection networks are defined, the node operator + issues START_PORT(RQ), NOF passes the associated signal to CS, and CS + passes ACTIVATE_PORT(RQ) to the DLC manager. Upon receiving the + ACTIVATE_PORT(RSP) signal from the DLC manager, CS sends a TG_UPDATE + signal to TRS for each defined connection network TG. Each signal + notifies TRS that a TG to the VRN has been activated and includes TG + vectors describing the TG. If the port fails or is deactivated, CS + sends TG_UPDATE indicating the connection network TGs are no longer + operational. Information about TGs between a network node and the + VRN is maintained in the network topology database. Information + about TGs between an end node and the VRN is maintained only in the + local topology database. If TRS has no node entry in its topology + database for the VRN, TRS dynamically creates such an entry. A VRN + node entry will become part of the network topology database only if + + + + + + +Dudley Informational [Page 21] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + a network node has defined a TG to the VRN; however, TRS is capable + of selecting a direct path between two end nodes across a connection + network without a VRN node entry. + +*--------------------------------------------------------------------* +| CS TRS DLC DMUX | +*--------------------------------------------------------------------* + . ACTIVATE_PORT(RQ) . create + o--------------------------------------->o----------------->o + . ACTIVATE_PORT(RSP) | . + o<---------------------------------------* . + | TG_UPDATE . . . + *------------------->o . . + . . . . + + Figure 8. IP Connection Network Establishment + +The TG vectors for IP connection network TGs include the following +information: + + o TG number + + o VRN CP name + + o TG characteristics used during route selection + + - Effective capacity + - Cost per connect time + - Cost per byte transmitted + - Security + - Propagation delay + - User defined parameters + + o Signaling information + + - IP version (indicates the format of the IP header including + the IP address) + + - IP address + + - Link service access point address (LSAP) used for XID, TEST, + DISC, and DM + +2.5.2.2 IP Connection Network Parameters + + For a connection network TG, the parameters are determined by CS + using several inputs. Parameters that are particular to the local + port, connection network, or TG are system defined and received in + + + +Dudley Informational [Page 22] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + DEFINE_PORT(RQ), DEFINE_CN(RQ), or DEFINE_CN_TG(RQ). Signaling + information for the destination node including its IP address is + received in the ACTIVATE_ROUTE request from SS. + + The following configuration parameters are received in DEFINE_CN(RQ): + + o Connection network name (CP name of the VRN) + + o Limited resource liveness timer (default is 45 sec.) + + o IP precedence (the setting of the 3-bit field within the Type of + Service byte of the IP header for LLC commands such as XID and + for each of the APPN transmission priorities; the defaults are + given in 2.6.1, "IP Prioritization" on page 28; this parameter is + used to override the settings in DEFINE_PORT) + + The following configuration parameters are received in + DEFINE_CN_TG(RQ): + + o Port name + + o Connection network name (CP name of the VRN) + + o Connection network TG number (set to a value between 1 and 239) + + o TG characteristics (see 2.6.3, "Default TG Characteristics" on + page 30) + + o Link service access point address (LSAP) used for XID, TEST, + DISC, and DM (default is X'04') + + o Link service access point address (LSAP) used for HPR network + layer packets (default is X'C8') + + o Limited resource (default is yes) + + o Retry count for LDLC (default is 3; this parameter is used to + override the setting in DEFINE_PORT) + + o Retry timer period for LDLC (default is 15 sec.; a smaller value + such as 10 seconds can be used for a campus connection network; + this parameter is used to override the setting in DEFINE_PORT) + + o LDLC liveness timer period (default is 10 seconds; this parameter + is used to override the setting in DEFINE_PORT; see 2.3.1, "LDLC + Liveness" on page 7) + + + + + +Dudley Informational [Page 23] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + o Shareable with other HPR traffic (default is yes for non-RSVP + links) + + o Maximum receive BTU size (default is 1461; this parameter is used + to override the value in DEFINE_PORT(RQ).) + + o Maximum send BTU size (default is 1461; this parameter is used to + override the value in DEFINE_PORT(RQ).) + + The following parameters are received in ACTIVATE_ROUTE for + connection network TGs: + + o The TG pair + + o The destination IP version (if this version is not supported by + the local node, the ACTIVATE_ROUTE_RSP reports the activation + failure with sense data X'086B46A5'.) + + o The destination IP address (in the format specified by the + destination IP version) + + o Destination service access point address (DSAP) used for XID, + TEST, DISC, and DM + +2.5.2.3 Sharing of TGs + + Connection network traffic is multiplexed onto a regular defined IP + TG (usually used for CP-CP session traffic) in order to reduce the + control block storage. No XIDs flow to establish a new TG on the IP + network, and no new LLC is created. When a regular TG is shared, + incoming traffic is demultiplexed using the normal means. If the + regular TG is deactivated, a path switch is required for the HPR + connection network traffic sharing the TG. + + Multiplexing is possible if the following conditions hold: + + 1. Both the regular TG and the connection network TG to the VRN are + defined as shareable between HPR traffic streams. + + 2. The destination IP address is the same. + + 3. The regular TG is established first. (Because links established + for connection network traffic do not support CP-CP sessions, + there is little value in allowing a regular TG to share such a + link.) + + The destination node is notified via XID when a TG can be shared + between HPR data streams. At either end, upon receiving + + + +Dudley Informational [Page 24] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + ACTIVATE_ROUTE requesting a shared TG for connection network traffic, + CS checks its TGs for one meeting the required specifications before + initiating a new link. First, CS looks for a link established for + the TG pair; if there is no such link, CS determines if there is a + regular TG that can be shared and, if multiple such TGs exist, which + TG to choose. As a result, RTP connections routed over the same TG + pair may actually use different links, and RTP connections routed + over different TG pairs may use the same link. + +2.5.2.4 Minimizing RSCV Length + + The maximum length of a Route Selection (X'2B') control vector (RSCV) + is 255 bytes. Use of connection networks significantly increases the + size of the RSCV contents required to describe a "hop" across an + SATF. First, because two connection network TGs are used to specify + an SATF hop, two TG Descriptor (X'46') control vectors are required. + Furthermore, inclusion of DLC signaling information within the TG + Descriptor control vectors increases the length of these control + vectors. As a result, the total number of hops that can be specified + in RSCVs traversing connection networks is reduced. + + To avoid unnecessarily limiting the number of hops, a primary goal in + designing the formats for IP signaling information is to minimize + their size. Additional techniques are also used to reduce the effect + of the RSCV length limitation. + + For an IP connection network, DLC signaling information is required + only for the second TG (i.e., from the VRN to the destination node); + the signaling information for the first TG is locally defined at the + origin node. For this reason, the topology database does not include + DLC signaling information for the entry describing a connection + network TG from a network node to a VRN. The DLC signaling + information is included in the allied entry for the TG in the + opposite direction. This mechanism cannot be used for a connection + network TG between a VRN and an end node. However, a node + implementing IP connection networks does not include IP signaling + information for the first connection network TG when constructing an + RSCV. + + In an environment where APPN network nodes are used to route between + legacy LANs and wide-area IP networks, it is recommended that + customers not define connection network TGs between these network + nodes and VRNs representing legacy LANs. Typically, defined links + are required between end nodes on the legacy LANs and such network + nodes which also act as network node servers for the end nodes. + These defined links can be used for user traffic as well as control + traffic. This technique will reduce the number of connection network + hops in RSCVs between end nodes on different legacy LANs. + + + +Dudley Informational [Page 25] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + Lastly, for environments where RSCVs are still not able to include + enough hops, extended border nodes (EBNs) can be used to partition + the network. In this case, the EBNs will also provide piecewise + subnet route calculation and RSCV swapping. Thus, the entire route + does not need to be described in a single RSCV with its length + limitation. + +2.5.3 XID Changes + + Packets transmitted over IP networks are lost or arrive out of order + more often than packets transmitted over other "link" technologies. + As a result, the following problem with the XID3 negotiation protocol + was exposed: + + -------------------------------------------------------------------- + + *---------------------------------* + |Node A Node B| + *---------------------------------* + o + o + o + XID3 (np, NEG) + o<-------------------------o + |XID3 (np, SEC) + *------------------------->o + XID3 (np, PRI)| + lost<-----------* + + time out + XID3 (np, SEC) + o------------------------->o + SETMODE | + o<-------------------------* + fail because never + received XID3 (np, PRI) + + Notation: np - negotiation proceeding + NEG - negotiable link station role + SEC - secondary link station role + PRI - primary link station role + + -------------------------------------------------------------------- + Figure 9. XID3 Protocol Problem + + In the above sequence, the XID3(np, PRI), which is a link-level + response to the received XID3(np, SEC), is lost. Node A times out + and resends the XID3(np, SEC) as a link-level command. When Node B + + + +Dudley Informational [Page 26] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + receives this command, it thinks that the XID3(np, PRI) was + successfully received by Node A and that the activation XID exchange + is complete. As a result, Node B sends SETMODE (SNRM, SABME, or + XID_DONE_RQ, depending upon the link type). When Node A receives + SETMODE, it fails the link activation because it has not received an + XID3(np, PRI) from Node B confirming that Node B does indeed agree to + be the primary. Moreover, there are similar problems with incomplete + TG number negotiation. + + To solve the problems with incomplete role and TG number negotiation, + two new indicators are defined in XID3. The problems are solved only + if both link stations support these new indicators: + + o Negotiation Complete Supported indicator (byte 12 bit 0) -- this + 1-bit field indicates whether the Negotiation Complete indicator + is supported. This field is meaningful when the XID exchange + state is negotiation proceeding; otherwise, it is reserved. A + value of 0 means the Negotiation Complete indicator is not + supported; a value of 1 means the indicator is supported. + + o Negotiation Complete indicator (byte 12 bit 1) -- this 1-bit + field is meaningful only when the XID exchange state is + negotiation proceeding, the XID3 is sent by the secondary link + station, and the Negotiation Complete Supported indicator is set + to 1; otherwise, this field is reserved. This field is set to 1 + by a secondary link station that supports enhanced XID + negotiation when it considers the activation XID negotiation to + be complete for both link station role and TG number (i.e., it is + ready to receive a SETMODE command from the primary link + station.) + + When a primary link station that supports enhanced XID negotiation + receives an XID3(np) with both the Negotiation Complete Supported + indicator and the Negotiation Complete indicator set to 1, the + primary link station will know that it can safely send SETMODE if it + also considers the XID negotiation to be complete. The new + indicators are used as shown in the following sequence when both the + primary and secondary link stations support enhanced XID negotiation. + + + + + + + + + + + + + +Dudley Informational [Page 27] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + -------------------------------------------------------------------- + + *----------------------------------* + |Node A Node B | + *----------------------------------* + o + o + o + XID3 (np, NEG, S, ^C) + 1 o<--------------------------o + |XID3 (np, SEC, S, ^C) + 2 *-------------------------->o + XID3 (np, PRI, S, ^C)| + 3 lost <-----------* + + time out + XID3 (np, SEC, S, ^C) + 4 o-------------------------->o + XID3 (np, PRI, S, ^C)| + 5 o<--------------------------* + |XID3 (np, SEC, S, C) + 6 *-------------------------->o + SETMODE | + 7 o<--------------------------* + + ^S indicates that byte 12 bit 0 is set to 0. + S indicates that byte 12 bit 0 is set to 1. + ^C indicates that byte 12 bit 1 is set to 0. + C indicates that byte 12 bit 1 is set to 1. + + -------------------------------------------------------------------- + Figure 10. Enhanced XID Negotiation + + When Node B receives the XID in flow 4, it realizes that the Node A + does not consider XID negotiation to be complete; as a result, it + resends its current XID information in flow 5. When Node A receives + this XID, it responds in flow 6 with an XID that indicates XID + negotiation is complete. At this point, Node B, acting as the + primary link station, sends SETMODE, and the link is activated + successfully. + + Migration cases with only one link station supporting enhanced XID + negotiation are shown in the two following sequences. In the next + sequence, only Node A (acting as the secondary link station) supports + the new function. + + + + + + +Dudley Informational [Page 28] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + -------------------------------------------------------------------- + + *---------------------------------* + |Node A Node B| + *---------------------------------* + o + o + o + XID3 (np, NEG, ^S) + 1 o<--------------------------o + |XID3 (np, SEC, S, ^C) + 2 *-------------------------->o + XID3 (np, PRI, ^S)| + 3 lost <-----------* + + time out + XID3 (np, SEC, S, ^C) + 4 o-------------------------->o + SETMODE | + 5 o<--------------------------* + fail + + + -------------------------------------------------------------------- + Figure 11. First Migration Case + + The XID negotiation fails because Node B does not understand the new + indicators and responds to flow 4 with SETMODE. + + In the next sequence, Node B supports the new indicators but Node A + does not. + + + + + + + + + + + + + + + + + + + + +Dudley Informational [Page 29] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + -------------------------------------------------------------------- + + *---------------------------------* + |Node A Node B| + *---------------------------------* + o + o + o + XID3 (np, NEG, S, ^C) + 1 o<--------------------------o + |XID3 (np, SEC, ^S) + 2 *-------------------------->o + XID3 (np, PRI, S, ^C)| + 3 lost <-----------* + + time out + XID3 (np, SEC, ^S) + 4 o-------------------------->o + SETMODE | + 5 o<--------------------------* + fail + + + ------------------------------------------------------------------------ + Figure 12. Second Migration Case + + The XID negotiation fails because Nobe A does not understand the new + indicators and thus cannot indicate that it thinks XID negotiation is + not complete in flow 4. Node B understands that the secondary link + station (node A) does not support the new indicators and respond with + SETMODE in flow 5. + + Products that support HPR/IP links are required to support enhanced + XID negotiation. Moreover, it is recommended that products + implementing this solution for HPR/IP links also support it for other + link types. + +2.5.4 Unsuccessful IP Link Activation + + Link activation may fail for several different reasons. When link + activation over a connection network or of an auto-activatable link + is attempted upon receiving ACTIVATE_ROUTE from SS, activation + failure is reported with ACTIVATE_ROUTE_RSP containing sense data + explaining the cause of failure. Likewise, when activation fails for + other regular defined links, the failure is reported with + START_LS(RSP) containing sense data. + + + + + +Dudley Informational [Page 30] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + As is normal for session activation failures, the sense data is also + sent to the node that initiated the session. At the APPN-to-HPR + boundary, a -RSP(BIND) or an UNBIND with an Extended Sense Data + control vector is generated and returned to the primary logical unit + (PLU). + + At an intermediate HPR node, link activation failure can be reported + with sense data X'08010000' or X'80020000'. At a node with route- + selection responsibility, such failure can be reported with sense + data X'80140001'. + + The following table contains the sense data for the various causes of + link activation failure: + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Dudley Informational [Page 31] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + ++----------------------------------------------------------------------+ +| Table 1 (Page 1 of 2). Native IP DLC Link Activation Failure Sense | +| Data | ++--------------------------------------------------------+-------------+ +| ERROR DESCRIPTION | SENSE DATA | ++--------------------------------------------------------+-------------+ +| The link specified in the RSCV is not available. | X'08010000' | ++--------------------------------------------------------+-------------+ +| The limit for null XID responses by a called node was | X'0809003A' | +| reached. | | ++--------------------------------------------------------+-------------+ +| A BIND was received over a subarea link, but the next | X'08400002' | +| hop is over a port that supports only HPR links. The | | +| receiver does not support this configuration. | | ++--------------------------------------------------------+-------------+ +| The contents of the DLC Signaling Type (X'91') | X'086B4691' | +| subfield of the TG Descriptor (X'46') control vector | | +| contained in the RSCV were invalid. | | ++--------------------------------------------------------+-------------+ +| The contents of the IP Address and Link Service Access | X'086B46A5' | +| Point Address (X'A5') subfield of the TG Descriptor | | +| (X'46') control vector contained in the RSCV were | | +| invalid. | | ++--------------------------------------------------------+-------------+ +| No DLC Signaling Type (X'91') subfield was found in | X'086D4691' | +| the TG Descriptor (X'46') control vector contained in | | +| the RSCV. | | ++--------------------------------------------------------+-------------+ +| No IP Address and Link Service Access Point Address | X'086D46A5' | +| (X'A5') subfield was found in the TG Descriptor | | +| (X'46') control vector contained in the RSCV. | | ++--------------------------------------------------------+-------------+ +| Multiple sets of DLC signaling information were found | X'08770019' | +| in the TG Descriptor (X'46') control vector contained | | +| in the RSCV. IP supports only one set of DLC | | +| signaling information. | | ++--------------------------------------------------------+-------------+ +| Link Definition Error: A link is defined as not | X'08770026' | +| supporting HPR, but the port only supports HPR links. | | ++--------------------------------------------------------+-------------+ +| A called node found no TG Identifier (X'80') subfield | X'088C4680' | +| within a TG Descriptor (X'46') control vector in a | | +| prenegotiation XID for a defined link in an IP | | +| network. | | ++--------------------------------------------------------+-------------+ + + + + + + +Dudley Informational [Page 32] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + ++----------------------------------------------------------------------+ +| Table 1 (Page 2 of 2). Native IP DLC Link Activation Failure Sense | +| Data | ++--------------------------------------------------------+-------------+ +| The XID3 received from the adjacent node does not | X'10160031' | +| contain an HPR Capabilities (X'61') control vector. | | +| The IP port supports only HPR links. | | ++--------------------------------------------------------+-------------+ +| The RTP Supported indicator is set to 0 in the HPR | X'10160032' | +| Capabilities (X'61') control vector of the XID3 | | +| received from the adjacent node. The IP port supports | | +| only links to nodes that support RTP. | | ++--------------------------------------------------------+-------------+ +| The Control Flows over RTP Supported indicator is set | X'10160033' | +| to 0 in the HPR Capabilities (X'61') control vector of | | +| the XID3 received from the adjacent node. The IP port | | +| supports only links to nodes that support control | | +| flows over RTP. | | ++--------------------------------------------------------+-------------+ +| The LDLC Supported indicator is set to 0 in the HPR | X'10160034' | +| Capabilities (X'61') control vector of the XID3 | | +| received from the adjacent node. The IP port supports | | +| only links to nodes that support LDLC. | | ++--------------------------------------------------------+-------------+ +| The HPR Capabilities (X'61') control vector received | X'10160044' | +| in XID3 does not include an IEEE 802.2 LLC (X'80') HPR | | +| Capabilities subfield. The subfield is required on an | | +| IP link. | | ++--------------------------------------------------------+-------------+ +| Multiple defined links between a pair of switched | X'10160045' | +| ports is not supported by the local node. A link | | +| activation request was received for a defined link, | | +| but there is an active defined link between the paired | | +| switched ports. | | ++--------------------------------------------------------+-------------+ +| Multiple dynamic links across a connection network | X'10160046' | +| between a pair of switched ports is not supported by | | +| the local node. A link activation request was | | +| received for a dynamic link, but there is an active | | +| dynamic link between the paired switched ports across | | +| the same connection network. | | ++--------------------------------------------------------+-------------+ +| Link failure | X'80020000' | ++--------------------------------------------------------+-------------+ +| Route selection services has determined that no path | X'80140001' | +| to the destination node exists for the specified COS. | | ++--------------------------------------------------------+-------------+ + + + + +Dudley Informational [Page 33] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + +2.6 IP Throughput Characteristics + +2.6.1 IP Prioritization + + Typically, IP routers process packets on a first-come-first-served + basis; i.e., no packets are given transmission priority. However, + some IP routers prioritize packets based on IP precedence (the 3-bit + field within the Type of Service byte of the IP header) or UDP port + numbers. (With the current plans for IP security, the UDP port + numbers are encrypted; as a result, IP routers would not be able to + prioritize encrypted traffic based on the UDP port numbers.) HPR + will be able to exploit routers that provide priority function. + + The 5 UDP port numbers, 12000-12004 (decimal), have been assigned by + the Internet Assigned Number Authority (IANA). Four of these port + numbers are used for ANR-routed network layer packets (NLPs) and + correspond to the APPN transmission priorities (network, 12001; high, + 12002; medium, 12003; and low, 12004), and one port number (12000) is + used for a set of LLC commands (i.e., XID, TEST, DISC, and DM) and + function-routed NLPs (i.e., XID_DONE_RQ and XID_DONE_RSP). These + port numbers are used for "listening" and are also used in the + destination port number field of the UDP header of transmitted + packets. The source port number field of the UDP header can be set + either to one of these port numbers or to an ephemeral port number. + + The IP precedence for each transmission priority and for the set of + LLC commands (including function-routed NLPs) are configurable. The + implicit assumption is that the precedence value is associated with + priority queueing and not with bandwidth allocation; however, + bandwidth allocation policies can be administered by matching on the + precedence field. The default mapping to IP precedence is shown in + the following table: + + + + + + + + + + + + + + + + + + + +Dudley Informational [Page 34] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + +---------------------------------------------+ + | Table 2. Default IP Precedence Settings | + +----------------------+----------------------+ + | PRIORITY | PRECEDENCE | + +----------------------+----------------------+ + | LLC commands and | 110 | + | function-routed NLPs | | + +----------------------+----------------------+ + | Network | 110 | + +----------------------+----------------------+ + | High | 100 | + +----------------------+----------------------+ + | Medium | 010 | + +----------------------+----------------------+ + | Low | 001 | + +----------------------+----------------------+ + + As an example, with this default mapping, telnet, interactive ftp, + and business-use web traffic could be mapped to a precedence value of + 011, and batch ftp could be mapped to a value of 000. + + These settings were devised based on the AIW's understanding of the + intended use of IP precedence. The use of IP precedence will be + modified appropriately if the IETF standardizes its use differently. + The other fields in the IP TOS byte are not used and should be set to + 0. + + For outgoing ANR-routed NLPs, the destination (and optionally the + source) UDP port numbers and IP precedence are set based on the + transmission priority specified in the HPR network header. + + It is expected that the native IP DLC architecture described in this + document will be used primarily for private campus or wide-area + intranets where the customer will be able to configure the routers to + honor the transmission priority associated with the UDP port numbers + or IP precedence. The architecture can be used to route HPR traffic + in the Internet; however, in that environment, routers do not + currently provide the priority function, and customers may find the + performance unacceptable. + + In the future, a form of bandwidth reservation may be possible in IP + networks using the Resource ReSerVation Protocol (RSVP), or the + differentiated services currently being studied by the Integrated + Services working group of the IETF. Bandwidth could be reserved for + an HPR/IP link thus insulating the HPR traffic from congestion + associated with the traffic of other protocols. + + + + + +Dudley Informational [Page 35] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + +2.6.2 APPN Transmission Priority and COS + + APPN transmission priority and class of service (COS) allow APPN TGs + to be highly utilized with batch traffic without impacting the + performance of response-time sensitive interactive traffic. + Furthermore, scheduling algorithms guarantee that lower-priority + traffic is not completely blocked. The result is predictable + performance. + + When a session is initiated across an APPN network, the session's + mode is mapped into a COS and transmission priority. For each COS, + APPN has a COS table that is used in the route selection process to + select the most appropriate TGs (based on their TG characteristics) + for the session to traverse. The TG characteristics and COS tables + are defined such that APPN topology and routing services (TRS) will + select the appropriate TG for the traffic of each COS. + +2.6.3 Default TG Characteristics + + In Chapter 7 (TRS) of [1], there is a set of SNA-defined TG default + profiles. When a TG (connection network or regular) is defined as + being of a particular technology (e.g., ethernet or X.25) without + specification of the TG's characteristics, parameters from the + technology's default profile are used in the TG's topology entry. + The customer is free to override these values via configuration. + Some technologies have multiple profiles (e.g., ISDN has both a + profile for switched and nonswitched.) Two default profiles are + required for IP TGs. This many are needed because there are both + campus and wide-area IP networks. As a result for each HPR/IP TG, a + customer should specify, at minimum, campus or wide area. HPR/IP TGs + traversing the Internet should be specified as wide-area links. If + no specification is made, a campus network is assumed. + + The 2 IP profiles are as follows: + ++----------------------------------------------------------------------+ +| Table 3. IP Default TG Characteristics | ++-------------------+---------+----------+---------+---------+---------+ +| | Cost | Cost per | Security| Propa- | Effec- | +| | per | byte | | gation | tive | +| | connect | | | delay | capacity| +| | time | | | | | ++-------------------+---------+----------+---------+---------+---------+ +| Campus | 0 | 0 | X'01' | X'71' | X'75' | ++-------------------+---------+----------+---------+---------+---------+ +| Wide area | 0 | 0 | X'20' | X'91' | X'43' | ++-------------------+---------+----------+---------+---------+---------+ + + + + +Dudley Informational [Page 36] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + Typically, a TG is either considered to be "free" if it is owned or + leased or "costly" if it is a switched carrier facility. Free TGs + have 0 for both cost parameters, and costly TGs have 128 for both + parameters. For campus IP networks, the default for both cost + parameters is 0. + + It is less clear what the defaults should be for wide area. Because + a router normally has leased access to an IP network, the defaults + for both costs are also 0. This assumes the IP network is not + tariffed. However, if the IP network is tariffed, then the customer + should set the cost per byte to 0 or 128 depending on whether the + tariff contains a component based on quantity of data transmitted, + and the customer should set the cost per connect time to 0 or 128 + based on whether there is a tariff component based on connect time. + Furthermore, for switched access to the IP network, the customer + settings for both costs should also reflect the tariff associated + with the switched access link. + + Only architected values (see "Security" in [1]) may be used for a + TG's security parameter. The default security value is X'01' + (lowest) for campus and X'20' (public switched network; secure in the + sense that there is no predetermined route the traffic will take) for + wide-area IP networks. The network administrator may override the + default value but should, in that case, ensure that an appropriate + level of security exists. + + For wide area, the value X'91' (packet switched) is the default for + propagation delay; this is consistent with other wide-area facilities + and indicates that IP packets will experience both terrestrial + propagation delay and queueing delay in intermediate routers. This + value is suitable for both the Internet and wide-area intranets; + however, the customer could use different values to favor intranets + over the Internet during route selection. The value X'99' (long) may + be appropriate for some international links across the Internet. For + campus, the default is X'71' (terrestrial); this setting essentially + equates the queueing delay in IP networks with terrestrial + propagation delay. + + For wide area, X'43' (56 kbs) is shown as the default effective + capacity; this is at the low-end of typical speeds for wide-area IP + links. For campus, X'75' (4 Mbs) is the default; this is at the + low-end of typical speeds for campus IP links. However, customers + should set the effective capacity for both campus and wide area IP + links based on the actual physical speed of the access link to the IP + network; for regular links, if both the source and destination access + speeds are known, customers should set the effective capacity based + on the minimum of these two link speeds. If there are multiple + access links, the capacity setting should be based on the physical + + + +Dudley Informational [Page 37] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + speed of the access link that is expected to be used for the link. + + For the encoding technique for effective capacity in the topology + database, see "Effective Capacity" in Chapter 7, Topology and Routing + Services of [1]. The table in that section can be extended as + follows for higher speeds: + ++----------------------------------------------------------------------+ +| Table 4. Calculated Effective Capacity Representations | ++-----------------------------------+----------------------------------+ +| Link Speed (Approx.) | Effective Capacity | ++-----------------------------------+----------------------------------+ +| 25M | X'8A' | ++-----------------------------------+----------------------------------+ +| 45M | X'91' | ++-----------------------------------+----------------------------------+ +| 100M | X'9A' | ++-----------------------------------+----------------------------------+ +| 155M | X'A0' | ++-----------------------------------+----------------------------------+ +| 467M | X'AC' | ++-----------------------------------+----------------------------------+ +| 622M | X'B0' | ++-----------------------------------+----------------------------------+ +| 1G | X'B5' | ++-----------------------------------+----------------------------------+ +| 1.9G | X'BC' | ++-----------------------------------+----------------------------------+ + +2.6.4 SNA-Defined COS Tables + + SNA-defined batch and interactive COS tables are provided in [1]. + These tables are enhanced in [2] (see section 18.7.2) for the + following reasons: + + o To ensure that the tables assign reasonable weights to ATM TGs + relative to each other and other technologies based on cost, + speed, and delay + + o To facilitate use of other new higher-speed facilities - This + goal is met by providing several speed groupings above 10 Mbps. + To keep the tables from growing beyond 12 rows, low-speed + groupings are merged. + + Products implementing the native IP DLC should use the new COS + tables. Although the effective capacity values in the old tables are + sufficient for typical IP speeds, the new tables are valuable because + higher-speed links can be used for IP networks. + + + +Dudley Informational [Page 38] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + +2.6.5 Route Setup over HPR/IP links + + The Resequence ("REFIFO") indicator is set in Route Setup request and + reply when the RTP path uses a multi-link TG because packets may not + be received in the order sent. The Resequence indicator is also set + when the RTP path includes an HPR/IP link as packets sent over an IP + network may arrive out of order. + + Adaptive rate-based congestion control (ARB) is an HPR Rapid + Transport Protocol (RTP) function that controls the data transmission + rate over RTP connections. ARB also provides fairness between the + RTP traffic streams sharing a link. For ARB to perform these + functions in the IP environment, it is necessary to coordinate the + ARB parameters with the IP TG characteristics. This is done for IP + links in a similar manner to that done for other link types. + +2.6.6 Access Link Queueing + + Typically, nodes implementing the native IP DLC have an access link + to a network of IP routers. These IP routers may be providing + prioritization based on UDP port numbers or IP precedence. A node + implementing the native IP DLC can be either an IP host or an IP + router; in both cases, such nodes should also honor the priorities + associated with either the UDP port numbers or the IP precedence when + transmitting HPR data over the access link to the IP network. + +-------------------------------------------------------------------- + +*--------* access link *--------* *--------* +| HPR |-------------| IP |-----| IP | +| node | | Router | | Router | +*--------* *--------* *--------* + | | + | | + | | + *--------* *--------* access link *--------* + | IP |-----| IP |-------------| HPR | + | Router | | Router | | node | + *--------* *--------* *--------* + + +-------------------------------------------------------------------- + Figure 13. Access Links + + Otherwise, the priority function in the router network will be + negated with the result being HPR interactive traffic delayed by + either HPR batch traffic or the traffic of other higher-layer + protocols at the access link queues. + + + +Dudley Informational [Page 39] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + +2.7 Port Link Activation Limits + + Three parameters are provided by NOF to CS on DEFINE_PORT(RQ) to + define the link activation limits for a port: total limit, inbound + limit, and outbound limit. The total limit is the desired maximum + number of active link stations allowed on the port for both regular + TGs and connection network TGs. The inbound limit is the desired + number of link stations reserved for connections initiated by + adjacent nodes; the purpose of this field is to insure that a minimum + number of link stations may be activated by adjacent nodes. The + outbound limit is the desired number of link stations reserved for + connections initiated by the local node. The sum of the inbound and + outbound limits must be less than or equal to the total limit. If + the sum is less than the total limit, the difference is the number of + link stations that can be activated on a demand basis as either + inbound or outbound. These limits should be based on the actual + adapter capability and the node's resources (e.g., control blocks). + + A connection network TG will be reported to topology as quiescing + when its port's total limit threshold is reached; likewise, an + inactive auto-activatable regular TG is reported as nonoperational. + When the number of active link stations drops far enough below the + threshold (e.g., so that at least 20 percent of the original link + activation limit has been recovered), connection network TGs are + reported as not quiescing, and auto-activatable TGs are reported as + operational. + +2.8 Network Management + + APPN and HPR management information is defined by the APPN MIB (RFC + 2155 [11]) and the HPR MIB (RFC 2238 [13]). In addition, the SNANAU + working group of the IETF plans to define an HPR-IP-MIB that will + provide HPR/IP-specific management information. In particular, this + MIB will provide a mapping of APPN traffic types to IP Type of + Service Precedence values, as well as a count of UDP packets sent for + each traffic type. + + There are also rules that must be specified concerning the values an + HPR/IP implementation returns for objects in the APPN MIB: + + o Several objects in the APPN MIB have the syntax IANAifType. The + value 126, defined as "IP (for APPN HPR in IP networks)" should + be returned by the following three objects when they identify an + HPR/IP link: + + - appnPortDlcType + - appnLsDlcType + - appnLsStatusDlcType + + + +Dudley Informational [Page 40] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + o Link-level addresses are reported in the following objects: + + - appnPortDlcLocalAddr + - appnLsLocalAddr + - appnLsRemoteAddr + - appnLsStatusLocalAddr + - appnLsStatusRemoteAddr + + All of these objects should return ASCII character strings that + represent IP addresses in the usual dotted-decimal format. (At + this point it's not clear what the "usual...format" will be for + IPv6 addresses, but whatever it turns out to be, that is what + these objects will return when an HPR/IP link traverses an IP + network.) + + o The following two objects return Object Identifiers that tie + table entries in the APPN MIB to entries in lower-layer MIBs: + + - appnPortSpecific + - appnLsSpecific + + Both of these objects should return the same value: a RowPointer + to the ifEntry in the agent's ifTable for the physical interface + associated with the local IP address for the port. If the agent + implements the IP-MIB (RFC 2011 [12]), this association between + the IP address and the physical interface will be represented in + the ipNetToMediaTable. + +2.9 IPv4-to-IPv6 Migration + + The native IP DLC is architected to use IP version 4 (IPv4). + However, support for IP version 6 (IPv6) may be required in the + future. + + IP routers and hosts can interoperate only if both ends use the same + version of the IP protocol. However, most IPv6 implementations + (routers and hosts) will actually have dual IPv4/IPv6 stacks. IPv4 + and IPv6 traffic can share transmission facilities provided that the + router/host at each end has a dual stack. IPv4 and IPv6 traffic will + coexist on the same infrastructure in most areas. The version number + in the IP header is used to map incoming packets to either the IPv4 + or IPv6 stack. A dual-stack host which wishes to talk to an IPv4 + host will use IPv4. + + Hosts which have an IPv4 address can use it as an IPv6 address using + a special IPv6 address prefix (i.e., it is an embedded IPv4 address). + This mapping was provided mainly for "legacy" application + compatibility purposes as such applications don't have the socket + + + +Dudley Informational [Page 41] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + structures needed to store full IPv6 addresses. Two IPv6 hosts may + communicate using IPv6 with embedded-IPv4 addresses. + + Both IPv4 and IPv6 addresses can be stored by the domain name service + (DNS). When an application queries DNS, it asks for IPv4 addresses, + IPv6 addresses, or both. So, it's the application that decides which + stack to use based on which addresses it asks for. + + Migration for HPR/IP ports will work as follows: + + An HPR/IP port is configured to support IPv4, IPv6, or both. If IPv4 + is supported, a local IPv4 address is defined; if IPv6 is supported, + a local IPv6 address (which can be an embedded IPv4 address) is + defined. If both IPv4 and IPv6 are supported, both a local IPv4 + address and a local IPv6 address are defined. + + Defined links will work as follows: If the local node supports IPv4 + only, a destination IPv4 address may be defined, or an IP host name + may be defined in which case DNS will be queried for an IPv4 address. + If the local node supports IPv6 only, a destination IPv6 address may + be defined, or an IP host name may be defined in which case DNS will + be queried for an IPv6 address. If both IPv4 and IPv6 are supported, + a destination IPv4 address may be defined, a destination IPv6 address + may be defined, or an IP host name may be defined in which case DNS + will be queried for both IPv4 and IPv6 addresses; if provided by DNS, + an IPv6 address can be used, and an IPv4 address can be used + otherwise. + + Separate IPv4 and IPv6 connection networks can be defined. If the + local node supports IPv4, it can define a connection network TG to + the IPv4 VRN. If the local node supports IPv6, it can define a TG to + the IPv6 VRN. If both are supported, TGs can be defined to both + VRNs. Therefore, the signaling information received in RSCVs will be + compatible with the local node's capabilities unless a configuration + error has occurred. + +3.0 References + + [1] IBM, Systems Network Architecture Advanced Peer-to-Peer + Networking Architecture Reference, SC30-3442-04. Viewable at URL: + http://www.raleigh.ibm.com/cgi-bin/bookmgr/BOOKS/D50L0000/CCONTENTS + + [2] IBM, Systems Network Architecture Advanced Peer-to-Peer + Networking High Performance Routing Architecture Reference, Version + 3.0, SV40-1018-02. Viewable at URL: http://www.raleigh.ibm.com/cgi- + bin/bookmgr/BOOKS/D50H6001/CCONTENTS + + + + + +Dudley Informational [Page 42] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + [3] IBM, Systems Network Architecture Formats, GA27-3136-16. + Viewable at URL: http://www.raleigh.ibm.com/cgi- + bin/bookmgr/BOOKS/D50A5003/CCONTENTS + + [4] Wells, L. and A. Bartky, "Data Link Switching: Switch-to-Switch + Protocol, AIW DLSw RIG: DLSw Closed Pages, DLSw Standard Version + 1.0", RFC 1795, April 1995. + + [5] Bryant, D. and P. Brittain, "APPN Implementers' Workshop Closed + Pages Document DLSw v2.0 Enhancements", RFC 2166, June 1997. + + [6] Postel, J., "User Datagram Protocol", STD 6, RFC 768, August + 1980. + + [7] Postel, J., "Internet Protocol", STD 5, RFC 791, September 1981. + + [8] Almquist, P., "Type of Service in the Internet Protocol Suite", + RFC 1349, July 1992. + + [9] Braden, R., "Requirements for Internet Hosts -- Communication + Layers", STD 3, RFC 1122, October 1989. + + [10] Braden, R., Zhang, L., Berson, S., Herzog, S., and S. Jamin, + "Resource ReSerVation Protocol (RSVP) -- Version 1 Functional + Specification", RFC 2205, September 1997. + + [11] Clouston, B., and B. Moore, "Definitions of Managed Objects for + APPN using SMIv2", RFC 2155, June 1997. + + [12] McCloghrie, K., "SNMPv2 Management Information Base for the + Internet Protocol using SMIv2", RFC 2011, November 1996. + + [13] Clouston, B., and B. Moore, "Definitions of Managed Objects for + HPR using SMIv2", RFC 2238, November 1997. + +4.0 Security Considerations + + For HPR, the IP network appears to be a link. For that reason, the + SNA session-level security functions (user authentication, LU + authentication, session encryption, etc.) are still available for + use. In addition, as HPR traffic flows as UDP datagrams through the + IP network, IPsec can be used to provide network-layer security + inside the IP network. + + There are firewall considerations when supporting HPR traffic using + the native IP DLC. First, the firewall filters can be set to allow + the HPR traffic to pass. Traffic can be restricted based on the + source and destination IP addresses and the destination port number; + + + +Dudley Informational [Page 43] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + + the source port number is not relevant. That is, the firewall should + accept traffic with the IP addresses of the HPR/IP nodes and with + destination port numbers in the range 12000 to 12004. Second, the + possibility exists for an attack using forged UDP datagrams; such + attacks could cause the RTP connection to fail or even introduce + false data on a session. In environments where such attacks are + expected, the use of network-layer security is recommended. + +5.0 Author's Address + + Gary Dudley + C3BA/501 + IBM Corporation + P.O. Box 12195 + Research Triangle Park, NC 27709, USA + + Phone: +1 919-254-4358 + Fax: +1 919-254-6243 + EMail: dudleyg@us.ibm.com + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Dudley Informational [Page 44] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + +6.0 Appendix - Packet Format + +6.1 HPR Use of IP Formats + ++----------------------------------------------------------------------+ +| 6.1.1 IP Format for LLC Commands and Responses | +| | +| The formats described here are used for the | +| following LLC commands and responses: XID | +| command and response, TEST command and response, | +| DISC command, and DM response. | ++----------------------------------------------------------------------+ + + ++----------------------------------------------------------------------+ +| IP Format for LLC Commands and Responses | ++-------+-----+--------------------------------------------------------+ +| Byte | Bit | Content | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| 0-p | | IP header (see note 1) | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| p+1- | | UDP header (see note 2) | +| p+8 | | | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| p+9- | | IEEE 802.2 LLC header (see note 3) | + _____________________ +| p+11 | | | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| p+9 | | DSAP: same as for the base APPN (i.e., X'04' or an | +| | | installation-defined value) | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| p+10 | | SSAP: same as for the base APPN (i.e., X'04' or an | +| | | installation-defined value) | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| p+11 | | Control: set as appropriate | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| p+12-n| | Remainder of PDU: XID3 or TEST information field, or | +| | | null for DISC command and DM response | ++-------+-----+--------------------------------------------------------+ + + + + + +Dudley Informational [Page 45] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + ++-------+-----+--------------------------------------------------------+ +| | | Note 1: Rules for encoding the IP header can be found | +| | | in RFC 791. | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| | | Note 2: Rules for encoding the UDP header can be | +| | | found in RFC 768. | ++-------+-----+--------------------------------------------------------+ + ++----------------------------------------------------------------------+ +| IP Format for LLC Commands and Responses | ++-------+-----+--------------------------------------------------------+ +| Byte | Bit | Content | ++-------+-----+--------------------------------------------------------+ + ++-------+-----+--------------------------------------------------------+ +| | | Note 3: Rules for encoding the IEEE 802.2 LLC header | +| | | can be found in ISO/IEC 8802-2:1994 (ANSI/IEEE Std | +| | | 802.2, 1994 Edition), Information technology - | +| | | Telecommunications and information exchange between | +| | | systems - Local and metropolitan area networks - | +| | | Specific requirements - Part 2: Logical Link Control. | ++-------+-----+--------------------------------------------------------+ + ++----------------------------------------------------------------------+ +| 6.1.2 IP Format for NLPs in UI Frames | +| | +| This format is used for either LDLC specific | +| messages or HPR session and control traffic. | ++----------------------------------------------------------------------+ ++----------------------------------------------------------------------+ +| IP Format for NLPs in UI Frames | ++-------+-----+--------------------------------------------------------+ +| Byte | Bit | Content | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| 0-p | | IP header (see note 1) | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| p+1- | | UDP header (see note 2) | +| p+8 | | | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| p+9- | | IEEE 802.2 LLC header | + _____________________ +| p+11 | | | ++-------+-----+--------------------------------------------------------+ + + + + +Dudley Informational [Page 46] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + ++-------+-----+--------------------------------------------------------+ +| p+9 | | DSAP: the destination SAP obtained from the IEEE | +| | | 802.2 LLC (X'80') subfield in the HPR Capabilities | +| | | (X'61') control vector in the received XID3 (see note | +| | | 3) | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| p+10 | | SSAP: the source SAP obtained from the IEEE 802.2 LLC | +| | | (X'80') subfield in the HPR Capabilities (X'61') | +| | | control vector in the sent XID3 (see note 4) | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| p+11 | | Control: | ++-------+-----+-------+------------------------------------------------+ +| | | X'03' | UI with P/F bit off | ++-------+-----+-------+------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| p+12-n| | Remainder of PDU: NLP | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| | | Note 1: Rules for encoding the IP header can be found | +| | | in RFC 791. | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| | | Note 2: Rules for encoding the UDP header can be | +| | | found in RFC 768. | ++-------+-----+--------------------------------------------------------+ ++----------------------------------------------------------------------+ +| IP Format for NLPs in UI Frames | ++-------+-----+--------------------------------------------------------+ +| Byte | Bit | Content | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| | | Note 3: The User-Defined Address bit is considered | +| | | part of the DSAP. The Individual/Group bit in the | +| | | DSAP field is set to 0 by the sender and ignored by | +| | | the receiver. | ++-------+-----+--------------------------------------------------------+ ++-------+-----+--------------------------------------------------------+ +| | | Note 4: The User-Defined Address bit is considered | +| | | part of the SSAP. The Command/Response bit in the | +| | | SSAP field is set to 0 by the sender and ignored by | +| | | the receiver. | ++-------+-----+--------------------------------------------------------+ + + + + + + + +Dudley Informational [Page 47] + +RFC 2353 APPN/HPR in IP Networks May 1998 + + +7.0 Full Copyright Statement + +Copyright (C) The Internet Society (1997). All Rights Reserved. + +This document and translations of it may be copied and furnished to +others, and derivative works that comment on or otherwise explain it or +assist in its implementation may be prepared, copied, published and +distributed, in whole or in part, without restriction of any kind, +provided that the above copyright notice and this paragraph are included +on all such copies and derivative works. However, this document itself +may not be modified in any way, such as by removing the copyright notice +or references to the Internet Society or other Internet organizations, +except as needed for the purpose of developing Internet standards in +which case the procedures for copyrights defined in the Internet +Standards process must be followed, or as required to translate it into +languages other than English. + +The limited permissions granted above are perpetual and will not be +revoked by the Internet Society or its successors or assigns. + +This document and the information contained herein is provided on an "AS +IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING TASK +FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT +LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN WILL NOT +INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR +FITNESS FOR A PARTICULAR PURPOSE. + + + + + + + + + + + + + + + + + + + + + + + + + +Dudley Informational [Page 48] + -- cgit v1.2.3