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/rfc1029.txt | 949 ++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 949 insertions(+) create mode 100644 doc/rfc/rfc1029.txt (limited to 'doc/rfc/rfc1029.txt') diff --git a/doc/rfc/rfc1029.txt b/doc/rfc/rfc1029.txt new file mode 100644 index 0000000..2b8e25b --- /dev/null +++ b/doc/rfc/rfc1029.txt @@ -0,0 +1,949 @@ +Network Working Group G. Parr +Request For Comments: 1029 University of Ulster + May 1988 + + + A MORE FAULT TOLERANT APPROACH TO ADDRESS RESOLUTION FOR + A MULTI-LAN SYSTEM OF ETHERNETS + +STATUS OF THIS MEMO + + This memo discusses an extension to a Bridge Protocol to detect and + disclose changes in neighbouring host address parameters in a Multi- + LAN system of Ethernets. The problem is one which is appearing more + and more regularly as the interconnected systems grow larger on + Campuses and in Commercial Institutions. This RFC suggests a + protocol enhancement for the Internet community, and requests + discussion and suggestions for improvements. Distribution of this + memo is unlimited. + +ABSTRACT + + Executing a protocol P, a sending host S decides, through P's routing + mechanism, that it wants to transmit to a target host T located + somewhere on a connected piece of 10Mbit Ethernet cable which + conforms to IEEE 802.3. To actually transmit the Ethernet packet, a + 48 bit Ethernet/hardware address must be generated. The addresses + assigned to hosts within protocol P are not always compatible with + the corresponding Ethernet address (being different address space + byte orderings or values). A protocol is presented which allows + dynamic distribution of the information required to build tables that + translate a host's address in protocol P's address space into a 48 + bit Ethernet address. An extension is incorporated to allow such a + protocol to be flexible enough to exist in a Transparent Bridge, or + generic Host. The capability of the Bridge to detect host reboot + conditions in a multi-LAN environment is also discussed, emphasising + particularly the effect on channel bandwidth. To illustrate the + operation of the protocol mechanisms, the Internet Protocol (IP) is + used as a benchmark [6], [8]. Part 1 presents an introduction to + Address Resolution, whilst Part 2 discusses a reboot detection + process. + +DEFINITIONS: + + CATENET: a group of IP networks linked together + IP : Internet Protocol + + + + + + +Parr [Page 1] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + PART 1 + +INTRODUCTION + + In the Ethernet, while all packets are broadcast, the hardware + interface selects only those with either the explicit hardware + broadcast address or the individual hardware address of this + interface. Packets which do not have one of these two addresses are + rejected by the interface and do not get passed to the host software. + This saves a great deal of otherwise wasted effort by the host + software having to examine packets and reject them. If the interface + hardware selected packets to pass to the host software by means of + the protocol address, there would be no need for any translation from + protocol to Ethernet address. Although it is very important to + minimize the number of packets which each host must examine, so + reducing especially needless inspections, use of the hardware + broadcast address should be confined to those situations where it is + uniquely beneficial. Perhaps if one were designing a new local + network one could eliminate the need for an address translation, but + in the real world of existing networks it fills a very important + purpose. A rare use of the broadcast hardware address, which avoids + putting any processing load on the other hosts of the Ethernet, is + where hosts obtain the information they need to use the specific and + individual hardware addresses to exchange most of their packets. + +REASONING BEHIND ADDRESS RESOLUTION + + The process of converting from the logical host address to the + physical Ethernet address has been termed ADDRESS RESOLUTION, and has + prompted research into a method which can be easily interfaced, + whilst at the same time remaining portable. + + The Ethernet requires 48 bit addresses on the physical cable [11] due + to the fact that the manufacturers of the LAN interface controllers + assign a unique 48 bit address during production. Of course, Network + Managers do not want to be bothered using this address to identify + the destination at the higher-level. Rather, they would prefer to + assign their logical names to the hosts within their supervision, and + allow some lower level protocol to perform a resolving operation. + Most of these logical protocol addresses are not 48 bits long, nor do + they necessarily have any relationship to the 48 bit address space. + + For example, IP addresses have a 32 bit address space [6], thus + giving rise to the need to distribute dynamically the correspondences + between a pair, and a 48 bit Ethernet + address. + + + + + +Parr [Page 2] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + +EXAMPLE ARP OPERATION + + Here is a review of the operation of ARP as defined in RFC-826 [5]. + Let hosts X and Y exist on the same Ethernet cable. They have + physical Ethernet addresses EA(X), and EA(Y), and DoD Internet + addresses IPA(X), and IPA(Y). Let the Ethernet type of Internet be + ET(IP). Host X begins an application, and sooner or later wishes to + communicate an Internet packet to host Y. Host X has knowledge of + the Internet address of Y, i.e., (IPA(Y)), and informs the lower + level that it wishes to talk to IPA(Y). The lower-level subsequently + consults the ARP Module (ARM) to convert into a 48 + bit Ethernet address but because X has not talked to Y previously, it + does not have this information in its Translation Cache (TC). It + discards (or queues) the Internet packet, and creates a new Address + Resolution packet with: + + PACKET FIELD VALUE ASSIGNED + + HRDTYP ETHERNET + + PROTYP ET(IP) + + HRDLEN length (EA(X)) + + PROTLEN length (IPA(X)) + + ARPOPC REQUEST + + SOURCE HWR EA(X) + + SOURCE PROT IPA(X) + + TARGET HWR don't know + + TARGET PROT IPA(Y) + + It then broadcasts this packet to all hosts on the connecting cable. + Host Y picks up this packet and determines that it understands the + hardware type (Ethernet), that it speaks the indicated protocol + (Internet), and that the packet is for it, that is, TARGET PROTOCOL + ADDRESS = IPA(Y). Replacing any previous entry, it enters the + information that -->EA(Y), + notices that it is a REPLY, and discards the packet (i.e., disposes + of the dynamic packet buffer). However, if the original Internet + Module packet had been queued, it could have been accessed and given + the full addressing information from the translation cache. + Alternatively, had it been discarded, the higher level would have + succeeded on a subsequent attempt, and the Internet packet would be + transmitted immediately. + +OBTAINING GREATER NETWORKING RANGE + + There are many benefits to be gained in dividing a large multiuser + network into smaller, more manageable networks. These include : Data + Security; Overall Network Reliability; Performance Enhancement; not + to mention the most obvious: Greater Networking Range. In some + network technologies, cable length may be stipulated not to exceed a + certain range due to electrical limitations. By installing a Bridge, + this restriction is effectively eliminated. An important + consideration is the effect the induced Bridge delays will have on + the protocol timeouts in operation on each LAN/Subnet. Careful + analysis of upper bounds on timeouts would have to be made in order + to gain full benefit from the increased range. In the case of + Ethernet the following system parameters exist [11], [12]: + + - the bus bandwidth is 10Mbit/s + + - the maximum node-to-node cable length is 1500 m + + - the maximum point-to-point link cable length is 1000 m + + - the maximum number of repeaters between two nodes is two + + - the worst case end-to-end bus propagation delay is 22.5 us + + - the jam time after collision is 32bit + + - the minimum interframe time is 9.6 us + + - the slot size is 512 bit = 51.2 us + + Once a decision has being taken to subnet, the resulting subLANs may + be connected by including a Bridge to link them together and + providing a protocol which makes the collection of subnets appear as + a single network. The basic idea of the Bridge providing 'repeater' + facilities would not suffice in this application. Moreover, the + Bridge would have to have further 'intelligence' to enable it to + select those packets which are destined for remote networks based on + + + +Parr [Page 4] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + the protocol address of the target host. Thereby preventing it from + forwarding packets needlessly that will not be accepted. If this + procedure was not adhered to, the channel bandwidth on the remote + networks would be inundated with packets, causing local valid traffic + to backoff and the efficiency of the respective networks to rapidly + decrease. + + One problem fundamental to the operation of the Bridge is how it + discovers on which LAN a particular host is interfaced. If there are + only two LANs in the system, each will have a dedicated cache at the + Bridge, and when a packet is received at the particular interface, + the source host's address parameters are entered in the respective + LAN cache. However, when we consider a Multi-LAN environment, the + procedure becomes more complicated. + + ___ + | + |-----h3 + | E4 + |-----hq |-----------------------| + | _ | | + |-----hx | | B1 | | + |---------------| | | | + |-----h1 |_| | | + | | h19 | | ______ + | | | | | -----|______| B4 + | | | | | B3 | + |-----he |-------------------| E2 |_| | + | | | | + |-----h5 | | | + | | | | + | --- --- | | + --- | | |------- | + E1 | | B2 | | + | |-----------------| | + --- | | + | |--------------------- + --- | + E3 | + | + FIGURE 1. A MULTI-LAN TOPOLOGY + + + In the normal set-up, whenever B3 or B4 would receive a packet on E4, + they would both update the caches on their E4 interface. In + addition, a method must be provided to permit B4 to distinguish + between packets arriving on E4 from E1, E2, E3, and those which + actually originated on E4. + + + +Parr [Page 5] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + This is so that packets can be categorized as being of remote or + local source and processed accordingly. The most obvious solution is + for each Bridge to act as an AGENT and plug in its address as the + source of any packets it cascades to a remote network, instead of the + packet being cascaded with its original source address. At Bridge + boot, it may issue a broadcast request for all locally connected + hosts/devices to return their local network protocol addresses. On + subsequent receipt of this information, the Bridge could then update + the cache for each of its interfaces so that it would now have a base + from which to perform future operations. + + The alternative to this automatic procedure is to permit manual + intervention in the Bridge software which could be activated by the + network manager in order to key in the addresses of the hosts + connected to each LAN interface. + + Thus, having provided a means for the Bridge to obtain the original + state of the LAN addresses when it boots, how then does the Bridge + distinguish the arrival of a new host on the locally connected system + from transmissions which were sent from a remote source and cascaded + by an adjacent Bridge? Two approaches are currently under + consideration to solve this problem, namely Explicit Subnets, and + Transparent Subnets [4], [7], [9], [14]. + + In the Explicit Subnet approach, the location of the host in the + system is important. The address of the host in the protocol suite + will reflect which subnet the host is interfaced to. Consequently + the protocol address space is divided into a three level hierarchy of + . Within the Internet there are five addressing + divisions in operation [10], classes A, B, C, D, and E. Classes D + and E relate to an addressing technique that will be used for + management of multi-casting groups and will not be discussed here. + With such a structure, it is possible to provide an address mask at + each interface so that received packets may have their source address + fields examined and compared with the address mask of this LAN. In + so doing, the component which is being verified is actually the + subnet address. If the masking operation is successful the source + must exist on this LAN, otherwise it must be remote. + + With the Transparent scheme, the first time a newly booted host + 'speaks' it will be looking for addressing information (probably + using BOOTSTRAP [1], RARP [2] or ARP [5]). Accordingly, the Bridge + will detect these respective requests and be in a position to perform + operations on the address parameters. The current approach in + Transparent Subnetting is that before any such requests can be + cascaded by the Bridge to an adjacent LAN, that Bridge will place its + interface address parameters into the source address fields, thus + acting as the AGENT. Therefore, this Bridge will 'see' either + + + +Parr [Page 6] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + packets arriving from the remote Bridge address, or local packets. + By virtue of the RARP/ARP operation, which hosts perform when they + first come up, any hi-level packets received on to the network not + having the bridge address, and not having a mapping in the cache for + that LAN, can be considered as being remote. + + Currently, there is a move toward the Transparent subnet proposal + originally described by Postel [7]. This has been due mainly to + practical problems of incompatible implementations from different + vendors, and the restrictions that the Explicit address space place + on the adaptability of the system to change (class C addresses are + not flexible enough for the Explicit scheme). It is also the opinion + of the Author of this paper that the Agent technique adopted by the + Bridges could have shortcomings in a dynamic environment which would + be detrimental to its operation; for example, where the bridges + themselves relocate or crash, or in the management of the "Agent For + Who" cache at the bridge. Insofar as Loop Resolution and + SelfStabilization after failure are Bridge problems that need to be + addressed, it is strongly felt their satisfactory solution will be + supported by elimination of the Agent technique [13]. + +BRIDGE OPERATIONS + + Referring to figure 1, assume that at some stage during its + processing [E1H3] wishes to communicate with [E2H19]. [E1H3] obtains + knowledge of the Internet address of [E2H19] from its translation + cache, but will not require the knowledge that [E2H19] exists on a + completely different subnet. [E1H3] calls its Internet Module to + transmit the packet. As detailed, the usual procedure of passing + control to its ARM is performed in an attempt to obtain a + translation. If we assume that [E1H3], and [E2H19] have not talked + before, the ARM in [E1H3] will not be able to resolve the addresses + on the first attempt. + + In such a case, an ARREQ packet is assembled and broadcast to all + hosts on the network [E1]. The packet traverses the cable and is + eventually picked up by the (B1) Bridge Address Resolution Module + (BARM), whereupon it determines whether or not it should intervene in + the request. If the target is determined as remote (i.e., having no + match in the local cache), the BARM examines its Global Translation + Cache (GTC) to determine if it has an entry for . + Should a mapping be obtained at the Bridge, there is no need for the + broadcast REQUEST packet to be cascaded on to the remote network + [E2]. It is therefore assumed that the entries in the GTC reflect + the most current addressing information. A match thus obtained, the + original ARREQ packet buffer is adapted as required and returned + directly to [E1H3] via the Bridges hardware interface IFE1. + + + + +Parr [Page 7] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + On the other hand, should the Bridges' GTC have no information on + [E2H19], the BARM would have to perform the following steps: + + 1. drop the current ARREQ from [E1H3], + + 2. create its own ARREQ using the Bridge source addresses + and copy the target_internet_addr from the original + [E1H3] ARREQ packet, + + 3. broadcast the ARREQ on network E2 via network interface + IFE2, and go into a timeout awaiting a REPLY. + + Should this timeout period expire, a number of retries will be + permitted under control of the BARM. Alternatively, if a REPLY is + received within the timeout interval, then the BARM will update its + GTC. The ARM of [E1H3] next will attempt to transmit another ARREQ, + but this time a mapping will be obtained at the BARM'S GTC, and the + appropriate REPLY will be returned. + + Part 1 has described the state of the art of the behaviour of Address + Resolution. Part 2 now extends the study to the more serious problem + of rebooting hosts in a multi-LAN system of Ethernets, and the + effects such changes have on the integrity of state information held + in ARP caches and routing tables. + + PART 2 + +THE CAPTURE OF REBOOTS + + Because Address Resolution packets are broadcast, all hosts on the + connecting cable including the Transparent Bridge will pick them up + and determine what they are. Referring to figure 1, it may well be + the case that a host on E1 wishes to communicate with a fellow host + on the same physical ether. Hence, if Hx wishes to talk to Hw on the + same ether, but has not done so previously, it will broadcast an + Address Resolution packet in the normal fashion. The Bridge will + also 'see' the packet as it passes by, and will act as described + above, unless that is, there is some method of preventing it doing + so; there is no point in the Bridge invoking its ARM, and wasting + processing time if the problem is going to be resolved locally. + + It may occur however, that H1 wants to communicate with H5. If + however, H5 has not talked with anyone before (i.e., it has been + "dormant"), H1 will issue an ARREQ. The Bridge will not know that H5 + is local because it won't have been entered in the local address + cache from previous conversations. To avoid broadcasting an ARREQ to + all networks/subnets, one way around this problem is to set up the + contents of the local cache at Bridge startup time. Therefore, the + + + +Parr [Page 8] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + Bridge will already know not to intervene. Thus, if the Bridge (with + 2 nets) finds that a particular IP destination address is not in the + local cache of interface 1, it would have to examine its GTC and scan + it for a mapping. Should no mapping be obtained at interface 2, one + of two possibilities exist: + + 1. the target host doesn't exist locally + + 2. the caches are corrupt (the eventuality of this should + be negligible!) + + If it is assumed that each of the translation caches contains have + the most recent addressing information regarding its own domain of + the network then, in this example, if the Bridge does not get a + mapping at the GTC it would appear that the host must exist remotely + from E1, and E2. + + Such a conclusion would ignore cases in which a host unplugs from a + particular hardware interface and plugs into another hardware + interface, or where logical names are reassigned to different + interfaces due to host user change. Either of these events could + happen had the host being accessed on E2, which would mean that a + REBOOT has taken place. + + Anticipating these possiblities local caches are essential. In + normal operation, the Bridge will process and forward IP packets + received from one network, and destined for another. If the Bridge + picks up an ARREQ, it will first look for a mapping in its GTC before + discarding the original ARREQ, and transmitting its own to the remote + network. In any case, the Bridge will always examine the local cache + entries at the receiving interface, so that it may determine if the + target address is local or remote. When the Bridge first scans the + local cache, it does so with the source IP address as the key. If no + mapping is retrieved, it then scans the GTC with the same key. + Should a mapping now be obtained, it remains for the Bridge to insert + the source IP into the local cache, where it has either been + previously deleted or corrupted. + + However, if the source IP exists in the respective local cache, the + validity of the source Ethernet address should also be verified by + examining the respective entry in the GTC. A scan of the GTC is then + performed with as the key. If a mapping + is retrieved, the respective should be checked against the + source Ethernet address in the packet header. If the addresses do + not match, then we have uncovered a Hardware Reboot condition (i.e., + a change in Ethernet ID). On the other hand, should the scan of the + GTC with fail to obtain a mapping, then + the Bridge would scan the GTC with the current Ethernet address in + + + +Parr [Page 9] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + the packet header. If this obtains a mapping, then a Protocol Reboot + condition (i.e., change in logical ID) has been detected. + + In the next section, the implications of these forms of 'Reboot' are + discussed. + +REBOOT SCENARIO + + In normal operation, packets will uneventfully traverse each subnet + either as complete Internet packets, broadcast ARREQ's, or direct + ARREP's. The Bridge attached to each subnet will 'hear', and 'see' + all packets as they travel past its connected interfaces. Because of + the existence of the local caches at each interface, the Bridge can + decide whether or not to intervene. In general circumstances, each + host on the Catenet will have a translation cache containing + entries for all packets it + has observed. Most of these entries will have been due to processing + ARREQ packets, which were broadcast, and by receiving REPLY packets. + In accordance with the foregoing , the Bridge will have a cache + attached to each subnet interface containing entries for protocol + addresses. + + Within the Bridge's Global Translation Cache (GTC) will be entries of + all triplets relating to + valid hosts which have been recognised. If we assume that we have + just connected up a Catenet such as that illustrated in figure 1, + then at power-up no stations will have knowledge about their + neighbours. If the Bridges are to remain transparent, the + translation caches at each host will be totally empty. The only + addressing details that will be in existence will be the protocol + addresses stored in the local caches of the Bridges. + + The hosts subsequently begin to run applications and will want to + communicate with one another. The first ARREQ is broadcast on the + respective subnet and all hosts, including the Bridge's interface to + the subnet, will pick it up and store the details. If, for example, + Hx issues an ARREQ for Hq, the Bridge will not intervene since there + is no need (providing no reboot has occurred at Hq). However, if Hx + wishes to talk with Hz, B1 will determine that the target IP in the + respective ARREQ does not exist in the local cache of IFE1, so it + will examine the GTC, with the of Hw as + the key. + + It is assumed that there will be a timeout mechanism in operation at + the source of any packet. In addition, the Bridge may also place the + target address in a 'search list' of currently sought hosts, so as to + prevent ARREQs from different sources being cascaded for the same + target. Under these conditions, Hx may re-issue its original ARREQ, + + + +Parr [Page 10] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + but will be ignored until the host Hw has replied to the ARREQ + transmitted by the Bridge. + +NORMAL RUNNING STATE + + Assuming that a few ARP's have been issued, IP packets will start + traversing the Catenet with full addressing information. Again, the + Bridges will 'see' all the packets. If we extend the situation one + step further, and assume that several conversations have taken place + across the Catenet, there will be entries in the translation caches + of the hosts concerned, regarding the + triplets of those hosts + with which the conversations took place. The Bridges also, will have + details in their GTC's for packets which they cascaded. + + If a host is relocated, any connections initiated by that host will + still work, provided that its own translation cache is cleared when + it does physically move. However, any connections subsequently + initiated to it by other hosts on the Catenet will have no particular + reason to know to discard their old translation for that host. + Ideally, 48 bit Ethernet addresses will be unique and fixed for all + time. + +RECOGNITION OF THESE REBOOT CONDITIONS + + With reference to figure 1, assume that for some reason a fault + occurs on the hardware interface of . The result of this is + that a new interface is installed with a newly acquired hardware + address. When is powered up, the previous contents of its + translation cache are cleared and it has no recollection of local, or + remote host addresses. Accordingly, begins to issue ARREQ's + to hosts it requires. Whenever transmits its first ARREQ, it + could be termed a 'HELLO PACKET', since everyone on the subnet can + pick up the packet, and store the relevant information in their + translation caches. Within hosts, a mapping will be found on the old + pair, and the current of the + packet header will replace whatever is entered in the translation + cache. + + At this point it would be easy for each host with an entry to + recognise the Hardware Reboot situation and inform the subnet with a + respective broadcast reboot packet. But allowing such a procedure + would be extremly inefficient on the broadcast medium, and would + drastically outweigh any improvements in performance which might be + obtained in the long term. In any case, given the fact that the + ARREQ is broadcast, all stations on the subnet will recognise the + reboot. The important point to consider is the effect such a reboot + will have on subsequent conversations which are initiated remotely. + + + +Parr [Page 11] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + Can redundant transmissions be thwarted before they tie up processing + time on hosts en-route to the rebooted target? How these + difficulties are resolved is critical to the level of performance + obtained in a Catenet configuration. Since it is not optimal for + hosts to inform the system of a reboot, it is left to the Bridge. + Whenever the Bridge receives a packet, be it IP, or ARP, it examines + the source address parameters in the packet header, in the hope of + detecting any incompatibilities between them and the entries in its + caches. There are three distinct possibilities, namely, a difference + in the 48 bit hardware address only, a difference in the protocol + address, and two completely new addresses. If an incompatibility is + discovered, a "REBOOT" packet is constructed and issued on all remote + interfaces containing the appropiate information, allowing Bridges to + update their GTC's and generic hosts their ARP caches. + + The structure of the Reboot packet is as depicted in figure 2. + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | P A C K E T O P C O D E |REB OPC| S O U R C E | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | H A R D W A R E A D D R E S S | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | S O U R C E P R O T O C O L A D D R E S S | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | M U L T I C A S T T A R G E T H A R D W A R E | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | A D D R E S S | M U L T I C A S T T A R G E T | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | P R O T O C O L | + +-+-+-+-+-+-+-+-+-+-+-+-+ + + ---------> NEXT FOLLOWS A VARIANT FIELD ON REBOOT OPCODE + + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | O L D S O U R C E H A R D W A R E | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | A D D R E S S | + +-+-+-+-+-+-+-+-+-+-+-+-+ + + OR + + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | O L D S O U R C E P R O T O C O L A D D R E S S | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + FIGURE 2. REBOOT PACKET + + + +Parr [Page 12] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + The following definitions apply: + + PACKET FIELD VALUE + + OPCODE REBOOT + + REBOOT OPCODE HARDWARE + + REBOOT OPCODE PROTOCOL + + The format is then as follows: + + 48 bit broadcast Ethernet address for the destination, + + 48 bit Ethernet address of source Bridge, + + 16 bit Protocol type = PACKET OPCODE - REBOOT. + + + For completeness and error checking it may be an advantage to have a + field which specifies the length of addresses in the Ethernet and + protocol address spaces. Thus, the Reboot packet structure contains + the following: + + FIELD FIELD SIZE DESCRIPTION + + HRDLEN 4 bit byte length of Ethernet address + + PROTLEN 4 bit byte length of Protocol address + + + SOURCE + PROTOCOL + ADDRESS 32 bit current protocol address of host + + TARGET + PROTOCOL + ADDRESS 32 bit broadcast target protocol address + + REBOOT + OPCODE 4 bit will be either PROTOCOL or HARDWARE + + + if PROTOCOL 32 bit old protocol address + + else HARDWARE 48 bit old hardware address + + + + + +Parr [Page 13] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + As shown, depending on the REBOOT-OPCODE, the structure will continue + with either the 48 bit old hardware address or the 32 bit old + protocol address. The choice of a variant packet structure is for + reasons of curtailing the size of the packet to the fields that are + truely necessary in each situation. From this Reboot packet + structure, the process of generating such a packet can be considered. + When the Bridge algorithm detects a reboot, it should create a reboot + packet structure containing the relevant addressing information and + subsequently multicast it on the interface(s) which access(es) the + remote subnet(s). The decision as to which interface(s) is/are + local, and which is/are remote, can be resolved automatically + whenever a packet is received. With respect to this packet transfer + the receive interface at the Bridge becomes local, and all others are + tagged as remote. + + Thus, hosts on the subnet remote from the reboot are informed of the + situation immediately as it is detected by the Bridge. In the + Catenet configuration illustrated in fig 1, this will have the effect + of updating the Translation Cache within each host, whenever it + receives the packet. If for example, reboots under hardware, + B3 will detect this occurance. There is no reason for the subnets + E1, E2, E3 to be aware of this episode. In normal operation, B3 will + recognise the reboot from the first ARREQ issued from . With + this reboot detection facility, B3 will be in a position to inform + the hosts on E1, E2, and E3. B3 can then create and issue the Reboot + packet via its interface with E3. When B3 picks it up, it will + update its own caches and subsequently cascade the packet onto E2, + where it will be passed on to E1 via B1. + +ARGUMENTS FOR REBOOT PACKETS + + It is envisaged that introducing Reboot packets, will serve to + enhance the bandwidth achievable within a Catenet system. Problems + of addressing 'dead' hosts will no longer exist in a correctly + functioning configuration. Translation Caches will have on hand the + most recent addressing information available, which should also serve + to enhance the performance of the routing strategy in operation. + Multiple, redundant processing of packets destined for 'dead' hosts + will be avoided. Weighing this against the processing involved with + a single multicast of Reboot packets, it is expected that the latter + will be is the most economically viable in relation to the long-term + traffic presented to the system. + +CONCLUSION + + It appears that reboots are becoming increasingly common on internet + networks. Many sites use Personal Computers (PC) as terminals and + the typical way to finish a session is to switch them off! With the + + + +Parr [Page 14] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + increasing popularity of multitasking Operating Systems on these + types of machines, problems are more likely to occur, particularly + when the PCs are diskless, or participating in a distributed file + system of some kind. Given the importance of correct addressing in + communications networks running Ethernet, it is anticipated the + reboot mechanism described will serve to improve the correctness and + validity of the protocol/network address mappings which may be stored + in the translation caches. To this degree, simulation is expected to + show that the volume of invalid traffic will decrease, to the benefit + of hosts, Bridges and servers alike. Likewise, ratification of the + routing policy is anticipated and since redundant/obsolete packets + will be thwarted, the efficient utilization of available channel + bandwidth across the catenet is also expected to improve. Thus, + effectively increasing Catenet throughput for 'valid' packets, and + therefore enhancing the level of service provided to the end users. + + It is obvious that the proposed scheme implies the alteration of the + packet processing code in Bridges/Gateways. The point to remember is + the increased favour with which larger, more complex Multi-LAN + systems of Ethernets are being received. The recent adaption of + extra telephone cables to serve as the transmission media for the + Ethernet can only result in installation costs being reduced, therein + making the Ethernet more attractive within large corporate buildings, + etc. It is sensible to suggest that the probability of host address + re-assignment shall increase in proportion to the number of physical + systems attached, component failure rate (for whatever reason), + relocation of resources, and the size and turnover of the workforce + (i.e., people moving from one room to another). Simulation + experiments are currently being developed to analyse the resultant + traffic patterns under this scheme, and it is hoped to highlight + thresholds where adoption of the scheme becomes a necessity. + + In addition, the Author is currently extending the boundaries of this + problem to encompass the reboot, or relocation of Bridges themselves. + Involved with this are the phenomena of loop resolution, load sharing + and duplicate packet suppression. It is envisaged that a Self- + Stabilizationg Bridge Protocol will result that will be more "light- + weight" than those adhering to the Spanning Tree Algorithm. + + The Author would appreciate feedback/comments on this RFC. My + network address is: CBAD13%UCVAX.ULSTER.AC.UK@CUNYVM.CUNY.EDU. + +ACKNOWLEDGEMENTS + + The Author acknowledges with gratitute the help and comments + contributed by Mr. Piotr Bielkowitz (Supervisor) of the Computing + Science Department, and the time devoted my Mr. Raymond Robinson for + painstakingly preparing the first draft of this paper on 'Pagemaker'. + + + +Parr [Page 15] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + Thanks are due also to Dr. M. W. A. Smith of Information Systems for + his assistance. Finally, this work was supported under a grant from + the Department of Education for Northern Ireland of which the Author + is extremely grateful. + +REFERENCES + + [1] Croft, Bill, and John Gilmore, "Bootstrap Protocol", RFC-951, + Stanford University, September 1985. + + [2] Finlayson, Mann, Mogul, and Theimer, "A Reverse Address + Resolution Protocol", RFC-903, Computer Science Dept, Stanford + University, June 1984. + + [3] Lorimer, Alan, and Jim Reid, "ARP Information Communique", + Computer Science Dept, Strathclyde University, 1987. + + [4] Mogul, Jeffrey, "Internet Subnets", RFC-917, Computer Science + Dept, Stanford University, October 1984. + + [5] Plummer, David, "An Ethernet Address Resolution Protocol", RFC- + 826, MIT, November 1982. + + [6] Postel, Jon, "DARPA Internet Program Protocol Specification", + RFC-791, USC/Information Sciences Institute, September 1981. + + [7] Postel, Jon, "Multi-LAN Address Resolution", RFC-925, + USC/Information Sciences Institute, October 1984. + + [8] Postel, Jon, Carl Sunshine, and Danny Cohen, "The ARPA Internet + Protocol", Computer Networks, no. 5, pp. 261-271, 1981. + + [9] Postel, Jon, and Jeff Mogul, "Internet Standard Subnetting + Procedure", RFC-950, USC/Information Sciences Institute and + Stanford University, August 1985. + + [10] Reynolds, Joyce, and Jon Postel, "Assigned Numbers", RFC-1010, + USC/Information Sciences Institute, May 1987. + + [11] "The Ethernet: a local area network, data link layer and + physical layer specification", Version 1.0 DEC, Intel and Xerox + Corporations, USA 30 September 1980). + + [12] Hughes, H.D., and L. Li, "Simulation model of an Ethernet", + Computer Performance, Vol 3, no. 4, December 1982. + + [13] Parr, Gerald P., "Address Resolution For An Intelligent + Filtering Bridge Running On A Subnetted Ethernet System", ACM + + + +Parr [Page 16] + +RFC 1029 Fault Tolerant ARP for Multi-LANs May 1988 + + + SIGCOMM Computer Communication Review, (July/August 1987), vol. + 17, no. 3. + + [14] Smoot, Carl-Mitchell, and John S. Quarterman, "Using ARP to + Implement Transparent Subnet Gateways", RFC-1027, Texas Internet + Consulting, October 1987. + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Parr [Page 17] + -- cgit v1.2.3