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/rfc1710.txt | 1291 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1291 insertions(+) create mode 100644 doc/rfc/rfc1710.txt (limited to 'doc/rfc/rfc1710.txt') diff --git a/doc/rfc/rfc1710.txt b/doc/rfc/rfc1710.txt new file mode 100644 index 0000000..7bfc29c --- /dev/null +++ b/doc/rfc/rfc1710.txt @@ -0,0 +1,1291 @@ + + + + + + +Network Working Group: R. Hinden +Request for Comments: 1710 Sun Microsystems +Category: Informational October 1994 + + + Simple Internet Protocol Plus White Paper + +Status of this Memo + + This memo provides information for the Internet community. This memo + does not specify an Internet standard of any kind. Distribution of + this memo is unlimited. + +Abstract + + This document was submitted to the IETF IPng area in response to RFC + 1550. Publication of this document does not imply acceptance by the + IPng area of any ideas expressed within. Comments should be + submitted to the author and/or the sipp@sunroof.eng.sun.com mailing + list. + +1. Introduction + + This white paper presents an overview of the Simple Internet Protocol + plus (SIPP) which is one of the candidates being considered in the + Internet Engineering Task Force (IETF) for the next version of the + Internet Protocol (the current version is usually referred to as + IPv4). This white paper is not intended to be a detailed + presentation of all of the features and motivation for SIPP, but is + intended to give the reader an overview of the proposal. It is also + not intended that this be an implementation specification, but given + the simplicity of the central core of SIPP, an implementor familiar + with IPv4 could probably construct a basic working SIPP + implementation from reading this overview. + + SIPP is a new version of IP which is designed to be an evolutionary + step from IPv4. It is a natural increment to IPv4. It can be + installed as a normal software upgrade in internet devices and is + interoperable with the current IPv4. Its deployment strategy was + designed to not have any "flag" days. SIPP is designed to run well + on high performance networks (e.g., ATM) and at the same time is + still efficient for low bandwidth networks (e.g., wireless). In + addition, it provides a platform for new internet functionality that + will be required in the near future. + + This white paper describes the work of IETF SIPP working group. + Several individuals deserve specific recognition. These include + Steve Deering, Paul Francis, Dave Crocker, Bob Gilligan, Bill + + + +Hinden [Page 1] + +RFC 1710 SIPP IPng White Paper October 1994 + + + Simpson, Ran Atkinson, Bill Fink, Erik Nordmark, Christian Huitema, + Sue Thompson, and Ramesh Govindan. + +2. Key Issues for the Next Generation of IP + + There are several key issues that should be used in the evaluation of + any next generation internet protocol. Some are very + straightforward. For example the new protocol must be able to + support large global internetworks. Others are less obvious. There + must be a clear way to transition the current installed base of IP + systems. It doesn't matter how good a new protocol is if there isn't + a practical way to transition the current operational systems running + IPv4 to the new protocol. + +2.1 Growth + + Growth is the basic issue which caused there to be a need for a next + generation IP. If anything is to be learned from our experience with + IPv4 it is that the addressing and routing must be capable of + handling reasonable scenarios of future growth. It is important that + we have an understanding of the past growth and where the future + growth will come from. + + Currently IPv4 serves what could be called the computer market. The + computer market has been the driver of the growth of the Internet. + It comprises the current Internet and countless other smaller + internets which are not connected to the Internet. Its focus is to + connect computers together in the large business, government, and + university education markets. This market has been growing at an + exponential rate. One measure of this is that the number of networks + in current Internet (23,494 as of 1/28/94) is doubling approximately + every 12 months. The computers which are used at the endpoints of + internet communications range from PC's to Supercomputers. Most are + attached to Local Area Networks (LANs) and the vast majority are not + mobile. + + The next phase of growth will probably not be driven by the computer + market. While the computer market will continue to grow at + significant rates due to expansion into other areas such as schools + (elementary through high school) and small businesses, it is doubtful + it will continue to grow at an exponential rate. What is likely to + happen is that other kinds of markets will develop. These markets + will fall into several areas. They all have the characteristic that + they are extremely large. They also bring with them a new set of + requirements which were not as evident in the early stages of IPv4 + deployment. The new markets are also likely to happen in parallel + with other. It may turn out that we will look back on the last ten + years of Internet growth as the time when the Internet was small and + + + +Hinden [Page 2] + +RFC 1710 SIPP IPng White Paper October 1994 + + + only doubling every year. The challenge for an IPng is to provide a + solution which solves todays problems and is attractive in these + emerging markets. + + Nomadic personal computing devices seem certain to become ubiquitous + as their prices drop and their capabilities increase. A key + capability is that they will be networked. Unlike the majority of + todays networked computers they will support a variety of types of + network attachments. When disconnected they will use RF wireless + networks, when used in networked facilities they will use infrared + attachment, and when docked they will use physical wires. This makes + them an ideal candidate for internetworking technology as they will + need a common protocol which can work over a variety of physical + networks. These types of devices will become consumer devices and + will replace the current generation of cellular phones, pagers, and + personal digital assistants. In addition to the obvious requirement + of an internet protocol which can support large scale routing and + addressing, they will require an internet protocol which imposes a + low overhead and supports auto configuration and mobility as a basic + element. The nature of nomadic computing requires an internet + protocol to have built in authentication and confidentiality. It + also goes without saying that these devices will need to communicate + with the current generation of computers. The requirement for low + overhead comes from the wireless media. Unlike LAN's which will be + very high speed, the wireless media will be several orders of + magnitude slower due to constraints on available frequencies, + spectrum allocation, and power consumption. + + Another market is networked entertainment. The first signs of this + emerging market are the proposals being discussed for 500 channels of + television, video on demand, etc. This is clearly a consumer market. + The possibility is that every television set will become an Internet + host. As the world of digital high definition television approaches, + the differences between a computer and a television will diminish. + As in the previous market, this market will require an Internet + protocol which supports large scale routing and addressing, and auto + configuration. This market also requires a protocol suite which + imposes the minimum overhead to get the job done. Cost will be the + major factor in the selection of a technology to use. + + Another market which could use the next generation IP is device + control. This consists of the control of everyday devices such as + lighting equipment, heating and cooling equipment, motors, and other + types of equipment which are currently controlled via analog switches + and in aggregate consume considerable amounts of power. The size of + this market is enormous and requires solutions which are simple, + robust, easy to use, and very low cost. + + + + +Hinden [Page 3] + +RFC 1710 SIPP IPng White Paper October 1994 + + + The challenge for the IETF in the selection of an IPng is to pick a + protocol which meets today's requirements and also matches the + requirements of these emerging markets. These markets will happen + with or without an IETF IPng. If the IETF IPng is a good match for + these new markets it is likely to be used. If not, these markets + will develop something else. They will not wait for an IETF + solution. If this should happen it is probable that because of the + size and scale of the new markets the IETF protocol would be + supplanted. If the IETF IPng is not appropriate for use in these + markets, it is also probable that they will each develop their own + protocols, perhaps proprietary. These new protocols would not + interoperate with each other. The opportunity for the IETF is to + select an IPng which has a reasonable chance to be used in these + emerging markets. This would have the very desirable outcome of + creating an immense, interoperable, world-wide information + infrastructure created with open protocols. The alternative is a + world of disjoint networks with protocols controlled by individual + vendors. + +2.2. Transition + + At some point in the next three to seven years the Internet will + require a deployed new version of the Internet protocol. Two factors + are driving this: routing and addressing. Global internet routing + based on the on 32-bit addresses of IPv4 is becoming increasingly + strained. IPv4 address do not provide enough flexibility to + construct efficient hierarchies which can be aggregated. The + deployment of Classless Inter-Domain Routing [CIDR] is extending the + life time of IPv4 routing routing by a number of years, the effort to + manage the routing will continue to increase. Even if the IPv4 + routing can be scaled to support a full IPv4 Internet, the Internet + will eventually run out of network numbers. There is no question + that an IPng is needed, but only a question of when. + + The challenge for an IPng is for its transition to be complete before + IPv4 routing and addressing break. The transition will be much + easier if IPv4 address are still globally unique. The two transition + requirements which are the most important are flexibility of + deployment and the ability for IPv4 hosts to communicate with IPng + hosts. There will be IPng-only hosts, just as there will be IPv4- + only hosts. The capability must exist for IPng-only hosts to + communicate with IPv4-only hosts globally while IPv4 addresses are + globally unique. + + The deployment strategy for an IPng must be as flexible as possible. + The Internet is too large for any kind of controlled rollout to be + successful. The importance of flexibility in an IPng and the need + for interoperability between IPv4 and IPng was well stated in a + + + +Hinden [Page 4] + +RFC 1710 SIPP IPng White Paper October 1994 + + + message to the sipp mailing list by Bill Fink, who is responsible for + a portion of NASA's operational internet. In his message he said: + + "Being a network manager and thereby representing the interests of + a significant number of users, from my perspective it's safe to + say that the transition and interoperation aspects of any IPng is + *the* key first element, without which any other significant + advantages won't be able to be integrated into the user's network + environment. I also don't think it wise to think of the + transition as just a painful phase we'll have to endure en route + to a pure IPng environment, since the transition/coexistence + period undoubtedly will last at least a decade and may very well + continue for the entire lifetime of IPng, until it's replaced with + IPngng and a new transition. I might wish it was otherwise but I + fear they are facts of life given the immense installed base. + + "Given this situation, and the reality that it won't be feasible + to coordinate all the infrastructure changes even at the national + and regional levels, it is imperative that the transition + capabilities support the ability to deploy the IPng in the + piecemeal fashion... with no requirement to need to coordinate + local changes with other changes elsewhere in the Internet... + + "I realize that support for the transition and coexistence + capabilities may be a major part of the IPng effort and may cause + some headaches for the designers and developers, but I think it is + a duty that can't be shirked and the necessary price that must be + paid to provide as seamless an environment as possible to the end + user and his basic network services such as e-mail, ftp, gopher, + X-Window clients, etc... + + "The bottom line for me is that we must have interoperability + during the extended transition period for the base IPv4 + functionality..." + + Another way to think about the requirement for compatibility with + IPv4 is to look at other product areas. In the product world, + backwards compatability is very important. Vendors who do not + provide backward compatibility for their customers usually find they + do not have many customers left. For example, chip makers put + considerable effort into making sure that new versions of their + processor always run all of the software that ran on the previous + model. It is unlikely that Intel would develop a new processor in + the X86 family that did not run DOS and the tens of thousands of + applications which run on the current versions of X86's. + + Operating system vendors go to great lengths to make sure new + versions of their operating systems are binary compatible with their + + + +Hinden [Page 5] + +RFC 1710 SIPP IPng White Paper October 1994 + + + old version. For example the labels on most PC or MAC software + usually indicate that they require OS version XX or greater. It + would be foolish for Microsoft come out with a new version of Windows + which did not run the applications which ran on the previous version. + Microsoft even provides the ability for windows applications to run + on their new OS NT. This is an important feature. They understand + that it was very important to make sure that the applications which + run on Windows also run on NT. + + The same requirement is also true for IPng. The Internet has a large + installed base. Features need to be designed into an IPng to make + the transition as easy as possible. As with processors and operating + systems, it must be backwards compatible with IPv4. Other protocols + have tried to replace TCP/IP, for example XTP and OSI. One element + in their failure to reach widespread acceptance was that neither had + any transition strategy other than running in parallel (sometimes + called dual stack). New features alone are not adequate to motivate + users to deploy new protocols. IPng must have a great transition + strategy and new features. + +3. History of the SIPP Effort + + The SIPP working group represents the evolution of three different + IETF working groups focused on developing an IPng. The first was + called IP Address Encapsulation (IPAE) and was chaired by Dave + Crocker and Robert Hinden. It proposed extensions to IPv4 which + would carry larger addresses. Much of its work was focused on + developing transition mechanisms. + + Somewhat later Steve Deering proposed a new protocol evolved from + IPv4 called the Simple Internet Protocol (SIP). A working group was + formed to work on this proposal which was chaired by Steve Deering + and Christian Huitema. SIP had 64-bit addresses, a simplified + header, and options in separate extension headers. After lengthly + interaction between the two working groups and the realization that + IPAE and SIP had a number of common elements and the transition + mechanisms developed for IPAE would apply to SIP, the groups decided + to merge and concentrate their efforts. The chairs of the new SIP + working group were Steve Deering and Robert Hinden. + + In parallel to SIP, Paul Francis (formerly Paul Tsuchiya) had founded + a working group to develop the "P" Internet Protocol (Pip). Pip was + a new internet protocol based on a new architecture. The motivation + behind Pip was that the opportunity for introducing a new internet + protocol does not come very often and given that opportunity + important new features should be introduced. Pip supported variable + length addressing in 16-bit units, separation of addresses from + identifiers, support for provider selection, mobility, and efficient + + + +Hinden [Page 6] + +RFC 1710 SIPP IPng White Paper October 1994 + + + forwarding. It included a transition scheme similar to IPAE. + + After considerable discussion among the leaders of the Pip and SIP + working groups, they came to realize that the advanced features in + Pip could be accomplished in SIP without changing the base SIP + protocol as well as keeping the IPAE transition mechanisms. In + essence it was possible to keep the best features of each protocol. + Based on this the groups decided to merge their efforts. The new + protocol was called Simple Internet Protocol Plus (SIPP). The chairs + of the merged working group are Steve Deering, Paul Francis, and + Robert Hinden. + +4. SIPP Overview + + SIPP is a new version of the Internet Protocol, designed as a + successor to IP version 4 [IPV4]. SIPP is assigned IP version number + 6. + + SIPP was designed to take an evolutionary step from IPv4. It was not + a design goal to take a radical step away from IPv4. Functions which + work in IPv4 were kept in SIPP. Functions which didn't work were + removed. The changes from IPv4 to SIPP fall primarily into the + following categories: + + o Expanded Routing and Addressing Capabilities + + SIPP increases the IP address size from 32 bits to 64 bits, to + support more levels of addressing hierarchy and a much greater + number of addressable nodes. SIPP addressing can be further + extended, in units of 64 bits, by a facility equivalent to + IPv4's Loose Source and Record Route option, in combination + with a new address type called "cluster addresses" which + identify topological regions rather than individual nodes. + The scaleability of multicast routing is improved by adding + a "scope" field to multicast addresses. + + o Header Format Simplification + + Some IPv4 header fields have been dropped or made optional, to + reduce the common-case processing cost of packet handling and to + keep the bandwidth cost of the SIPP header almost as low as that + of IPv4, despite the increased size of the addresses. The basic + SIPP header is only four bytes longer than IPv4. + + + + + + + + +Hinden [Page 7] + +RFC 1710 SIPP IPng White Paper October 1994 + + + o Improved Support for Options + + Changes in the way IP header options are encoded allows for more + efficient forwarding, less stringent limits on the length of + options, and greater flexibility for introducing new options in + the future. + + o Quality-of-Service Capabilities + + A new capability is added to enable the labeling of packets + belonging to particular traffic "flows" for which the sender + requests special handling, such as non-default quality of + service or "real-time" service. + + o Authentication and Privacy Capabilities + + SIPP includes the definition of extensions which provide support + for authentication, data integrity, and confidentiality. This + is included as a basic element of SIPP. + + The SIPP protocol consists of two parts, the basic SIPP header and + SIPP Options. + +4.1 SIPP Header Format + + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |Version| Flow Label | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Payload Length | Payload Type | Hop Limit | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + + Source Address + + | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + + Destination Address + + | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + + Version 4-bit Internet Protocol version number = 6. + + Flow Label 28-bit field. See SIPP Quality of Service + section. + + Payload Length 16-bit unsigned integer. Length of payload, + i.e., the rest of the packet following the + SIPP header, in octets. + + + +Hinden [Page 8] + +RFC 1710 SIPP IPng White Paper October 1994 + + + Payload Type 8-bit selector. Identifies the type of + header immediately following the SIPP + header. Uses the same values as the IPv4 + Protocol field [STD 2, RFC 1700]. + + Hop Limit 8-bit unsigned integer. Decremented by 1 + by each node that forwards the packet. + The packet is discarded if Hop Limit is + decremented to zero. + + Source Address 64 bits. An address of the initial sender of + the packet. See [ROUT] for details. + + Destination Address 64 bits. An address of the intended + recipient of the packet (possibly not the + ultimate recipient, if an optional Routing + Header is present). + +4.2 SIPP Options + + SIPP includes an improved option mechanism over IPv4. SIPP options + are placed in separate headers that are located between the SIPP + header and the transport-layer header in a packet. Most SIPP option + headers are not examined or processed by any router along a packet's + delivery path until it arrives at its final destination. This + facilitates a major improvement in router performance for packets + containing options. In IPv4 the presence of any options requires the + router to examine all options. The other improvement is that unlike + IPv4, SIPP options can be of arbitrary length and the total amount of + options carried in a packet is not limited to 40 bytes. This feature + plus the manner in which they are processed, permits SIPP options to + be used for functions which were not practical in IPv4. A good + example of this is the SIPP Authentication and Security Encapsulation + options. + + In order to improve the performance when handling subsequent option + headers and the transport protocol which follows, SIPP options are + always an integer multiple of 8 octets long, in order to retain this + alignment for subsequent headers. + + + + + + + + + + + + +Hinden [Page 9] + +RFC 1710 SIPP IPng White Paper October 1994 + + + The SIPP option headers which are currently defined are: + + Option Function + --------------- --------------------------------------- + Routing Extended Routing (like IPv4 loose source + route) + Fragmentation Fragmentation and Reassembly + Authentication Integrity and Authentication + Security Encapsulation Confidentiality + Hop-by-Hop Option Special options which require hop by hop + processing + +4.3 SIPP Addressing + + SIPP addresses are 64-bits long and are identifiers for individual + nodes and sets of nodes. There are three types of SIPP addresses. + These are unicast, cluster, and multicast. Unicast addresses + identify a single node. Cluster addresses identify a group of nodes, + that share a common address prefix, such that a packet sent to a + cluster address will be delivered to one member of the group. + Multicast addresses identify a group of nodes, such that a packet + sent to a multicast address is delivered to all of the nodes in the + group. + + SIPP supports addresses which are twice the number of bits as IPv4 + addresses. These addresses support an address space which is four + billion (2^^32) times the size of IPv4 addresses (2^^32). Another + way to say this is that SIPP supports four billion internets each the + size of the maximum IPv4 internet. That is enough to allow each + person on the planet to have their own internet. Even with several + layers of hierarchy (with assignment utilization similar to IPv4) + this would allow for each person on the planet to have their own + internet each holding several thousand hosts. + + In addition, SIPP supports extended addresses using the routing + option. This capability allows the address space to grow to 128- + bits, 192-bits (or even larger) while still keeping the address units + in manageable 64-bit units. This permits the addresses to grow while + keeping the routing algorithms efficient because they continue to + operate using 64- bit units. + +4.3.1 Unicast Addresses + + There are several forms of unicast address assignment in SIPP. These + are global hierarchical unicast addresses, local-use addresses, and + IPv4- only host addresses. The assignment plan for unicast addresses + is described in [ADDR]. + + + + +Hinden [Page 10] + +RFC 1710 SIPP IPng White Paper October 1994 + + +4.3.1.1 Global Unicast Addresses + + Global unicast addresses are used for global communication. They are + the most common SIPP address and are similar in function to IPv4 + addresses. Their format is: + + |1| n bits | m bits | p bits | 63-n-m-p| + +-+-------------------+---------------------+-----------+---------+ + |C| PROVIDER ID | SUBSCRIBER ID | SUBNET ID | NODE ID | + +-+-------------------+---------------------+-----------+---------+ + + The first bit is the IPv4 compatibility bit, or C-bit. It indicates + whether the node represented by the address is IPv4 or SIPP. SIPP + addresses are provider-oriented. That is, the high-order part of the + address is assigned to internet service providers, which then assign + portions of the address space to subscribers, etc. This usage is + similar to assignment of IP addresses under CIDR. The SUBSCRIBER ID + distinguishes among multiple subscribers attached to the provider + identified by the PROVIDER ID. The SUBNET ID identifies a + topologically connected group of nodes within the subscriber network + identified by the subscriber prefix. The NODE ID identifies a single + node among the group of nodes identified by the subnet prefix. + +4.3.1.2 Local-Use Address + + A local-use address is a unicast address that has only local + routability scope (within the subnet or within a subscriber network), + and may have local or global uniqueness scope. They are intended for + use inside of a site for "plug and play" local communication, for + bootstrapping up to a single global addresses, and as part of an + address sequence for global communication. Their format is: + + | 4 | + |bits| 12 bits | 48 bits | + +----+---------------+--------------------------------------------+ + |0110| SUBNET ID | NODE ID | + +----+---------------+--------------------------------------------+ + + The NODE ID is an identifier which much be unique in the domain in + which it is being used. In most cases these will use a node's IEEE- + 802 48bit address. The SUBNET ID identifies a specific subnet in a + site. The combination of the SUBNET ID and the NODE ID to form a + local use address allows a large private internet to be constructed + without any other address allocation. + + Local-use addresses have two primary benefits. First, for sites or + organizations that are not (yet) connected to the global Internet, + there is no need to request an address prefix from the global + + + +Hinden [Page 11] + +RFC 1710 SIPP IPng White Paper October 1994 + + + Internet address space. Local-use addresses can be used instead. If + the organization connects to the global Internet, it can use it's + local use addresses to communicate with a server (e.g., using the + Dynamic Host Configuration Protocol [DHCP]) to have a global address + automatically assigned. + + The second benefit of local-use addresses is that they can hold much + larger NODE IDs, which makes possible a very simple form of auto- + configuration of addresses. In particular, a node may discover a + SUBNET ID by listening to a Router Advertisement messages on its + attached link(s), and then fabricating a SIPP address for itself by + using its link-level address as the NODE ID on that subnet. + + An auto-configured local-use address may be used by a node as its own + identification for communication within the local domain, possibly + including communication with a local address server to obtain a + global SIPP address. The details of host auto-configuration are + described in [DHCP]. + +4.3.1.3 IPv4-Only Addresses + + SIPP unicast addresses are assigned to IPv4-only hosts as part of the + IPAE scheme for transition from IPv4 to SIPP. Such addresses have + the following form: + + |1| 31 bits | 32 bits | + +-+------------------------------+--------------------------------+ + |1| HIGHER-ORDER SIPP PREFIX | IPv4 ADDRESS | + +-+------------------------------+--------------------------------+ + + The highest-order bit of a SIPP address is called the IPv4 + compatibility bit or the C bit. A C bit value of 1 identifies an + address as belonging to an IPv4-only node. + + The IPv4 node's 32-bit IPv4 address is carried in the low-order 32 + bits of the SIPP address. The remaining 31 bits are used to carry + HIGHER- ORDER SIPP PREFIX, such as a service-provider ID. + +4.3.2 Cluster Addresses + + Cluster addresses are unicast addresses that are used to reach the + "nearest" one (according to unicast routing's notion of nearest) of + the set of boundary routers of a cluster of nodes identified by a + common prefix in the SIPP unicast routing hierarchy. These are used + to identify a set of nodes. The cluster address, when used as part + of an address sequence, permits a node to select which of several + providers it wants to carry its traffic. A cluster address can only + be used as a destination address. In this example there would be a + + + +Hinden [Page 12] + +RFC 1710 SIPP IPng White Paper October 1994 + + + cluster address for each provider. This capability is sometimes + called "source selected policies". Cluster addresses have the + general form: + + | n bits | 64-n bits | + +---------------------------------+-------------------------------+ + | CLUSTER PREFIX |0000000000000000000000000000000| + +---------------------------------+-------------------------------+ + +4.3.3 Multicast Addresses + + A SIPP multicast address is an identifier for a group of nodes. A + node may belong to any number of multicast groups. Multicast + addresses have the following format: + + + |1| 7 | 4 | 4 | 48 bits | + +-+-------+----+----+---------------------------------------------+ + |C|1111111|FLGS|SCOP| GROUP ID | + +-+-------+----+----+---------------------------------------------+ + + Where: + + C = IPv4 compatibility bit. + + 1111111 in the rest of the first octet identifies the address as + being a multicast address. + + +-+-+-+-+ + FLGS is a set of 4 flags: |0|0|0|T| + +-+-+-+-+ + + The high-order 3 flags are reserved, and must be initialized to 0. + + T = 0 indicates a permanently-assigned ("well-known") multicast + address, assigned by the global internet numbering authority. + + T = 1 indicates a non-permanently-assigned ("transient") multicast + address. + + SCOP is a 4-bit multicast scope value used to limit the scope of + the multicast group. The values are: + + 0 reserved 8 intra-organization scope + 1 intra-node scope 9 (unassigned) + 2 intra-link scope 10 (unassigned) + 3 (unassigned) 11 intra-community scope + 4 (unassigned) 12 (unassigned) + + + +Hinden [Page 13] + +RFC 1710 SIPP IPng White Paper October 1994 + + + 5 intra-site scope 13 (unassigned) + 6 (unassigned) 14 global scope + 7 (unassigned) 15 reserved + + GROUP ID identifies the multicast group, either permanent or + transient, within the given scope. + +4.4 SIPP Routing + + Routing in SIPP is almost identical to IPv4 routing under CIDR except + that the addresses are 64-bit SIPP addresses instead of 32-bit IPv4 + addresses. This is true even when extended addresses are being used. + With very straightforward extensions, all of IPv4's routing + algorithms (OSPF, BGP, RIP, IDRP, etc.) can used to route SIPP [OSPF] + [RIP2] [IDRP]. + + SIPP also includes simple routing extensions which support powerful + new routing functionality. These capabilities include: + + Provider Selection (based on policy, performance, cost, etc.) + Host Mobility (route to current location) + Auto-Readdressing (route to new address) + Extended Addressing (route to "sub-cloud") + + The new routing functionality is obtained by creating sequences of + SIPP addresses using the SIPP Routing option. The routing option is + used by a SIPP source to list one or more intermediate nodes (or + topological clusters) to be "visited" on the way to a packet's + destination. This function is very similar in function to IPv4's + Loose Source and Record Route option. A node would publish its + address sequence in the Domain Name System [DNS]. + + The identification of a specific transport connection is done by only + using the first (source) and last (destination) address in the + sequence. These identifying addresses (i.e., first and last + addresses of a route sequence) are required to be unique within the + scope over which they are used. This permits the middle addresses in + the address sequence to change (in the cases of mobility, provider + changes, site readdressing, etc.) without disrupting the transport + connection. + + In order to make address sequences a general function, SIPP hosts are + required to reverse routes in a packet it receives containing address + sequences in order to return the packet to its originator. This + approach is taken to make SIPP host implementations from the start + support the handling and reversal of source routes. This is the key + for allowing them to work with hosts which implement the new features + such as provider selection or extended addresses. + + + +Hinden [Page 14] + +RFC 1710 SIPP IPng White Paper October 1994 + + + Three examples show how the extended addressing can be used. In + these examples, address sequences are shown by a list of individual + addresses separated by commas. For example: + + SRC, I1, I2, I3, DST + + Where the first address is the source address, the last address is + the destination address, and the middle addresses are intermediate + addresses. + + For these examples assume that two hosts, H1 and H2 wish to + communicate. Assume that H1 and H2's sites are both connected to + providers P1 and P2. A third wireless provider, PR, is connected to + both providers P1 and P2. + + ----- P1 ------ + / | \ + / | \ + H1 PR H2 + \ | / + \ | / + ----- P2 ------ + + The simplest case (no use of address sequences) is when H1 wants to + send a packet to H2 containing the addresses: + + H1, H2 + + When H2 replied it would reverse the addresses and construct a packet + containing the addresses: + + H2, H1 + + In this example either provider could be used, and H1 and H2 would + not be able to select which provider traffic would be sent to and + received from. + + If H1 decides that it wants to enforce a policy that all + communication to/from H2 can only use provider P1, it would construct + a packet containing the address sequence: + + H1, P1, H2 + + This ensures that when H2 replies to H1, it will reverse the route + and the reply it would also travel over P1. The addresses in H2's + reply would look like: + + H2, P1, H1 + + + +Hinden [Page 15] + +RFC 1710 SIPP IPng White Paper October 1994 + + + If H1 became mobile and moved to provider PR, it could maintain (not + breaking any transport connections) communication with H2, by sending + packets that contain the address sequence: + + H1, PR, P1, H2 + + This would ensure that when H2 replied it would enforce H1's policy + of exclusive use of provider P1 and send the packet to H1 new + location on provider PR. The reversed address sequence would be: + + H2, P1, PR, H1 + + The address extension facility of SIPP can be used for provider + selection, mobility, readdressing, and extended addressing. It is a + simple but powerful capability. + +4.5 SIPP Quality-of-Service Capabilities + + The Flow Label field in the SIPP header may be used by a host to + label those packets for which it requests special handling by SIPP + routers, such as non-default quality of service or "real-time" + service. This labeling is important in order to support applications + which require some degree of consistent throughput, delay, and/or + jitter. The Flow Label is a 28-bit field, internally structured into + three subfields as follows: + + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |R| DP | Flow ID | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + R (Reserved) 1-bit subfield. Initialized to zero for + transmission; Ignored on reception. + + DP (Drop Priority) 3-bit unsigned integer. Specifies the + priority of the packet, relative to other + packets from the same source, for being + discarded by a router under conditions of + congestion. Larger values indicates a + greater willingness by the sender to allow + the packet to be discarded. + + Flow ID 24-bit subfield used to identify a + specific flow. + + A flow is a sequence of packets sent from a particular source to a + particular (unicast or multicast) destination for which the source + desires special handling by the intervening routers. There may be + multiple active flows from a source to a destination, as well as + + + +Hinden [Page 16] + +RFC 1710 SIPP IPng White Paper October 1994 + + + traffic that is not associated with any flow. A flow is identified + by the combination of a Source Address and a non-zero Flow ID. + Packets that do not belong to a flow carry a Flow ID of zero. + + A Flow ID is assigned to a flow by the flow's source node. New Flow + IDs must be chosen (pseudo-)randomly and uniformly from the range 1 + to FFFFFF hex. The purpose of the random allocation is to make any + set of bits within the Flow ID suitable for use as a hash key by the + routers, for looking up the special-handling state associated with + the flow. A Flow ID must not be re-used by a source for a new flow + while any state associated with the previous usage still exists in + any router. + + The Drop Priority subfield provides a means separate from the Flow ID + for distinguishing among packets from the same source, to allow a + source to specify which of its packets are to be discarded in + preference to others when a router cannot forward them all. This is + useful for applications like video where it is preferable to drop + packets carrying screen updates rather than the packets carrying the + video synchronization information. + +4.6 SIPP Security + + The current Internet has a number of security problems and lacks + effective privacy and authentication mechanisms below the application + layer. SIPP remedies these shortcomings by having two integrated + options that provide security services. These two options may be + used singly or together to provide differing levels of security to + different users. This is very important because different user + communities have different security needs. + + The first mechanism, called the "SIPP Authentication Header", is an + option which provides authentication and integrity (without + confidentiality) to SIPP datagrams. While the option is algorithm- + independent and will support many different authentication + techniques, the use of keyed MD5 is proposed to help ensure + interoperability within the worldwide Internet. This can be used to + eliminate a significant class of network attacks, including host + masquerading attacks. The use of the SIPP Authentication Header is + particularly important when source routing is used with SIPP because + of the known risks in IP source routing. Its placement at the + internet layer can help provide host origin authentication to those + upper layer protocols and services that currently lack meaningful + protections. This mechanism should be exportable by vendors in the + United States and other countries with similar export restrictions + because it only provides authentication and integrity, and + specifically does not provide confidentiality. The exportability of + the SIPP Authentication Header encourages its widespread + + + +Hinden [Page 17] + +RFC 1710 SIPP IPng White Paper October 1994 + + + implementation and use. + + The second security option provided with SIPP is the "SIPP + Encapsulating Security Header". This mechanism provides integrity + and confidentiality to SIPP datagrams. It is simpler than some + similar security protocols (e.g., SP3D, ISO NLSP) but remains + flexible and algorithm-independent. To achieve interoperability + within the global Internet, the use of DES CBC is proposed as the + standard algorithm for use with the SIPP Encapsulating Security + Header. + +5. SIPP Transition Mechanisms + + The two key motivations in the SIPP transition mechanisms are to + provide direct interoperability between IPv4 and SIPP hosts and to + allow the user population to adopt SIPP in an a highly diffuse + fashion. The transition must be incremental, with few or no critical + interdependencies, if it is to succeed. The SIPP transition allows + the users to upgrade their hosts to SIPP, and the network operators + to deploy SIPP in routers, with very little coordination between the + two. + + The mechanisms and policies of the SIPP transition are called "IPAE". + Having a separate term serves to highlight those features designed + specifically for transition. Once an acronym for an encapsulation + technique to facilitate transition, the term "IPAE" now is mostly + historical. + + The IPAE transition is based on five key elements: + + 1) A 64-bit SIPP addressing plan that encompasses the existing + 32-bit IPv4 addressing plan. The 64-bit plan will be used to + assign addresses for both SIPP and IPv4 nodes at the beginning + of the transition. Existing IPv4 nodes will not need to change + their addresses, and IPv4 hosts being upgraded to SIPP keep their + existing IPv4 addresses as the low-order 32 bits of their SIPP + addresses. Since the SIPP addressing plan is a superset of the + existing IPv4 plan, SIPP hosts are assigned only a single 64-bit + address, which can be used to communicate with both SIPP and IPv4 + hosts. + + 2) A mechanism for encapsulating SIPP traffic within IPv4 packets so + that the IPv4 infrastructure can be leveraged early in the + transition. Most of the "SIPP within IPv4 tunnels" can be + automatically configured. + + + + + + +Hinden [Page 18] + +RFC 1710 SIPP IPng White Paper October 1994 + + + 3) Algorithms in SIPP hosts that allow them to directly interoperate + with IPv4 hosts located on the same subnet and elsewhere in the + Internet. + + 4) A mechanism for translating between IPv4 and SIPP headers to + allow SIPP-only hosts to communicate with IPv4-only hosts and to + facilitate IPv4 hosts communicating over over a SIPP-only + backbone. + + 5) An optional mechanism for mapping IPv4 addresses to SIPP address + to allow improved scaling of IPv4 routing. At the present time + given the success of CIDR, this does not look like it will be + needed in a transition to SIPP. If Internet growth should + continue beyond what CIDR can handle, it is available as an + optional mechanism. + + IPAE ensures that SIPP hosts can interoperate with IPv4 hosts + anywhere in the Internet up until the time when IPv4 addresses run + out, and afterward allows SIPP and IPv4 hosts within a limited scope + to interoperate indefinitely. This feature protects for a very long + time the huge investment users have made in IPv4. Hosts that need + only a limited connectivity range (e.g., printers) need never be + upgraded to SIPP. This feature also allows SIPP-only hosts to + interoperate with IPv4-only hosts. + + The incremental upgrade features of IPAE allow the host and router + vendors to integrate SIPP into their product lines at their own pace, + and allows the end users and network operators to deploy SIPP on + their own schedules. + + The interoperability between SIPP and IPv4 provided by IPAE also has + the benefit of extending the lifetime of IPv4 hosts. Given the large + installed base of IPv4, changes to IPv4 in hosts are nearly + impossible. Once an IPng is chosen, most of the new feature + development will be done on IPng. New features in IPng will increase + the incentives to adopt and deploy it. + +6. Why SIPP? + + There are a number of reasons why SIPP should be selected as the + IETF's IPng. It solves the Internet scaling problem, provides a + flexible transition mechanism for the current Internet, and was + designed to meet the needs of new markets such as nomadic personal + computing devices, networked entertainment, and device control. It + does this in a evolutionary way which reduces the risk of + architectural problems. + + + + + +Hinden [Page 19] + +RFC 1710 SIPP IPng White Paper October 1994 + + + Ease of transition is a key point in the design of SIPP. It is not + something was was added in at the end. SIPP is designed to + interoperate with IPv4. Specific mechanisms (C-bit, embedded IPv4 + addresses, etc.) were built into SIPP to support transition and + compatability with IPv4. It was designed to permit a gradual and + piecemeal deployment without any dependencies. + + SIPP supports large hierarchical addresses which will allow the + Internet to continue to grow and provide new routing capabilities not + built into IPv4. It has cluster addresses which can be used for + policy route selection and has scoped multicast addresses which + provide improved scaleability over IPv4 multicast. It also has local + use addresses which provide the ability for "plug and play" + installation. + + SIPP is designed to have performance better than IPv4 and work well + in low bandwidth applications like wireless. Its headers are less + expensive to process than IPv4 and its 64-bit addresses are chosen to + be well matched to the new generation of 64bit processors. Its + compact header minimizes bandwidth overhead which makes it ideal for + wireless use. + + SIPP provides a platform for new Internet functionality. This + includes support for real-time flows, provider selection, host + mobility, end-to- end security, auto-configuration, and auto- + reconfiguration. + + In summary, SIPP is a new version of IP. It can be installed as a + normal software upgrade in internet devices. It is interoperable + with the current IPv4. Its deployment strategy was designed to not + have any "flag" days. SIPP is designed to run well on high + performance networks (e.g., ATM) and at the same time is still + efficient for low bandwidth networks (e.g., wireless). In addition, + it provides a platform for new internet functionality that will be + required in the near future. + + + + + + + + + + + + + + + + +Hinden [Page 20] + +RFC 1710 SIPP IPng White Paper October 1994 + + +7. Status of SIPP Effort + + There are many active participants in the SIPP working group. Groups + making active contributions include: + + Group Activity + --------------------- ---------------------------------------- + Beame & Whiteside Implementation (PC) + Bellcore Implementation (SunOS), DNS and ICMP specs. + Digital Equipment Corp. Implementation (Alpha/OSF, Open VMS) + INRIA Implementation (BSD, BIND), DNS & OSPF specs. + INESC Implementation (BSD/Mach/x-kernel) + Intercon Implementation (MAC) + MCI Phone Conferences + Merit IDRP for SIPP Specification + Naval Research Lab. Implementation (BSD) Security Design + Network General Implementation (Sniffer) + SGI Implementation (IRIX, NetVisulizer) + Sun Implementation (Solaris 2.x, Snoop) + TGV Implementation (Open VMS) + Xerox PARC Protocol Design + Bill Simpson Implementation (KA9Q) + + As of the time this paper was written there were a number of SIPP and + IPAE implementations. These include: + + Implementation Status + -------------- ------------------------------------ + BSD/Mach Completed (telnet, NFS, AFS, UDP) + BSD/Net/2 In Progress + Bind Code done + DOS &Windows Completed (telnet, ftp, tftp, ping) + IRIX In progress (ping) + KA9Q In progress (ping, TCP) + Mac OS Completed (telnet, ftp, finger, ping) + NetVisualizer Completed (SIP & IPAE) + Open VMS Completed (telnet, ftp), In Progress + OSF/1 In Progress (ping, ICMP) + Sniffer Completed (SIP & IPAE) + Snoop Completed (SIP & IPAE) + Solaris Completed (telnet, ftp, tftp, ping) + Sun OS In Progress + + + + + + + + + +Hinden [Page 21] + +RFC 1710 SIPP IPng White Paper October 1994 + + +8. Where to Get Additional Information + + The documentation listed in the reference sections can be found in + one of the IETF internet draft directories or in the archive site for + the SIPP working group. This is located at: + + ftp.parc.xerox.com in the /pub/sipp directory. + + In addition other material relating to SIPP (such as postscript + versions of presentations on SIPP) can also be found in the SIPP + working group archive. + + To join the SIPP working group, send electronic mail to + + sipp-request@sunroof.eng.sun.com + + An archive of mail sent to this mailing list can be found in the IETF + directories at cnri.reston.va.us. + +9. Security Considerations + + Security issues are discussed in section 4.6. + +10. Author's Address + + Robert M. Hinden + Manager, Internet Engineering + Sun Microsystems, Inc. + MS MTV5-44 + 2550 Garcia Ave. + Mt. View, CA 94303 + + Phone: (415) 336-2082 + Fax: (415) 336-6016 + EMail: hinden@eng.sun.com + +11. References + + [ADDR] Francis, P., "Simple Internet Protocol Plus (SIPP): Unicast + Hierarchical Address Assignment", Work in Progress, January + 1994. + + [AUTH] Atkinson, R., "SIPP Authentication Payload", + Work in Progress, January, 1994. + + [CIDR] Fuller, V., Li, T., Yu, J., and K. Varadhan, "Supernetting: + an Address Assignment and Aggregation Strategy", RFC 1338, + BARRNet, cisco, Merit, OARnet, June 1992. + + + +Hinden [Page 22] + +RFC 1710 SIPP IPng White Paper October 1994 + + + [DISC] Simpson, W., "SIPP Neighbor Discovery", Work in Progress, + March 1994. + + [DIS2] Simpson, W., "SIPP Neighbor Discovery -- ICMP Message + Formats", Work in Progress, March 1994. + + [DHCP] Thomson, S., "Simple Internet Protocol Plus (SIPP): Automatic + Host Address Assignment", Work in Progress, March 1994. + + [DNS] Thomson, S., and C. Huitema, "DNS Extensions to Support + Simple Internet Protocol Plus (SIPP)", Work in Progress, + March 1994. + + [ICMP] Govindan, R., and S. Deering, "ICMP and IGMP for the Simple + Internet Protocol Plus (SIPP)", Work in Progress, March 1994. + + [IDRP] Hares, S., "IDRP for SIP", Work in Progress, November 1993. + + [IPAE] Gilligan, R., et al, "IPAE: The SIPP Interoperability and + Transition Mechanism", Work in Progress, March 1994. + + [IPV4] Postel, J., "Internet Protocol- DARPA Internet Program + Protocol Specification", STD 5, RFC 791, DARPA, + September 1981. + + [OSPF] Francis, P., "OSPF for SIPP", Work in Progress, February + 1994. + + [RIP2] Malkin, G., and C. Huitema, "SIP-RIP", Work in Progress, + March 1993. + + [ROUT] Deering, S., et al, "Simple Internet Protocol Plus (SIPP): + Routing and Addressing", Work in Progress, February 1994. + + [SARC] Atkinson, R., "SIPP Security Architecture", Work in Progress, + January 1994. + + [SECR] Atkinson, R., "SIPP Encapsulating Security Payload (ESP)", + Work in Progress, January 1994. + + [SIPP] Deering, S., "Simple Internet Protocol Plus (SIPP) + Specification", Work in Progress, February 1994. + + + + + + + + + +Hinden [Page 23] + -- cgit v1.2.3