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/rfc1680.txt | 395 ++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 395 insertions(+) create mode 100644 doc/rfc/rfc1680.txt (limited to 'doc/rfc/rfc1680.txt') diff --git a/doc/rfc/rfc1680.txt b/doc/rfc/rfc1680.txt new file mode 100644 index 0000000..2cf82c3 --- /dev/null +++ b/doc/rfc/rfc1680.txt @@ -0,0 +1,395 @@ + + + + + + +Network Working Group C. Brazdziunas +Request for Comments: 1680 Bellcore +Category: Informational August 1994 + + + IPng Support for ATM Services + +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 big-internet@munnari.oz.au mailing list. + +Executive Summary + + This white paper describes engineering considerations for IPng as + solicited by RFC 1550 [1]. IPng should provide support for existing + and emerging link technologies that it will be transported over. Link + technologies like Ethernet simply multiplex traffic from upper layer + protocols onto a single channel. "Sophisticated" link technologies + like ATM are emerging in the marketplace allowing several virtual + channels to be established over a single wire (or fiber) potentially + based on an applications' network performance objectives. + + Support for both "sophisticated" (ATM) and existing link technologies + needs to be considered in an IPng candidate. End-to-end applications + will communicate through a network where IPng packets travel across + subnetworks such as Ethernet and Hippi and also more "sophisticated" + link levels such as ATM. Though initial support for IPng over ATM + subnetworks will not facilitate a virtual circuit per application, + the hooks to provide such a mapping should be in place while also + maintaining support for the transport of IPng packets across + conventional subnetworks. Application support for QOS-based link + level service requires that the following types of ATM information + be mappable (or derivable) from the higher level protocol(s) such as + IPng: source and destination(s) addresses, connection quality of + service parameters, connection state, and ATM virtual circuit + identifier. Some of these mappings may be derivable from information + provided by proposed resource reservation protocols supporting an + integrated services Internet [4]. However, the ATM virtual circuit + identifier should be efficiently derivable from IPng packet + + + +Brazdziunas [Page 1] + +RFC 1680 IPng Support for ATM Services August 1994 + + + information. + + An IPng candidate should provide evidence that the mapping from an + applications' IPng packets to ATM virtual circuit(s) can be + accomplished in a heterogeneous Internet architecture keeping in + consideration the gigabit/sec rates that IPng/ATM subnetworks will + eventually be operating at. + +1. Introduction + + This paper describes parameters that are needed to map IPng (or any + protocol operating above the link level) to ATM services. ATM is a + "sophisticated" link level technology which provides the potential + capability for applications at the TCP/UDP level to map to a single + ATM virtual circuit for transport across an ATM network(s) customized + to the network performance and traffic requirements for that + application. This is a step above many of today's existing link + technologies which can only support a single level of network + performance that must be shared by all applications operating on a + single endpoint. + + The future Internet will be comprised of both conventional and + "sophisticated" link technologies. The "sophisticated" features of + link layers like ATM need to be incorporated into an internet where + data travels not only across an ATM network but also several other + existing LAN and WAN technologies. Future networks are likely to be a + combination of subnetworks providing best-effort link level service + such as Ethernet and also sophisticated subnetworks that can support + quality of service-based connections like ATM. One can envision data + originating from an Ethernet, passing through an ATM network, FDDI + network, another ATM network, and finally arriving at its destination + residing on a HIPPI network. IPng packets will travel through such a + list of interconnected network technologies as ATM is incorporated as + one of the components of the future Internet. + + To support per application customizable link level connections, four + types of ATM information should be derivable from the higher level + protocol(s) like IPng. This ATM information includes: source and + destination ATM addresses, connection quality of service parameters, + connection state, and an ATM virtual circuit identifier which maps to + a single IPng application (i.e., single TCP/UDP application). Some of + these mapping could potentially be derivable through information + provided by proposed resource reservation protocols supporting an + integrated services Internet [4]. However, the ATM virtual circuit + identifier needs to be efficiently mappable from IPng packet + information. + + + + + +Brazdziunas [Page 2] + +RFC 1680 IPng Support for ATM Services August 1994 + + + Organization of this white paper is as follows. First the + characteristics of ATM are described focusing on functions that are + not provided in today's LAN technologies. This section provides + background information necessary for the following section describing + the parameters needed to map IPng services to ATM services. + +2. Terminology + + In this white paper, the term "application" refers to a process or + set of collective processes operating at the TCP/UDP level or above + in the protocol stack. For example, each instance of "telnet" or + "ftp" session running on an end station is a distinct application. + +3. Characteristics of ATM Service + + ATM has several characteristics which differentiates it from current + link level technologies. First of all, ATM has the capability of + providing many virtual channels to transmit information over a single + wire (or fiber). This is very similar to X.25, where many logical + channels can be established over a single physical media. But unlike + X.25, ATM allows for each of these channels or circuits to have a + customizable set of performance and quality of service + characteristics. Link level technologies like Ethernet provide a + single channel with a single performance and quality of service + characteristic. In a sense, a single ATM link level media appears + like an array of of link level technologies each with customizable + characteristics. + + ATM virtual circuits can be established dynamically utilizing its + signaling protocol. ATM signaling is a source initiated negotiation + process for connection establishment. This protocol informs elements + in the network of the characteristics for the desired connection. ATM + signaling does not provide any guidelines for how network elements + decide whether it can accept a call or where a signaling request + should be forwarded if the end destination (from the link level + perspective) has not been reached. In short, ATM signaling does not + support any routing functionality of network admission control. + + ATM signaling establishes a "hard state" in the network for a call. + "Hard state" implies that the state of a connection in intermediate + switching equipment can be set and once established it will be + maintained until a message is received by one of the ends of the call + requesting a change in state for the connection [2]. As a result, an + ATM end system (this could be a workstation with an ATM adapter or a + router with an ATM interface) receives guaranteed service from the + ATM network. The ATM network is responsible for maintaining the + connection state. The price the ATM termination points pay for this + guarantee is the responsibility of changing the state of the + + + +Brazdziunas [Page 3] + +RFC 1680 IPng Support for ATM Services August 1994 + + + connection, specifically informing the ATM network to establish, + alter, or tear-down the connection. + + Each ATM end point in a network has an ATM address associated with it + to support dynamic connection establishment via signaling. These + addresses are hierarchical in structure and globally unique [3]. As a + result, these addresses are routable. This allows ATM networks to + eventually support a large number of ATM endpoints once a routing + architecture and protocols to support it become available. + + The ATM User-Network Interface (UNI) signaling protocol based on + ITU-TS Q.93B allows many different service parameters to be + specified for describing connection characteristics. [3] These + parameters can be grouped into several categories: ATM adaptation + layer (AAL) information, network QOS objectives, connection traffic + descriptor, and transit network selector. The AAL information + specifies negotiable parameters such as AAL type and maximum packet + sizes. The network QOS objectives describe the service that the ATM + user expects from the network. Q.93B allows for one of five service + classes to be selected by the ATM user. The service classes are + defined as general traffic types such as circuit emulation (class A), + variable bit rate audio and video (class B), connection-oriented data + transfer (class C), connectionless data transfer (class D), best + effort service (class X), and unspecified [3]. Each of these + categories are further specified through network provider objectives + for various ATM performance parameters. These parameters may include + cell transfer delay, cell delay variation, and cell loss ratio. The + connection traffic descriptor specifies characteristics of the data + generated by the user of the connection. This information allows the + ATM network to commit the resources necessary to support the traffic + flow with the quality of service the user expects. Characteristics + defined in the ATM Forum UNI specification include peak cell rate, + sustainable cell rate, and maximum and minimum burst sizes [3]. + Lastly, the transit network selection parameter allows an ATM user to + select a preferred network provider to service the connection [3]. + +4. Parameters Required to Map IPng to ATM + + There are several parameters required to map ATM services from a + higher level service like IPng. These ATM parameters can be + categorized in the following manner: addressing parameters, + connection QOS-related parameters, connection management information, + and ATM virtual circuit identifier. The first three categories + provide support for ATM signaling. The last parameter, a connection + identifier that maps IPng packets to ATM virtual circuits, provides + support for an ATM virtual circuit per application when the end-to- + end connection travels across an ATM subnetwork(s) (this does not + assume that ATM is the only type of subnetwork that this connection + + + +Brazdziunas [Page 4] + +RFC 1680 IPng Support for ATM Services August 1994 + + + travels across). Below, mapping issues for each of these parameters + will be described. + +4.1. Addressing + + ATM supports routable addresses to each ATM endpoint to facilitate + the dynamic establishment of connections. These addresses need to be + derived from a higher level address such as an IPng address and IPng + routing information. This type of mapping is not novel. It is a + mapping that is currently done for support of current IP over link + technologies such as Ethernet. An IP over ATM address resolution + protocol (ARP) has been described in the Internet Standard, + "Classical IP over ATM" [5]. In addition, support for IP routing over + large ATM networks is being worked in the IETF's "Routing over Large + Clouds" working group. + +4.2. Quality of Service + + As described in section 3, an ATM virtual circuit is established + based upon a user's traffic characteristics and network performance + objectives. These characteristics which include delay and throughput + requirements can only be defined by the application level (at the + transport level or above) as opposed to the internetworking (IPng) + level. For instance, a file transfer application transferring a 100 + MB file has very different link level performance requirements than a + network time application. The former requires a high throughput and + low error rate connection whereas the latter could perhaps be + adequately serviced utilizing a best-effort service. Current IP does + not provide much support for a quality of service specification and + provides no support for the specification of link level performance + needs by an application directly. This is due to the fact that only a + single type of link level performance is available with link + technologies like Ethernet. As a result, all applications over IP + today receive the same level of link service. + + IPng packets need not explicitly contain information parameters + describing an application's traffic characteristics and network + performance objectives (e.g., delay = low, throughput = 10 Mb/s). + This information could potentially be mapped from resource + reservation protocols that operate at the IP (and potentially IPng) + level [4]. + +4.3. Connection Management + + The establishment and release of ATM connections should ultimately be + controlled by the applications utilizing the circuits. As described + in section 3, ATM signaling establishes a "hard state" in the network + which is controlled by the ATM termination points [2]. Currently, IP + + + +Brazdziunas [Page 5] + +RFC 1680 IPng Support for ATM Services August 1994 + + + provides no explicit mechanism for link level connection management. + Future support for link level connection management could be + accomplished through resource reservation protocols and need not + necessarily be supported directly via information contained in the + IPng protocol. + +4.4. Connection Identifier + + A mapping function needs to exist between IPng packets and ATM so + that application flows map one-to-one to ATM virtual circuits. + Currently, application traffic flows are identified at the transport + level by UDP/TCP source and destination ports and IP protocol + identifiers. This level of identification should also be available + at the IPng level so that information in the IPng packets identify an + application's flow and map to an ATM virtual circuit supporting that + flow when the IPng packets travels across an ATM subnetwork(s). + + Using the current IP protocol, identifying an application's traffic + flow requires the combination of the following five parameters: + source and destination IP addresses, source and destination UDP/TCP + ports, and IP protocol identifier. This application connection + identifier for IP is complex and could potentially be costly to + implement in IP end stations and routers. The IPng connection + identifier should be large enough so that all application level + traffic from an IPng end point can be mapped into the IPng packet. + Currently, ATM provides 24 bits for virtual circuit identification + (VPI and VCI). This provides sufficient capacity for 2^24 + (16,777,216) connections [6]. The actual number of bits that are used + for the ATM virtual circuit however is established through + negotiation between the ATM endpoint and ATM network. This number is + useful as an upper bound for the number of mappings that are needed + to be supported by IPng. + + An IPng candidate should be able to identify how IPng packets from an + application can map to an ATM virtual circuit. In addition, this + mapping should be large enough to support a mapping for every IPng + application on an end system to an ATM virtual circuit. Careful + consideration should be given to complexity of this mapping for IPng + to ATM since it needs to eventually support gigabit/sec rates. + + + + + + + + + + + + +Brazdziunas [Page 6] + +RFC 1680 IPng Support for ATM Services August 1994 + + +References + + [1] Bradner, S., and A. Mankin, "IP: Next Generation (IPng) White + Paper Solicitation", RFC 1550, Harvard University, NRL, December + 1993. + + [2] Clark, D., "The Design Philosophy of the DARPA Internet + Protocols", Proc. ATM SIGCOMM '88, August 1988. + + [3] "ATM User-Network Interface Specification, Version 3.0", ATM + Forum, September 10, 1993. + + [4] Zhang, L., Estrin, D., Herzog, S., and S. Jamin, "Resource + ReSerVation Protocol (RSVP) - Version 1 Functional + Specification", Work in Progress, October 1993. + + [5] Laubach, M., "Classical IP and ARP over ATM", RFC 1577, Hewlett- + Packard Laboratories, January 1994. + + [6] "Asynchronous Transfer Mode (ATM) and ATM Adaptation Layer (AAL) + Protocols Generic Requirements", Bellcore Technical Advisory TA- + NWT-001113, Issue 1, June 1993. + +Security Considerations + + Security issues are not discussed in this memo. + +Author's Address + + Christina Brazdziunas + Bellcore + 445 South Street + Morristown, NJ 07960 + + Phone: (201) 829-4173 + EMail: crb@faline.bellcore.com + + + + + + + + + + + + + + + +Brazdziunas [Page 7] + -- cgit v1.2.3