Network Working Group F. Baker, Editor
Request for Comments: 1812 Cisco Systems
Obsoletes: 1716, 1009 June 1995
Category: Standards Track
Requirements for IP Version 4 Routers
Status of this Memo
This document specifies an Internet standards track protocol for the
Internet community, and requests discussion and suggestions for
improvements. Please refer to the current edition of the "Internet
Official Protocol Standards" (STD 1) for the standardization state
and status of this protocol. Distribution of this memo is unlimited.
PREFACE
This document is an updated version of RFC 1716, the historical
Router Requirements document. That RFC preserved the significant
work that went into the working group, but failed to adequately
describe current technology for the IESG to consider it a current
standard.
The current editor had been asked to bring the document up to date,
so that it is useful as a procurement specification and a guide to
implementors. In this, he stands squarely on the shoulders of those
who have gone before him, and depends largely on expert contributors
for text. Any credit is theirs; the errors are his.
The content and form of this document are due, in large part, to the
working group's chair, and document's original editor and author:
Philip Almquist. It is also largely due to the efforts of its
previous editor, Frank Kastenholz. Without their efforts, this
document would not exist.
Table of Contents
1. INTRODUCTION ........................................ 61.1 Reading this Document .............................. 81.1.1 Organization ..................................... 81.1.2 Requirements ..................................... 91.1.3 Compliance ....................................... 101.2 Relationships to Other Standards ................... 111.3 General Considerations ............................. 121.3.1 Continuing Internet Evolution .................... 121.3.2 Robustness Principle ............................. 131.3.3 Error Logging .................................... 14
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1.3.4 Configuration .................................... 141.4 Algorithms ......................................... 162. INTERNET ARCHITECTURE ............................... 162.1 Introduction ....................................... 162.2 Elements of the Architecture ....................... 172.2.1 Protocol Layering ................................ 172.2.2 Networks ......................................... 192.2.3 Routers .......................................... 202.2.4 Autonomous Systems ............................... 212.2.5 Addressing Architecture .......................... 212.2.5.1 Classical IP Addressing Architecture ........... 212.2.5.2 Classless Inter Domain Routing (CIDR) .......... 232.2.6 IP Multicasting .................................. 242.2.7 Unnumbered Lines and Networks Prefixes ........... 252.2.8 Notable Oddities ................................. 262.2.8.1 Embedded Routers ............................... 262.2.8.2 Transparent Routers ............................ 272.3 Router Characteristics ............................. 282.4 Architectural Assumptions .......................... 313. LINK LAYER .......................................... 323.1 INTRODUCTION ....................................... 323.2 LINK/INTERNET LAYER INTERFACE ...................... 333.3 SPECIFIC ISSUES .................................... 343.3.1 Trailer Encapsulation ............................ 343.3.2 Address Resolution Protocol - ARP ................ 343.3.3 Ethernet and 802.3 Coexistence ................... 353.3.4 Maximum Transmission Unit - MTU .................. 353.3.5 Point-to-Point Protocol - PPP .................... 353.3.5.1 Introduction ................................... 363.3.5.2 Link Control Protocol (LCP) Options ............ 363.3.5.3 IP Control Protocol (IPCP) Options ............. 383.3.6 Interface Testing ................................ 384. INTERNET LAYER - PROTOCOLS .......................... 394.1 INTRODUCTION ....................................... 394.2 INTERNET PROTOCOL - IP ............................. 394.2.1 INTRODUCTION ..................................... 394.2.2 PROTOCOL WALK-THROUGH ............................ 404.2.2.1 Options: RFC 791 Section 3.2 ................... 404.2.2.2 Addresses in Options: RFC 791 Section 3.1 ...... 424.2.2.3 Unused IP Header Bits: RFC 791 Section 3.1 ..... 43
4.2.2.4 Type of Service: RFC 791 Section 3.1 ........... 444.2.2.5 Header Checksum: RFC 791 Section 3.1 ........... 444.2.2.6 Unrecognized Header Options: RFC 791,
Section 3.1 .................................... 444.2.2.7 Fragmentation: RFC 791 Section 3.2 ............. 454.2.2.8 Reassembly: RFC 791 Section 3.2 ................ 464.2.2.9 Time to Live: RFC 791 Section 3.2 .............. 464.2.2.10 Multi-subnet Broadcasts: RFC 922 .............. 47
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4.2.2.11 Addressing: RFC 791 Section 3.2 ............... 474.2.3 SPECIFIC ISSUES .................................. 504.2.3.1 IP Broadcast Addresses ......................... 504.2.3.2 IP Multicasting ................................ 504.2.3.3 Path MTU Discovery ............................. 514.2.3.4 Subnetting ..................................... 514.3 INTERNET CONTROL MESSAGE PROTOCOL - ICMP ........... 524.3.1 INTRODUCTION ..................................... 524.3.2 GENERAL ISSUES ................................... 534.3.2.1 Unknown Message Types .......................... 534.3.2.2 ICMP Message TTL ............................... 534.3.2.3 Original Message Header ........................ 534.3.2.4 ICMP Message Source Address .................... 534.3.2.5 TOS and Precedence ............................. 544.3.2.6 Source Route ................................... 544.3.2.7 When Not to Send ICMP Errors ................... 554.3.2.8 Rate Limiting .................................. 564.3.3 SPECIFIC ISSUES .................................. 564.3.3.1 Destination Unreachable ........................ 564.3.3.2 Redirect ....................................... 574.3.3.3 Source Quench .................................. 574.3.3.4 Time Exceeded .................................. 584.3.3.5 Parameter Problem .............................. 584.3.3.6 Echo Request/Reply ............................. 584.3.3.7 Information Request/Reply ...................... 594.3.3.8 Timestamp and Timestamp Reply .................. 594.3.3.9 Address Mask Request/Reply ..................... 614.3.3.10 Router Advertisement and Solicitations ........ 624.4 INTERNET GROUP MANAGEMENT PROTOCOL - IGMP .......... 625. INTERNET LAYER - FORWARDING ......................... 635.1 INTRODUCTION ....................................... 635.2 FORWARDING WALK-THROUGH ............................ 635.2.1 Forwarding Algorithm ............................. 635.2.1.1 General ........................................ 645.2.1.2 Unicast ........................................ 645.2.1.3 Multicast ...................................... 655.2.2 IP Header Validation ............................. 675.2.3 Local Delivery Decision .......................... 695.2.4 Determining the Next Hop Address ................. 715.2.4.1 IP Destination Address ......................... 725.2.4.2 Local/Remote Decision .......................... 725.2.4.3 Next Hop Address ............................... 745.2.4.4 Administrative Preference ...................... 775.2.4.5 Load Splitting ................................. 795.2.5 Unused IP Header Bits: RFC-791 Section 3.1 ....... 795.2.6 Fragmentation and Reassembly: RFC-791,
Section 3.2 ...................................... 805.2.7 Internet Control Message Protocol - ICMP ......... 80
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5.2.7.1 Destination Unreachable ........................ 805.2.7.2 Redirect ....................................... 825.2.7.3 Time Exceeded .................................. 845.2.8 INTERNET GROUP MANAGEMENT PROTOCOL - IGMP ........ 845.3 SPECIFIC ISSUES .................................... 855.3.1 Time to Live (TTL) ............................... 855.3.2 Type of Service (TOS) ............................ 865.3.3 IP Precedence .................................... 875.3.3.1 Precedence-Ordered Queue Service ............... 885.3.3.2 Lower Layer Precedence Mappings ................ 895.3.3.3 Precedence Handling For All Routers ............ 905.3.4 Forwarding of Link Layer Broadcasts .............. 925.3.5 Forwarding of Internet Layer Broadcasts .......... 925.3.5.1 Limited Broadcasts ............................. 935.3.5.2 Directed Broadcasts ............................ 935.3.5.3 All-subnets-directed Broadcasts ................ 945.3.5.4 Subnet-directed Broadcasts .................... 945.3.6 Congestion Control ............................... 945.3.7 Martian Address Filtering ........................ 965.3.8 Source Address Validation ........................ 975.3.9 Packet Filtering and Access Lists ................ 975.3.10 Multicast Routing ............................... 985.3.11 Controls on Forwarding .......................... 985.3.12 State Changes ................................... 995.3.12.1 When a Router Ceases Forwarding ............... 995.3.12.2 When a Router Starts Forwarding ............... 1005.3.12.3 When an Interface Fails or is Disabled ........ 1005.3.12.4 When an Interface is Enabled .................. 1005.3.13 IP Options ...................................... 1015.3.13.1 Unrecognized Options .......................... 1015.3.13.2 Security Option ............................... 1015.3.13.3 Stream Identifier Option ...................... 1015.3.13.4 Source Route Options .......................... 1015.3.13.5 Record Route Option ........................... 1025.3.13.6 Timestamp Option .............................. 1026. TRANSPORT LAYER ..................................... 1036.1 USER DATAGRAM PROTOCOL - UDP ....................... 1036.2 TRANSMISSION CONTROL PROTOCOL - TCP ................ 1047. APPLICATION LAYER - ROUTING PROTOCOLS ............... 1067.1 INTRODUCTION ....................................... 1067.1.1 Routing Security Considerations .................. 1067.1.2 Precedence ....................................... 1077.1.3 Message Validation ............................... 1077.2 INTERIOR GATEWAY PROTOCOLS ......................... 1077.2.1 INTRODUCTION ..................................... 1077.2.2 OPEN SHORTEST PATH FIRST - OSPF .................. 1087.2.3 INTERMEDIATE SYSTEM TO INTERMEDIATE SYSTEM -
DUAL IS-IS ....................................... 108
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7.3 EXTERIOR GATEWAY PROTOCOLS ........................ 1097.3.1 INTRODUCTION .................................... 1097.3.2 BORDER GATEWAY PROTOCOL - BGP .................... 1097.3.2.1 Introduction ................................... 1097.3.2.2 Protocol Walk-through .......................... 1107.3.3 INTER-AS ROUTING WITHOUT AN EXTERIOR PROTOCOL
.................................................. 1107.4 STATIC ROUTING ..................................... 1117.5 FILTERING OF ROUTING INFORMATION ................... 1127.5.1 Route Validation ................................. 1137.5.2 Basic Route Filtering ............................ 1137.5.3 Advanced Route Filtering ......................... 1147.6 INTER-ROUTING-PROTOCOL INFORMATION EXCHANGE ........ 1148. APPLICATION LAYER - NETWORK MANAGEMENT PROTOCOLS
..................................................... 1158.1 The Simple Network Management Protocol - SNMP ...... 1158.1.1 SNMP Protocol Elements ........................... 1158.2 Community Table .................................... 1168.3 Standard MIBS ...................................... 1188.4 Vendor Specific MIBS ............................... 1198.5 Saving Changes ..................................... 1209. APPLICATION LAYER - MISCELLANEOUS PROTOCOLS ......... 1209.1 BOOTP .............................................. 1209.1.1 Introduction ..................................... 1209.1.2 BOOTP Relay Agents ............................... 12110. OPERATIONS AND MAINTENANCE ......................... 12210.1 Introduction ...................................... 12210.2 Router Initialization ............................. 12310.2.1 Minimum Router Configuration .................... 12310.2.2 Address and Prefix Initialization ............... 12410.2.3 Network Booting using BOOTP and TFTP ............ 12510.3 Operation and Maintenance ......................... 12610.3.1 Introduction .................................... 12610.3.2 Out Of Band Access .............................. 12710.3.2 Router O&M Functions ............................ 12710.3.2.1 Maintenance - Hardware Diagnosis .............. 12710.3.2.2 Control - Dumping and Rebooting ............... 12710.3.2.3 Control - Configuring the Router .............. 12810.3.2.4 Net Booting of System Software ................ 12810.3.2.5 Detecting and responding to misconfiguration
............................................... 12910.3.2.6 Minimizing Disruption ......................... 13010.3.2.7 Control - Troubleshooting Problems ............ 13010.4 Security Considerations ........................... 13110.4.1 Auditing and Audit Trails ....................... 13110.4.2 Configuration Control ........................... 13211. REFERENCES ......................................... 133
APPENDIX A. REQUIREMENTS FOR SOURCE-ROUTING HOSTS ...... 145
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APPENDIX B. GLOSSARY ................................... 146
APPENDIX C. FUTURE DIRECTIONS .......................... 152
APPENDIX D. Multicast Routing Protocols ................ 154D.1 Introduction ....................................... 154D.2 Distance Vector Multicast Routing Protocol -
DVMRP .............................................. 154D.3 Multicast Extensions to OSPF - MOSPF ............... 154D.4 Protocol Independent Multicast - PIM ............... 155
APPENDIX E Additional Next-Hop Selection Algorithms
................................................... 155E.1. Some Historical Perspective ....................... 155E.2. Additional Pruning Rules .......................... 157E.3 Some Route Lookup Algorithms ....................... 159E.3.1 The Revised Classic Algorithm .................... 159E.3.2 The Variant Router Requirements Algorithm ........ 160E.3.3 The OSPF Algorithm ............................... 160E.3.4 The Integrated IS-IS Algorithm ................... 162
Security Considerations ................................ 163
APPENDIX F: HISTORICAL ROUTING PROTOCOLS ............... 164F.1 EXTERIOR GATEWAY PROTOCOL - EGP .................... 164F.1.1 Introduction ..................................... 164F.1.2 Protocol Walk-through ............................ 165F.2 ROUTING INFORMATION PROTOCOL - RIP ................. 167F.2.1 Introduction ..................................... 167F.2.2 Protocol Walk-Through ............................ 167F.2.3 Specific Issues .................................. 172F.3 GATEWAY TO GATEWAY PROTOCOL - GGP .................. 173
Acknowledgments ........................................ 173
Editor's Address ....................................... 175
This memo replaces for RFC 1716, "Requirements for Internet Gateways"
([INTRO:1]).
This memo defines and discusses requirements for devices that perform
the network layer forwarding function of the Internet protocol suite.
The Internet community usually refers to such devices as IP routers or
simply routers; The OSI community refers to such devices as
intermediate systems. Many older Internet documents refer to these
devices as gateways, a name which more recently has largely passed out
of favor to avoid confusion with application gateways.
An IP router can be distinguished from other sorts of packet switching
devices in that a router examines the IP protocol header as part of
the switching process. It generally removes the Link Layer header a
message was received with, modifies the IP header, and replaces the
Link Layer header for retransmission.
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The authors of this memo recognize, as should its readers, that many
routers support more than one protocol. Support for multiple protocol
suites will be required in increasingly large parts of the Internet in
the future. This memo, however, does not attempt to specify Internet
requirements for protocol suites other than TCP/IP.
This document enumerates standard protocols that a router connected to
the Internet must use, and it incorporates by reference the RFCs and
other documents describing the current specifications for these
protocols. It corrects errors in the referenced documents and adds
additional discussion and guidance for an implementor.
For each protocol, this memo also contains an explicit set of
requirements, recommendations, and options. The reader must
understand that the list of requirements in this memo is incomplete by
itself. The complete set of requirements for an Internet protocol
router is primarily defined in the standard protocol specification
documents, with the corrections, amendments, and supplements contained
in this memo.
This memo should be read in conjunction with the Requirements for
Internet Hosts RFCs ([INTRO:2] and [INTRO:3]). Internet hosts and
routers must both be capable of originating IP datagrams and receiving
IP datagrams destined for them. The major distinction between
Internet hosts and routers is that routers implement forwarding
algorithms, while Internet hosts do not require forwarding
capabilities. Any Internet host acting as a router must adhere to the
requirements contained in this memo.
The goal of open system interconnection dictates that routers must
function correctly as Internet hosts when necessary. To achieve this,
this memo provides guidelines for such instances. For simplification
and ease of document updates, this memo tries to avoid overlapping
discussions of host requirements with [INTRO:2] and [INTRO:3] and
incorporates the relevant requirements of those documents by
reference. In some cases the requirements stated in [INTRO:2] and
[INTRO:3] are superseded by this document.
A good-faith implementation of the protocols produced after careful
reading of the RFCs should differ from the requirements of this memo
in only minor ways. Producing such an implementation often requires
some interaction with the Internet technical community, and must
follow good communications software engineering practices. In many
cases, the requirements in this document are already stated or implied
in the standard protocol documents, so that their inclusion here is,
in a sense, redundant. They were included because some past
implementation has made the wrong choice, causing problems of
interoperability, performance, and/or robustness.
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This memo includes discussion and explanation of many of the
requirements and recommendations. A simple list of requirements would
be dangerous, because:
o Some required features are more important than others, and some
features are optional.
o Some features are critical in some applications of routers but
irrelevant in others.
o There may be valid reasons why particular vendor products that are
designed for restricted contexts might choose to use different
specifications.
However, the specifications of this memo must be followed to meet the
general goal of arbitrary router interoperation across the diversity
and complexity of the Internet. Although most current implementations
fail to meet these requirements in various ways, some minor and some
major, this specification is the ideal towards which we need to move.
These requirements are based on the current level of Internet
architecture. This memo will be updated as required to provide
additional clarifications or to include additional information in
those areas in which specifications are still evolving.
This memo emulates the layered organization used by [INTRO:2] and
[INTRO:3]. Thus, Chapter 2 describes the layers found in the Internet
architecture. Chapter 3 covers the Link Layer. Chapters 4 and 5 are
concerned with the Internet Layer protocols and forwarding algorithms.
Chapter 6 covers the Transport Layer. Upper layer protocols are
divided among Chapters 7, 8, and 9. Chapter 7 discusses the protocols
which routers use to exchange routing information with each other.
Chapter 8 discusses network management. Chapter 9 discusses other
upper layer protocols. The final chapter covers operations and
maintenance features. This organization was chosen for simplicity,
clarity, and consistency with the Host Requirements RFCs. Appendices
to this memo include a bibliography, a glossary, and some conjectures
about future directions of router standards.
In describing the requirements, we assume that an implementation
strictly mirrors the layering of the protocols. However, strict
layering is an imperfect model, both for the protocol suite and for
recommended implementation approaches. Protocols in different layers
interact in complex and sometimes subtle ways, and particular
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functions often involve multiple layers. There are many design
choices in an implementation, many of which involve creative breaking
of strict layering. Every implementor is urged to read [INTRO:4] and
[INTRO:5].
Each major section of this memo is organized into the following
subsections:
(1) Introduction
(2) Protocol Walk-Through - considers the protocol specification
documents section-by-section, correcting errors, stating
requirements that may be ambiguous or ill-defined, and providing
further clarification or explanation.
(3) Specific Issues - discusses protocol design and implementation
issues that were not included in the walk-through.
Under many of the individual topics in this memo, there is
parenthetical material labeled DISCUSSION or IMPLEMENTATION. This
material is intended to give a justification, clarification or
explanation to the preceding requirements text. The implementation
material contains suggested approaches that an implementor may want to
consider. The DISCUSSION and IMPLEMENTATION sections are not part of
the standard.
In this memo, the words that are used to define the significance of
each particular requirement are capitalized. These words are:
o MUST
This word means that the item is an absolute requirement of the
specification. Violation of such a requirement is a fundamental
error; there is no case where it is justified.
o MUST IMPLEMENT
This phrase means that this specification requires that the item be
implemented, but does not require that it be enabled by default.
o MUST NOT
This phrase means that the item is an absolute prohibition of the
specification.
o SHOULD
This word means that there may exist valid reasons in particular
circumstances to ignore this item, but the full implications should
be understood and the case carefully weighed before choosing a
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different course.
o SHOULD IMPLEMENT
This phrase is similar in meaning to SHOULD, but is used when we
recommend that a particular feature be provided but does not
necessarily recommend that it be enabled by default.
o SHOULD NOT
This phrase means that there may exist valid reasons in particular
circumstances when the described behavior is acceptable or even
useful. Even so, the full implications should be understood and
the case carefully weighed before implementing any behavior
described with this label.
o MAY
This word means that this item is truly optional. One vendor may
choose to include the item because a particular marketplace
requires it or because it enhances the product, for example;
another vendor may omit the same item.
Some requirements are applicable to all routers. Other requirements
are applicable only to those which implement particular features or
protocols. In the following paragraphs, relevant refers to the union
of the requirements applicable to all routers and the set of
requirements applicable to a particular router because of the set of
features and protocols it has implemented.
Note that not all Relevant requirements are stated directly in this
memo. Various parts of this memo incorporate by reference sections of
the Host Requirements specification, [INTRO:2] and [INTRO:3]. For
purposes of determining compliance with this memo, it does not matter
whether a Relevant requirement is stated directly in this memo or
merely incorporated by reference from one of those documents.
An implementation is said to be conditionally compliant if it
satisfies all the Relevant MUST, MUST IMPLEMENT, and MUST NOT
requirements. An implementation is said to be unconditionally
compliant if it is conditionally compliant and also satisfies all the
Relevant SHOULD, SHOULD IMPLEMENT, and SHOULD NOT requirements. An
implementation is not compliant if it is not conditionally compliant
(i.e., it fails to satisfy one or more of the Relevant MUST, MUST
IMPLEMENT, or MUST NOT requirements).
This specification occasionally indicates that an implementation
SHOULD implement a management variable, and that it SHOULD have a
certain default value. An unconditionally compliant implementation
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implements the default behavior, and if there are other implemented
behaviors implements the variable. A conditionally compliant
implementation clearly documents what the default setting of the
variable is or, in the absence of the implementation of a variable,
may be construed to be. An implementation that both fails to
implement the variable and chooses a different behavior is not
compliant.
For any of the SHOULD and SHOULD NOT requirements, a router may
provide a configuration option that will cause the router to act other
than as specified by the requirement. Having such a configuration
option does not void a router's claim to unconditional compliance if
the option has a default setting, and that setting causes the router
to operate in the required manner.
Likewise, routers may provide, except where explicitly prohibited by
this memo, options which cause them to violate MUST or MUST NOT
requirements. A router that provides such options is compliant
(either fully or conditionally) if and only if each such option has a
default setting that causes the router to conform to the requirements
of this memo. Please note that the authors of this memo, although
aware of market realities, strongly recommend against provision of
such options. Requirements are labeled MUST or MUST NOT because
experts in the field have judged them to be particularly important to
interoperability or proper functioning in the Internet. Vendors
should weigh carefully the customer support costs of providing options
that violate those rules.
Of course, this memo is not a complete specification of an IP router,
but rather is closer to what in the OSI world is called a profile.
For example, this memo requires that a number of protocols be
implemented. Although most of the contents of their protocol
specifications are not repeated in this memo, implementors are
nonetheless required to implement the protocols according to those
specifications.
There are several reference documents of interest in checking the
status of protocol specifications and standardization:
o INTERNET OFFICIAL PROTOCOL STANDARDS
This document describes the Internet standards process and lists
the standards status of the protocols. As of this writing, the
current version of this document is STD 1, RFC 1780, [ARCH:7].
This document is periodically re-issued. You should always
consult an RFC repository and use the latest version of this
document.
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o Assigned Numbers
This document lists the assigned values of the parameters used in
the various protocols. For example, it lists IP protocol codes,
TCP port numbers, Telnet Option Codes, ARP hardware types, and
Terminal Type names. As of this writing, the current version of
this document is STD 2, RFC 1700, [INTRO:7]. This document is
periodically re-issued. You should always consult an RFC
repository and use the latest version of this document.
o Host Requirements
This pair of documents reviews the specifications that apply to
hosts and supplies guidance and clarification for any
ambiguities. Note that these requirements also apply to routers,
except where otherwise specified in this memo. As of this
writing, the current versions of these documents are RFC 1122 and
RFC 1123 (STD 3), [INTRO:2] and [INTRO:3].
o Router Requirements (formerly Gateway Requirements)
This memo.
Note that these documents are revised and updated at different times;
in case of differences between these documents, the most recent must
prevail.
These and other Internet protocol documents may be obtained from the:
The InterNIC
DS.INTERNIC.NET
InterNIC Directory and Database Service
info@internic.net
+1-908-668-6587
URL: http://ds.internic.net/
The enormous growth of the Internet has revealed problems of
management and scaling in a large datagram based packet communication
system. These problems are being addressed, and as a result there
will be continuing evolution of the specifications described in this
memo. New routing protocols, algorithms, and architectures are
constantly being developed. New internet layer protocols, and
modifications to existing protocols, are also constantly being
devised. Routers play a crucial role in the Internet, and the number
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of routers deployed in the Internet is much smaller than the number
of hosts. Vendors should therefore expect that router standards will
continue to evolve much more quickly than host standards. These
changes will be carefully planned and controlled since there is
extensive participation in this planning by the vendors and by the
organizations responsible for operation of the networks.
Development, evolution, and revision are characteristic of computer
network protocols today, and this situation will persist for some
years. A vendor who develops computer communications software for
the Internet protocol suite (or any other protocol suite!) and then
fails to maintain and update that software for changing
specifications is going to leave a trail of unhappy customers. The
Internet is a large communication network, and the users are in
constant contact through it. Experience has shown that knowledge of
deficiencies in vendor software propagates quickly through the
Internet technical community.
At every layer of the protocols, there is a general rule (from
[TRANS:2] by Jon Postel) whose application can lead to enormous
benefits in robustness and interoperability:
Be conservative in what you do,
be liberal in what you accept from others.
Software should be written to deal with every conceivable error, no
matter how unlikely. Eventually a packet will come in with that
particular combination of errors and attributes, and unless the
software is prepared, chaos can ensue. It is best to assume that the
network is filled with malevolent entities that will send packets
designed to have the worst possible effect. This assumption will
lead to suitably protective design. The most serious problems in the
Internet have been caused by unforeseen mechanisms triggered by low
probability events; mere human malice would never have taken so
devious a course!
Adaptability to change must be designed into all levels of router
software. As a simple example, consider a protocol specification
that contains an enumeration of values for a particular header field
- e.g., a type field, a port number, or an error code; this
enumeration must be assumed to be incomplete. If the protocol
specification defines four possible error codes, the software must
not break when a fifth code is defined. An undefined code might be
logged, but it must not cause a failure.
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The second part of the principal is almost as important: software on
hosts or other routers may contain deficiencies that make it unwise
to exploit legal but obscure protocol features. It is unwise to
stray far from the obvious and simple, lest untoward effects result
elsewhere. A corollary of this is watch out for misbehaving hosts;
router software should be prepared to survive in the presence of
misbehaving hosts. An important function of routers in the Internet
is to limit the amount of disruption such hosts can inflict on the
shared communication facility.
The Internet includes a great variety of systems, each implementing
many protocols and protocol layers, and some of these contain bugs
and misguided features in their Internet protocol software. As a
result of complexity, diversity, and distribution of function, the
diagnosis of problems is often very difficult.
Problem diagnosis will be aided if routers include a carefully
designed facility for logging erroneous or strange events. It is
important to include as much diagnostic information as possible when
an error is logged. In particular, it is often useful to record the
header(s) of a packet that caused an error. However, care must be
taken to ensure that error logging does not consume prohibitive
amounts of resources or otherwise interfere with the operation of the
router.
There is a tendency for abnormal but harmless protocol events to
overflow error logging files; this can be avoided by using a circular
log, or by enabling logging only while diagnosing a known failure.
It may be useful to filter and count duplicate successive messages.
One strategy that seems to work well is to both:
o Always count abnormalities and make such counts accessible through
the management protocol (see Chapter 8); and
o Allow the logging of a great variety of events to be selectively
enabled. For example, it might useful to be able to log
everything or to log everything for host X.
This topic is further discussed in [MGT:5].
In an ideal world, routers would be easy to configure, and perhaps
even entirely self-configuring. However, practical experience in the
real world suggests that this is an impossible goal, and that many
attempts by vendors to make configuration easy actually cause
customers more grief than they prevent. As an extreme example, a
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router designed to come up and start routing packets without
requiring any configuration information at all would almost certainly
choose some incorrect parameter, possibly causing serious problems on
any networks unfortunate enough to be connected to it.
Often this memo requires that a parameter be a configurable option.
There are several reasons for this. In a few cases there currently
is some uncertainty or disagreement about the best value and it may
be necessary to update the recommended value in the future. In other
cases, the value really depends on external factors - e.g., the
distribution of its communication load, or the speeds and topology of
nearby networks - and self-tuning algorithms are unavailable and may
be insufficient. In some cases, configurability is needed because of
administrative requirements.
Finally, some configuration options are required to communicate with
obsolete or incorrect implementations of the protocols, distributed
without sources, that persist in many parts of the Internet. To make
correct systems coexist with these faulty systems, administrators
must occasionally misconfigure the correct systems. This problem
will correct itself gradually as the faulty systems are retired, but
cannot be ignored by vendors.
When we say that a parameter must be configurable, we do not intend
to require that its value be explicitly read from a configuration
file at every boot time. For many parameters, there is one value
that is appropriate for all but the most unusual situations. In such
cases, it is quite reasonable that the parameter default to that
value if not explicitly set.
This memo requires a particular value for such defaults in some
cases. The choice of default is a sensitive issue when the
configuration item controls accommodation of existing, faulty,
systems. If the Internet is to converge successfully to complete
interoperability, the default values built into implementations must
implement the official protocol, not misconfigurations to accommodate
faulty implementations. Although marketing considerations have led
some vendors to choose misconfiguration defaults, we urge vendors to
choose defaults that will conform to the standard.
Finally, we note that a vendor needs to provide adequate
documentation on all configuration parameters, their limits and
effects.
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In several places in this memo, specific algorithms that a router
ought to follow are specified. These algorithms are not, per se,
required of the router. A router need not implement each algorithm
as it is written in this document. Rather, an implementation must
present a behavior to the external world that is the same as a
strict, literal, implementation of the specified algorithm.
Algorithms are described in a manner that differs from the way a good
implementor would implement them. For expository purposes, a style
that emphasizes conciseness, clarity, and independence from
implementation details has been chosen. A good implementor will
choose algorithms and implementation methods that produce the same
results as these algorithms, but may be more efficient or less
general.
We note that the art of efficient router implementation is outside
the scope of this memo.
This chapter does not contain any requirements. However, it does
contain useful background information on the general architecture of
the Internet and of routers.
General background and discussion on the Internet architecture and
supporting protocol suite can be found in the DDN Protocol Handbook
[ARCH:1]; for background see for example [ARCH:2], [ARCH:3], and
[ARCH:4]. The Internet architecture and protocols are also covered
in an ever-growing number of textbooks, such as [ARCH:5] and
[ARCH:6].
The Internet system consists of a number of interconnected packet
networks supporting communication among host computers using the
Internet protocols. These protocols include the Internet Protocol
(IP), the Internet Control Message Protocol (ICMP), the Internet
Group Management Protocol (IGMP), and a variety transport and
application protocols that depend upon them. As was described in
Section [1.2], the Internet Engineering Steering Group periodically
releases an Official Protocols memo listing all the Internet
protocols.
All Internet protocols use IP as the basic data transport mechanism.
IP is a datagram, or connectionless, internetwork service and
includes provision for addressing, type-of-service specification,
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fragmentation and reassembly, and security. ICMP and IGMP are
considered integral parts of IP, although they are architecturally
layered upon IP. ICMP provides error reporting, flow control,
first-hop router redirection, and other maintenance and control
functions. IGMP provides the mechanisms by which hosts and routers
can join and leave IP multicast groups.
Reliable data delivery is provided in the Internet protocol suite by
Transport Layer protocols such as the Transmission Control Protocol
(TCP), which provides end-end retransmission, resequencing and
connection control. Transport Layer connectionless service is
provided by the User Datagram Protocol (UDP).
To communicate using the Internet system, a host must implement the
layered set of protocols comprising the Internet protocol suite. A
host typically must implement at least one protocol from each layer.
The protocol layers used in the Internet architecture are as follows
[ARCH:7]:
o Application Layer
The Application Layer is the top layer of the Internet protocol
suite. The Internet suite does not further subdivide the
Application Layer, although some application layer protocols do
contain some internal sub-layering. The application layer of the
Internet suite essentially combines the functions of the top two
layers - Presentation and Application - of the OSI Reference Model
[ARCH:8]. The Application Layer in the Internet protocol suite
also includes some of the function relegated to the Session Layer
in the OSI Reference Model.
We distinguish two categories of application layer protocols: user
protocols that provide service directly to users, and support
protocols that provide common system functions. The most common
Internet user protocols are:
- Telnet (remote login)
- FTP (file transfer)
- SMTP (electronic mail delivery)
There are a number of other standardized user protocols and many
private user protocols.
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Support protocols, used for host name mapping, booting, and
management include SNMP, BOOTP, TFTP, the Domain Name System (DNS)
protocol, and a variety of routing protocols.
Application Layer protocols relevant to routers are discussed in
chapters 7, 8, and 9 of this memo.
o Transport Layer
The Transport Layer provides end-to-end communication services.
This layer is roughly equivalent to the Transport Layer in the OSI
Reference Model, except that it also incorporates some of OSI's
Session Layer establishment and destruction functions.
There are two primary Transport Layer protocols at present:
- Transmission Control Protocol (TCP)
- User Datagram Protocol (UDP)
TCP is a reliable connection-oriented transport service that
provides end-to-end reliability, resequencing, and flow control.
UDP is a connectionless (datagram) transport service. Other
transport protocols have been developed by the research community,
and the set of official Internet transport protocols may be
expanded in the future.
Transport Layer protocols relevant to routers are discussed in
Chapter 6.
o Internet Layer
All Internet transport protocols use the Internet Protocol (IP) to
carry data from source host to destination host. IP is a
connectionless or datagram internetwork service, providing no
end-to-end delivery guarantees. IP datagrams may arrive at the
destination host damaged, duplicated, out of order, or not at all.
The layers above IP are responsible for reliable delivery service
when it is required. The IP protocol includes provision for
addressing, type-of-service specification, fragmentation and
reassembly, and security.
The datagram or connectionless nature of IP is a fundamental and
characteristic feature of the Internet architecture.
The Internet Control Message Protocol (ICMP) is a control protocol
that is considered to be an integral part of IP, although it is
architecturally layered upon IP - it uses IP to carry its data
end-to-end. ICMP provides error reporting, congestion reporting,
and first-hop router redirection.
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The Internet Group Management Protocol (IGMP) is an Internet layer
protocol used for establishing dynamic host groups for IP
multicasting.
The Internet layer protocols IP, ICMP, and IGMP are discussed in
chapter 4.
o Link Layer
To communicate on a directly connected network, a host must
implement the communication protocol used to interface to that
network. We call this a Link Layer protocol.
Some older Internet documents refer to this layer as the Network
Layer, but it is not the same as the Network Layer in the OSI
Reference Model.
This layer contains everything below the Internet Layer and above
the Physical Layer (which is the media connectivity, normally
electrical or optical, which encodes and transports messages).
Its responsibility is the correct delivery of messages, among
which it does not differentiate.
Protocols in this Layer are generally outside the scope of
Internet standardization; the Internet (intentionally) uses
existing standards whenever possible. Thus, Internet Link Layer
standards usually address only address resolution and rules for
transmitting IP packets over specific Link Layer protocols.
Internet Link Layer standards are discussed in chapter 3.
The constituent networks of the Internet system are required to
provide only packet (connectionless) transport. According to the IP
service specification, datagrams can be delivered out of order, be
lost or duplicated, and/or contain errors.
For reasonable performance of the protocols that use IP (e.g., TCP),
the loss rate of the network should be very low. In networks
providing connection-oriented service, the extra reliability provided
by virtual circuits enhances the end-end robustness of the system,
but is not necessary for Internet operation.
Constituent networks may generally be divided into two classes:
o Local-Area Networks (LANs)
LANs may have a variety of designs. LANs normally cover a small
geographical area (e.g., a single building or plant site) and
provide high bandwidth with low delays. LANs may be passive
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(similar to Ethernet) or they may be active (such as ATM).
o Wide-Area Networks (WANs)
Geographically dispersed hosts and LANs are interconnected by
wide-area networks, also called long-haul networks. These
networks may have a complex internal structure of lines and
packet-switches, or they may be as simple as point-to-point
lines.
In the Internet model, constituent networks are connected together by
IP datagram forwarders which are called routers or IP routers. In
this document, every use of the term router is equivalent to IP
router. Many older Internet documents refer to routers as gateways.
Historically, routers have been realized with packet-switching
software executing on a general-purpose CPU. However, as custom
hardware development becomes cheaper and as higher throughput is
required, special purpose hardware is becoming increasingly common.
This specification applies to routers regardless of how they are
implemented.
A router connects to two or more logical interfaces, represented by
IP subnets or unnumbered point to point lines (discussed in section
[2.2.7]). Thus, it has at least one physical interface. Forwarding
an IP datagram generally requires the router to choose the address
and relevant interface of the next-hop router or (for the final hop)
the destination host. This choice, called relaying or forwarding
depends upon a route database within the router. The route database
is also called a routing table or forwarding table. The term
"router" derives from the process of building this route database;
routing protocols and configuration interact in a process called
routing.
The routing database should be maintained dynamically to reflect the
current topology of the Internet system. A router normally
accomplishes this by participating in distributed routing and
reachability algorithms with other routers.
Routers provide datagram transport only, and they seek to minimize
the state information necessary to sustain this service in the
interest of routing flexibility and robustness.
Packet switching devices may also operate at the Link Layer; such
devices are usually called bridges. Network segments that are
connected by bridges share the same IP network prefix forming a
single IP subnet. These other devices are outside the scope of this
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document.
An Autonomous System (AS) is a connected segment of a network
topology that consists of a collection of subnetworks (with hosts
attached) interconnected by a set of routes. The subnetworks and the
routers are expected to be under the control of a single operations
and maintenance (O&M) organization. Within an AS routers may use one
or more interior routing protocols, and sometimes several sets of
metrics. An AS is expected to present to other ASs an appearence of
a coherent interior routing plan, and a consistent picture of the
destinations reachable through the AS. An AS is identified by an
Autonomous System number.
The concept of an AS plays an important role in the Internet routing
(see Section 7.1).
An IP datagram carries 32-bit source and destination addresses, each
of which is partitioned into two parts - a constituent network prefix
and a host number on that network. Symbolically:
IP-address ::= { <Network-prefix>, <Host-number> }
To finally deliver the datagram, the last router in its path must map
the Host-number (or rest) part of an IP address to the host's Link
Layer address.
Although well documented elsewhere [INTERNET:2], it is useful to
describe the historical use of the network prefix. The language
developed to describe it is used in this and other documents and
permeates the thinking behind many protocols.
The simplest classical network prefix is the Class A, B, C, D, or E
network prefix. These address ranges are discriminated by observing
the values of the most significant bits of the address, and break the
address into simple prefix and host number fields. This is described
in [INTERNET:18]. In short, the classification is:
0xxx - Class A - general purpose unicast addresses with standard
8 bit prefix
10xx - Class B - general purpose unicast addresses with standard
16 bit prefix
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110x - Class C - general purpose unicast addresses with standard
24 bit prefix
1110 - Class D - IP Multicast Addresses - 28 bit prefix, non-
aggregatable
1111 - Class E - reserved for experimental use
This simple notion has been extended by the concept of subnets.
These were introduced to allow arbitrary complexity of interconnected
LAN structures within an organization, while insulating the Internet
system against explosive growth in assigned network prefixes and
routing complexity. Subnets provide a multi-level hierarchical
routing structure for the Internet system. The subnet extension,
described in [INTERNET:2], is a required part of the Internet
architecture. The basic idea is to partition the <Host-number> field
into two parts: a subnet number, and a true host number on that
subnet:
IP-address ::=
{ <Network-number>, <Subnet-number>, <Host-number> }
The interconnected physical networks within an organization use the
same network prefix but different subnet numbers. The distinction
between the subnets of such a subnetted network is not normally
visible outside of that network. Thus, routing in the rest of the
Internet uses only the <Network-prefix> part of the IP destination
address. Routers outside the network treat <Network-prefix> and
<Host-number> together as an uninterpreted rest part of the 32-bit IP
address. Within the subnetted network, the routers use the extended
network prefix:
{ <Network-number>, <Subnet-number> }
The bit positions containing this extended network number have
historically been indicated by a 32-bit mask called the subnet mask.
The <Subnet-number> bits SHOULD be contiguous and fall between the
<Network-number> and the <Host-number> fields. More up to date
protocols do not refer to a subnet mask, but to a prefix length; the
"prefix" portion of an address is that which would be selected by a
subnet mask whose most significant bits are all ones and the rest are
zeroes. The length of the prefix equals the number of ones in the
subnet mask. This document assumes that all subnet masks are
expressible as prefix lengths.
The inventors of the subnet mechanism presumed that each piece of an
organization's network would have only a single subnet number. In
practice, it has often proven necessary or useful to have several
subnets share a single physical cable. For this reason, routers
should be capable of configuring multiple subnets on the same
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physical interfaces, and treat them (from a routing or forwarding
perspective) as though they were distinct physical interfaces.
The explosive growth of the Internet has forced a review of address
assignment policies. The traditional uses of general purpose (Class
A, B, and C) networks have been modified to achieve better use of
IP's 32-bit address space. Classless Inter Domain Routing (CIDR)
[INTERNET:15] is a method currently being deployed in the Internet
backbones to achieve this added efficiency. CIDR depends on
deploying and routing to arbitrarily sized networks. In this model,
hosts and routers make no assumptions about the use of addressing in
the internet. The Class D (IP Multicast) and Class E (Experimental)
address spaces are preserved, although this is primarily an
assignment policy.
By definition, CIDR comprises three elements:
o topologically significant address assignment,
o routing protocols that are capable of aggregating network layer
reachability information, and
o consistent forwarding algorithm ("longest match").
The use of networks and subnets is now historical, although the
language used to describe them remains in current use. They have
been replaced by the more tractable concept of a network prefix. A
network prefix is, by definition, a contiguous set of bits at the
more significant end of the address that defines a set of systems;
host numbers select among those systems. There is no requirement
that all the internet use network prefixes uniformly. To collapse
routing information, it is useful to divide the internet into
addressing domains. Within such a domain, detailed information is
available about constituent networks; outside it, only the common
network prefix is advertised.
The classical IP addressing architecture used addresses and subnet
masks to discriminate the host number from the network prefix. With
network prefixes, it is sufficient to indicate the number of bits in
the prefix. Both representations are in common use. Architecturally
correct subnet masks are capable of being represented using the
prefix length description. They comprise that subset of all possible
bits patterns that have
o a contiguous string of ones at the more significant end,
o a contiguous string of zeros at the less significant end, and
o no intervening bits.
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Routers SHOULD always treat a route as a network prefix, and SHOULD
reject configuration and routing information inconsistent with that
model.
IP-address ::= { <Network-prefix>, <Host-number> }
An effect of the use of CIDR is that the set of destinations
associated with address prefixes in the routing table may exhibit
subset relationship. A route describing a smaller set of
destinations (a longer prefix) is said to be more specific than a
route describing a larger set of destinations (a shorter prefix);
similarly, a route describing a larger set of destinations (a shorter
prefix) is said to be less specific than a route describing a smaller
set of destinations (a longer prefix). Routers must use the most
specific matching route (the longest matching network prefix) when
forwarding traffic.
IP multicasting is an extension of Link Layer multicast to IP
internets. Using IP multicasts, a single datagram can be addressed
to multiple hosts without sending it to all. In the extended case,
these hosts may reside in different address domains. This collection
of hosts is called a multicast group. Each multicast group is
represented as a Class D IP address. An IP datagram sent to the
group is to be delivered to each group member with the same best-
effort delivery as that provided for unicast IP traffic. The sender
of the datagram does not itself need to be a member of the
destination group.
The semantics of IP multicast group membership are defined in
[INTERNET:4]. That document describes how hosts and routers join and
leave multicast groups. It also defines a protocol, the Internet
Group Management Protocol (IGMP), that monitors IP multicast group
membership.
Forwarding of IP multicast datagrams is accomplished either through
static routing information or via a multicast routing protocol.
Devices that forward IP multicast datagrams are called multicast
routers. They may or may not also forward IP unicasts. Multicast
datagrams are forwarded on the basis of both their source and
destination addresses. Forwarding of IP multicast packets is
described in more detail in Section [5.2.1]. Appendix D discusses
multicast routing protocols.
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Traditionally, each network interface on an IP host or router has its
own IP address. This can cause inefficient use of the scarce IP
address space, since it forces allocation of an IP network prefix to
every point-to-point link.
To solve this problem, a number of people have proposed and
implemented the concept of unnumbered point to point lines. An
unnumbered point to point line does not have any network prefix
associated with it. As a consequence, the network interfaces
connected to an unnumbered point to point line do not have IP
addresses.
Because the IP architecture has traditionally assumed that all
interfaces had IP addresses, these unnumbered interfaces cause some
interesting dilemmas. For example, some IP options (e.g., Record
Route) specify that a router must insert the interface address into
the option, but an unnumbered interface has no IP address. Even more
fundamental (as we shall see in chapter 5) is that routes contain the
IP address of the next hop router. A router expects that this IP
address will be on an IP (sub)net to which the router is connected.
That assumption is of course violated if the only connection is an
unnumbered point to point line.
To get around these difficulties, two schemes have been conceived.
The first scheme says that two routers connected by an unnumbered
point to point line are not really two routers at all, but rather two
half-routers that together make up a single virtual router. The
unnumbered point to point line is essentially considered to be an
internal bus in the virtual router. The two halves of the virtual
router must coordinate their activities in such a way that they act
exactly like a single router.
This scheme fits in well with the IP architecture, but suffers from
two important drawbacks. The first is that, although it handles the
common case of a single unnumbered point to point line, it is not
readily extensible to handle the case of a mesh of routers and
unnumbered point to point lines. The second drawback is that the
interactions between the half routers are necessarily complex and are
not standardized, effectively precluding the connection of equipment
from different vendors using unnumbered point to point lines.
Because of these drawbacks, this memo has adopted an alternate
scheme, which has been invented multiple times but which is probably
originally attributable to Phil Karn. In this scheme, a router that
has unnumbered point to point lines also has a special IP address,
called a router-id in this memo. The router-id is one of the
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router's IP addresses (a router is required to have at least one IP
address). This router-id is used as if it is the IP address of all
unnumbered interfaces.
A router may be a stand-alone computer system, dedicated to its IP
router functions. Alternatively, it is possible to embed router
functions within a host operating system that supports connections to
two or more networks. The best-known example of an operating system
with embedded router code is the Berkeley BSD system. The embedded
router feature seems to make building a network easy, but it has a
number of hidden pitfalls:
(1) If a host has only a single constituent-network interface, it
should not act as a router.
For example, hosts with embedded router code that gratuitously
forward broadcast packets or datagrams on the same net often
cause packet avalanches.
(2) If a (multihomed) host acts as a router, it is subject to the
requirements for routers contained in this document.
For example, the routing protocol issues and the router control
and monitoring problems are as hard and important for embedded
routers as for stand-alone routers.
Internet router requirements and specifications may change
independently of operating system changes. An administration
that operates an embedded router in the Internet is strongly
advised to maintain and update the router code. This might
require router source code.
(3) When a host executes embedded router code, it becomes part of the
Internet infrastructure. Thus, errors in software or
configuration can hinder communication between other hosts. As
a consequence, the host administrator must lose some autonomy.
In many circumstances, a host administrator will need to disable
router code embedded in the operating system. For this reason,
it should be straightforward to disable embedded router
functionality.
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(4) When a host running embedded router code is concurrently used for
other services, the Operation and Maintenance requirements for
the two modes of use may conflict.
For example, router O&M will in many cases be performed remotely
by an operations center; this may require privileged system
access that the host administrator would not normally want to
distribute.
There are two basic models for interconnecting local-area networks
and wide-area (or long-haul) networks in the Internet. In the first,
the local-area network is assigned a network prefix and all routers
in the Internet must know how to route to that network. In the
second, the local-area network shares (a small part of) the address
space of the wide-area network. Routers that support this second
model are called address sharing routers or transparent routers. The
focus of this memo is on routers that support the first model, but
this is not intended to exclude the use of transparent routers.
The basic idea of a transparent router is that the hosts on the
local-area network behind such a router share the address space of
the wide-area network in front of the router. In certain situations
this is a very useful approach and the limitations do not present
significant drawbacks.
The words in front and behind indicate one of the limitations of this
approach: this model of interconnection is suitable only for a
geographically (and topologically) limited stub environment. It
requires that there be some form of logical addressing in the network
level addressing of the wide-area network. IP addresses in the local
environment map to a few (usually one) physical address in the wide-
area network. This mapping occurs in a way consistent with the { IP
address <-> network address } mapping used throughout the wide-area
network.
Multihoming is possible on one wide-area network, but may present
routing problems if the interfaces are geographically or
topologically separated. Multihoming on two (or more) wide-area
networks is a problem due to the confusion of addresses.
The behavior that hosts see from other hosts in what is apparently
the same network may differ if the transparent router cannot fully
emulate the normal wide-area network service. For example, the
ARPANET used a Link Layer protocol that provided a Destination Dead
indication in response to an attempt to send to a host that was off-
line. However, if there were a transparent router between the
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ARPANET and an Ethernet, a host on the ARPANET would not receive a
Destination Dead indication for Ethernet hosts.
An Internet router performs the following functions:
(1) Conforms to specific Internet protocols specified in this
document, including the Internet Protocol (IP), Internet Control
Message Protocol (ICMP), and others as necessary.
(2) Interfaces to two or more packet networks. For each connected
network the router must implement the functions required by that
network. These functions typically include:
o Encapsulating and decapsulating the IP datagrams with the
connected network framing (e.g., an Ethernet header and
checksum),
o Sending and receiving IP datagrams up to the maximum size
supported by that network, this size is the network's Maximum
Transmission Unit or MTU,
o Translating the IP destination address into an appropriate
network-level address for the connected network (e.g., an
Ethernet hardware address), if needed, and
o Responding to network flow control and error indications, if
any.
See chapter 3 (Link Layer).
(3) Receives and forwards Internet datagrams. Important issues in
this process are buffer management, congestion control, and
fairness.
o Recognizes error conditions and generates ICMP error and
information messages as required.
o Drops datagrams whose time-to-live fields have reached zero.
o Fragments datagrams when necessary to fit into the MTU of the
next network.
See chapter 4 (Internet Layer - Protocols) and chapter 5
(Internet Layer - Forwarding) for more information.
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(4) Chooses a next-hop destination for each IP datagram, based on the
information in its routing database. See chapter 5 (Internet
Layer - Forwarding) for more information.
(5) (Usually) supports an interior gateway protocol (IGP) to carry
out distributed routing and reachability algorithms with the
other routers in the same autonomous system. In addition, some
routers will need to support an exterior gateway protocol (EGP)
to exchange topological information with other autonomous
systems. See chapter 7 (Application Layer - Routing Protocols)
for more information.
(6) Provides network management and system support facilities,
including loading, debugging, status reporting, exception
reporting and control. See chapter 8 (Application Layer -
Network Management Protocols) and chapter 10 (Operation and
Maintenance) for more information.
A router vendor will have many choices on power, complexity, and
features for a particular router product. It may be helpful to
observe that the Internet system is neither homogeneous nor fully
connected. For reasons of technology and geography it is growing
into a global interconnect system plus a fringe of LANs around the
edge. More and more these fringe LANs are becoming richly
interconnected, thus making them less out on the fringe and more
demanding on router requirements.
o The global interconnect system is composed of a number of wide-area
networks to which are attached routers of several Autonomous
Systems (AS); there are relatively few hosts connected directly to
the system.
o Most hosts are connected to LANs. Many organizations have clusters
of LANs interconnected by local routers. Each such cluster is
connected by routers at one or more points into the global
interconnect system. If it is connected at only one point, a LAN
is known as a stub network.
Routers in the global interconnect system generally require:
o Advanced Routing and Forwarding Algorithms
These routers need routing algorithms that are highly dynamic,
impose minimal processing and communication burdens, and offer
type-of-service routing. Congestion is still not a completely
resolved issue (see Section [5.3.6]). Improvements in these areas
are expected, as the research community is actively working on
these issues.
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o High Availability
These routers need to be highly reliable, providing 24 hours a
day, 7 days a week service. Equipment and software faults can
have a wide-spread (sometimes global) effect. In case of failure,
they must recover quickly. In any environment, a router must be
highly robust and able to operate, possibly in a degraded state,
under conditions of extreme congestion or failure of network
resources.
o Advanced O&M Features
Internet routers normally operate in an unattended mode. They
will typically be operated remotely from a centralized monitoring
center. They need to provide sophisticated means for monitoring
and measuring traffic and other events and for diagnosing faults.
o High Performance
Long-haul lines in the Internet today are most frequently full
duplex 56 KBPS, DS1 (1.544 Mbps), or DS3 (45 Mbps) speeds. LANs,
which are half duplex multiaccess media, are typically Ethernet
(10Mbps) and, to a lesser degree, FDDI (100Mbps). However,
network media technology is constantly advancing and higher speeds
are likely in the future.
The requirements for routers used in the LAN fringe (e.g., campus
networks) depend greatly on the demands of the local networks. These
may be high or medium-performance devices, probably competitively
procured from several different vendors and operated by an internal
organization (e.g., a campus computing center). The design of these
routers should emphasize low average latency and good burst
performance, together with delay and type-of-service sensitive
resource management. In this environment there may be less formal
O&M but it will not be less important. The need for the routing
mechanism to be highly dynamic will become more important as networks
become more complex and interconnected. Users will demand more out
of their local connections because of the speed of the global
interconnects.
As networks have grown, and as more networks have become old enough
that they are phasing out older equipment, it has become increasingly
imperative that routers interoperate with routers from other vendors.
Even though the Internet system is not fully interconnected, many
parts of the system need to have redundant connectivity. Rich
connectivity allows reliable service despite failures of
communication lines and routers, and it can also improve service by
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shortening Internet paths and by providing additional capacity.
Unfortunately, this richer topology can make it much more difficult
to choose the best path to a particular destination.
The current Internet architecture is based on a set of assumptions
about the communication system. The assumptions most relevant to
routers are as follows:
o The Internet is a network of networks.
Each host is directly connected to some particular network(s); its
connection to the Internet is only conceptual. Two hosts on the
same network communicate with each other using the same set of
protocols that they would use to communicate with hosts on distant
networks.
o Routers do not keep connection state information.
To improve the robustness of the communication system, routers are
designed to be stateless, forwarding each IP packet independently
of other packets. As a result, redundant paths can be exploited
to provide robust service in spite of failures of intervening
routers and networks.
All state information required for end-to-end flow control and
reliability is implemented in the hosts, in the transport layer or
in application programs. All connection control information is
thus co-located with the end points of the communication, so it
will be lost only if an end point fails. Routers control message
flow only indirectly, by dropping packets or increasing network
delay.
Note that future protocol developments may well end up putting
some more state into routers. This is especially likely for
multicast routing, resource reservation, and flow based
forwarding.
o Routing complexity should be in the routers.
Routing is a complex and difficult problem, and ought to be
performed by the routers, not the hosts. An important objective
is to insulate host software from changes caused by the inevitable
evolution of the Internet routing architecture.
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o The system must tolerate wide network variation.
A basic objective of the Internet design is to tolerate a wide
range of network characteristics - e.g., bandwidth, delay, packet
loss, packet reordering, and maximum packet size. Another
objective is robustness against failure of individual networks,
routers, and hosts, using whatever bandwidth is still available.
Finally, the goal is full open system interconnection: an Internet
router must be able to interoperate robustly and effectively with
any other router or Internet host, across diverse Internet paths.
Sometimes implementors have designed for less ambitious goals.
For example, the LAN environment is typically much more benign
than the Internet as a whole; LANs have low packet loss and delay
and do not reorder packets. Some vendors have fielded
implementations that are adequate for a simple LAN environment,
but work badly for general interoperation. The vendor justifies
such a product as being economical within the restricted LAN
market. However, isolated LANs seldom stay isolated for long.
They are soon connected to each other, to organization-wide
internets, and eventually to the global Internet system. In the
end, neither the customer nor the vendor is served by incomplete
or substandard routers.
The requirements in this document are designed for a full-function
router. It is intended that fully compliant routers will be
usable in almost any part of the Internet.
Although [INTRO:1] covers Link Layer standards (IP over various link
layers, ARP, etc.), this document anticipates that Link-Layer
material will be covered in a separate Link Layer Requirements
document. A Link-Layer Requirements document would be applicable to
both hosts and routers. Thus, this document will not obsolete the
parts of [INTRO:1] that deal with link-layer issues.
Routers have essentially the same Link Layer protocol requirements as
other sorts of Internet systems. These requirements are given in
chapter 3 of Requirements for Internet Gateways [INTRO:1]. A router
MUST comply with its requirements and SHOULD comply with its
recommendations. Since some of the material in that document has
become somewhat dated, some additional requirements and explanations
are included below.
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DISCUSSION
It is expected that the Internet community will produce a
Requirements for Internet Link Layer standard which will supersede
both this chapter and the chapter entitled "INTERNET LAYER
PROTOCOLS" in [INTRO:1].
This document does not attempt to specify the interface between the
Link Layer and the upper layers. However, note well that other parts
of this document, particularly chapter 5, require various sorts of
information to be passed across this layer boundary.
This section uses the following definitions:
o Source physical address
The source physical address is the Link Layer address of the host
or router from which the packet was received.
o Destination physical address
The destination physical address is the Link Layer address to
which the packet was sent.
The information that must pass from the Link Layer to the
Internetwork Layer for each received packet is:
(1) The IP packet [5.2.2],
(2) The length of the data portion (i.e., not including the Link-
Layer framing) of the Link Layer frame [5.2.2],
(3) The identity of the physical interface from which the IP packet
was received [5.2.3], and
(4) The classification of the packet's destination physical address
as a Link Layer unicast, broadcast, or multicast [4.3.2],
[5.3.4].
In addition, the Link Layer also should provide:
(5) The source physical address.
The information that must pass from the Internetwork Layer to the
Link Layer for each transmitted packet is:
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(1) The IP packet [5.2.1]
(2) The length of the IP packet [5.2.1]
(3) The destination physical interface [5.2.1]
(4) The next hop IP address [5.2.1]
In addition, the Internetwork Layer also should provide:
(5) The Link Layer priority value [5.3.3.2]
The Link Layer must also notify the Internetwork Layer if the packet
to be transmitted causes a Link Layer precedence-related error
[5.3.3.3].
Routers that can connect to ten megabit Ethernets MAY be able to
receive and forward Ethernet packets encapsulated using the trailer
encapsulation described in [LINK:1]. However, a router SHOULD NOT
originate trailer encapsulated packets. A router MUST NOT originate
trailer encapsulated packets without first verifying, using the
mechanism described in [INTRO:2], that the immediate destination of
the packet is willing and able to accept trailer-encapsulated
packets. A router SHOULD NOT agree (using these mechanisms) to
accept trailer-encapsulated packets.
Routers that implement ARP MUST be compliant and SHOULD be
unconditionally compliant with the requirements in [INTRO:2].
The link layer MUST NOT report a Destination Unreachable error to IP
solely because there is no ARP cache entry for a destination; it
SHOULD queue up to a small number of datagrams breifly while
performing the ARP request/reply sequence, and reply that the
destination is unreachable to one of the queued datagrams only when
this proves fruitless.
A router MUST not believe any ARP reply that claims that the Link
Layer address of another host or router is a broadcast or multicast
address.
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Routers that can connect to ten megabit Ethernets MUST be compliant
and SHOULD be unconditionally compliant with the Ethernet
requirements of [INTRO:2].
The MTU of each logical interface MUST be configurable within the
range of legal MTUs for the interface.
Many Link Layer protocols define a maximum frame size that may be
sent. In such cases, a router MUST NOT allow an MTU to be set which
would allow sending of frames larger than those allowed by the Link
Layer protocol. However, a router SHOULD be willing to receive a
packet as large as the maximum frame size even if that is larger than
the MTU.
DISCUSSION
Note that this is a stricter requirement than imposed on hosts by
[INTRO:2], which requires that the MTU of each physical interface
be configurable.
If a network is using an MTU smaller than the maximum frame size
for the Link Layer, a router may receive packets larger than the
MTU from misconfigured and incompletely initialized hosts. The
Robustness Principle indicates that the router should successfully
receive these packets if possible.
Contrary to [INTRO:1], the Internet does have a standard point to
point line protocol: the Point-to-Point Protocol (PPP), defined in
[LINK:2], [LINK:3], [LINK:4], and [LINK:5].
A point to point interface is any interface that is designed to send
data over a point to point line. Such interfaces include telephone,
leased, dedicated or direct lines (either 2 or 4 wire), and may use
point to point channels or virtual circuits of multiplexed interfaces
such as ISDN. They normally use a standardized modem or bit serial
interface (such as RS-232, RS-449 or V.35), using either synchronous
or asynchronous clocking. Multiplexed interfaces often have special
physical interfaces.
A general purpose serial interface uses the same physical media as a
point to point line, but supports the use of link layer networks as
well as point to point connectivity. Link layer networks (such as
X.25 or Frame Relay) use an alternative IP link layer specification.
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Routers that implement point to point or general purpose serial
interfaces MUST IMPLEMENT PPP.
PPP MUST be supported on all general purpose serial interfaces on a
router. The router MAY allow the line to be configured to use point
to point line protocols other than PPP. Point to point interfaces
SHOULD either default to using PPP when enabled or require
configuration of the link layer protocol before being enabled.
General purpose serial interfaces SHOULD require configuration of the
link layer protocol before being enabled.
This section provides guidelines to router implementors so that they
can ensure interoperability with other routers using PPP over either
synchronous or asynchronous links.
It is critical that an implementor understand the semantics of the
option negotiation mechanism. Options are a means for a local device
to indicate to a remote peer what the local device will accept from
the remote peer, not what it wishes to send. It is up to the remote
peer to decide what is most convenient to send within the confines of
the set of options that the local device has stated that it can
accept. Therefore it is perfectly acceptable and normal for a remote
peer to ACK all the options indicated in an LCP Configuration Request
(CR) even if the remote peer does not support any of those options.
Again, the options are simply a mechanism for either device to
indicate to its peer what it will accept, not necessarily what it
will send.
The PPP Link Control Protocol (LCP) offers a number of options that
may be negotiated. These options include (among others) address and
control field compression, protocol field compression, asynchronous
character map, Maximum Receive Unit (MRU), Link Quality Monitoring
(LQM), magic number (for loopback detection), Password Authentication
Protocol (PAP), Challenge Handshake Authentication Protocol (CHAP),
and the 32-bit Frame Check Sequence (FCS).
A router MAY use address/control field compression on either
synchronous or asynchronous links. A router MAY use protocol field
compression on either synchronous or asynchronous links. A router
that indicates that it can accept these compressions MUST be able to
accept uncompressed PPP header information also.
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DISCUSSION
These options control the appearance of the PPP header. Normally
the PPP header consists of the address, the control field, and the
protocol field. The address, on a point to point line, is 0xFF,
indicating "broadcast". The control field is 0x03, indicating
"Unnumbered Information." The Protocol Identifier is a two byte
value indicating the contents of the data area of the frame. If a
system negotiates address and control field compression it
indicates to its peer that it will accept PPP frames that have or
do not have these fields at the front of the header. It does not
indicate that it will be sending frames with these fields removed.
Protocol field compression, when negotiated, indicates that the
system is willing to receive protocol fields compressed to one
byte when this is legal. There is no requirement that the sender
do so.
Use of address/control field compression is inconsistent with the
use of numbered mode (reliable) PPP.
IMPLEMENTATION
Some hardware does not deal well with variable length header
information. In those cases it makes most sense for the remote
peer to send the full PPP header. Implementations may ensure this
by not sending the address/control field and protocol field
compression options to the remote peer. Even if the remote peer
has indicated an ability to receive compressed headers there is no
requirement for the local router to send compressed headers.
A router MUST negotiate the Asynchronous Control Character Map (ACCM)
for asynchronous PPP links, but SHOULD NOT negotiate the ACCM for
synchronous links. If a router receives an attempt to negotiate the
ACCM over a synchronous link, it MUST ACKnowledge the option and then
ignore it.
DISCUSSION
There are implementations that offer both synchronous and
asynchronous modes of operation and may use the same code to
implement the option negotiation. In this situation it is
possible that one end or the other may send the ACCM option on a
synchronous link.
A router SHOULD properly negotiate the maximum receive unit (MRU).
Even if a system negotiates an MRU smaller than 1,500 bytes, it MUST
be able to receive a 1,500 byte frame.
A router SHOULD negotiate and enable the link quality monitoring
(LQM) option.
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DISCUSSION
This memo does not specify a policy for deciding whether the
link's quality is adequate. However, it is important (see Section
[3.3.6]) that a router disable failed links.
A router SHOULD implement and negotiate the magic number option for
loopback detection.
A router MAY support the authentication options (PAP - Password
Authentication Protocol, and/or CHAP - Challenge Handshake
Authentication Protocol).
A router MUST support 16-bit CRC frame check sequence (FCS) and MAY
support the 32-bit CRC.
A router MAY offer to perform IP address negotiation. A router MUST
accept a refusal (REJect) to perform IP address negotiation from the
peer.
Routers operating at link speeds of 19,200 BPS or less SHOULD
implement and offer to perform Van Jacobson header compression.
Routers that implement VJ compression SHOULD implement an
administrative control enabling or disabling it.
A router MUST have a mechanism to allow routing software to determine
whether a physical interface is available to send packets or not; on
multiplexed interfaces where permanent virtual circuits are opened
for limited sets of neighbors, the router must also be able to
determine whether the virtual circuits are viable. A router SHOULD
have a mechanism to allow routing software to judge the quality of a
physical interface. A router MUST have a mechanism for informing the
routing software when a physical interface becomes available or
unavailable to send packets because of administrative action. A
router MUST have a mechanism for informing the routing software when
it detects a Link level interface has become available or
unavailable, for any reason.
DISCUSSION
It is crucial that routers have workable mechanisms for
determining that their network connections are functioning
properly. Failure to detect link loss, or failure to take the
proper actions when a problem is detected, can lead to black
holes.
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The mechanisms available for detecting problems with network
connections vary considerably, depending on the Link Layer
protocols in use and the interface hardware. The intent is to
maximize the capability to detect failures within the Link-Layer
constraints.
This chapter and chapter 5 discuss the protocols used at the Internet
Layer: IP, ICMP, and IGMP. Since forwarding is obviously a crucial
topic in a document discussing routers, chapter 5 limits itself to
the aspects of the protocols that directly relate to forwarding. The
current chapter contains the remainder of the discussion of the
Internet Layer protocols.
Routers MUST implement the IP protocol, as defined by [INTERNET:1].
They MUST also implement its mandatory extensions: subnets (defined
in [INTERNET:2]), IP broadcast (defined in [INTERNET:3]), and
Classless Inter-Domain Routing (CIDR, defined in [INTERNET:15]).
Router implementors need not consider compliance with the section of
[INTRO:2] entitled "Internet Protocol -- IP," as that section is
entirely duplicated or superseded in this document. A router MUST be
compliant, and SHOULD be unconditionally compliant, with the
requirements of the section entitled "SPECIFIC ISSUES" relating to IP
in [INTRO:2].
In the following, the action specified in certain cases is to
silently discard a received datagram. This means that the datagram
will be discarded without further processing and that the router will
not send any ICMP error message (see Section [4.3]) as a result.
However, for diagnosis of problems a router SHOULD provide the
capability of logging the error (see Section [1.3.3]), including the
contents of the silently discarded datagram, and SHOULD count
datagrams discarded.
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In datagrams received by the router itself, the IP layer MUST
interpret IP options that it understands and preserve the rest
unchanged for use by higher layer protocols.
Higher layer protocols may require the ability to set IP options in
datagrams they send or examine IP options in datagrams they receive.
Later sections of this document discuss specific IP option support
required by higher layer protocols.
DISCUSSION
Neither this memo nor [INTRO:2] define the order in which a
receiver must process multiple options in the same IP header.
Hosts and routers originating datagrams containing multiple
options must be aware that this introduces an ambiguity in the
meaning of certain options when combined with a source-route
option.
Here are the requirements for specific IP options:
(a) Security Option
Some environments require the Security option in every packet
originated or received. Routers SHOULD IMPLEMENT the revised
security option described in [INTERNET:5].
DISCUSSION
Note that the security options described in [INTERNET:1] and RFC
1038 ([INTERNET:16]) are obsolete.
(b) Stream Identifier Option
This option is obsolete; routers SHOULD NOT place this option
in a datagram that the router originates. This option MUST be
ignored in datagrams received by the router.
(c) Source Route Options
A router MUST be able to act as the final destination of a
source route. If a router receives a packet containing a
completed source route, the packet has reached its final
destination. In such an option, the pointer points beyond the
last field and the destination address in the IP header
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addresses the router. The option as received (the recorded
route) MUST be passed up to the transport layer (or to ICMP
message processing).
In the general case, a correct response to a source-routed
datagram traverses the same route. A router MUST provide a
means whereby transport protocols and applications can reverse
the source route in a received datagram. This reversed source
route MUST be inserted into datagrams they originate (see
[INTRO:2] for details) when the router is unaware of policy
constraints. However, if the router is policy aware, it MAY
select another path.
Some applications in the router MAY require that the user be
able to enter a source route.
A router MUST NOT originate a datagram containing multiple
source route options. What a router should do if asked to
forward a packet containing multiple source route options is
described in Section [5.2.4.1].
When a source route option is created (which would happen when
the router is originating a source routed datagram or is
inserting a source route option as a result of a special
filter), it MUST be correctly formed even if it is being
created by reversing a recorded route that erroneously includes
the source host (see case (B) in the discussion below).
DISCUSSION
Suppose a source routed datagram is to be routed from source _S to
destination D via routers G1, G2, Gn. Source S constructs a
datagram with G1's IP address as its destination address, and a
source route option to get the datagram the rest of the way to its
destination. However, there is an ambiguity in the specification
over whether the source route option in a datagram sent out by S
should be (A) or (B):
(A): {>>G2, G3, ... Gn, D} <--- CORRECT
(B): {S, >>G2, G3, ... Gn, D} <---- WRONG
(where >> represents the pointer). If (A) is sent, the datagram
received at D will contain the option: {G1, G2, ... Gn >>}, with S
and D as the IP source and destination addresses. If (B) were
sent, the datagram received at D would again contain S and D as
the same IP source and destination addresses, but the option would
be: {S, G1, ...Gn >>}; i.e., the originating host would be the
first hop in the route.
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(d) Record Route Option
Routers MAY support the Record Route option in datagrams
originated by the router.
(e) Timestamp Option
Routers MAY support the timestamp option in datagrams
originated by the router. The following rules apply:
o When originating a datagram containing a Timestamp Option, a
router MUST record a timestamp in the option if
- Its Internet address fields are not pre-specified or
- Its first pre-specified address is the IP address of the
logical interface over which the datagram is being sent
(or the router's router-id if the datagram is being sent
over an unnumbered interface).
o If the router itself receives a datagram containing a
Timestamp Option, the router MUST insert the current time
into the Timestamp Option (if there is space in the option
to do so) before passing the option to the transport layer
or to ICMP for processing. If space is not present, the
router MUST increment the Overflow Count in the option.
o A timestamp value MUST follow the rules defined in [INTRO:2].
IMPLEMENTATION
To maximize the utility of the timestamps contained in the
timestamp option, the timestamp inserted should be, as nearly as
practical, the time at which the packet arrived at the router.
For datagrams originated by the router, the timestamp inserted
should be, as nearly as practical, the time at which the datagram
was passed to the Link Layer for transmission.
The timestamp option permits the use of a non-standard time clock,
but the use of a non-synchronized clock limits the utility of the
time stamp. Therefore, routers are well advised to implement the
Network Time Protocol for the purpose of synchronizing their
clocks.
Routers are called upon to insert their address into Record Route,
Strict Source and Record Route, Loose Source and Record Route, or
Timestamp Options. When a router inserts its address into such an
option, it MUST use the IP address of the logical interface on which
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the packet is being sent. Where this rule cannot be obeyed because
the output interface has no IP address (i.e., is an unnumbered
interface), the router MUST instead insert its router-id. The
router's router-id is one of the router's IP addresses. The Router
ID may be specified on a system basis or on a per-link basis. Which
of the router's addresses is used as the router-id MUST NOT change
(even across reboots) unless changed by the network manager.
Relevant management changes include reconfiguration of the router
such that the IP address used as the router-id ceases to be one of
the router's IP addresses. Routers with multiple unnumbered
interfaces MAY have multiple router-id's. Each unnumbered interface
MUST be associated with a particular router-id. This association
MUST NOT change (even across reboots) without reconfiguration of the
router.
DISCUSSION
This specification does not allow for routers that do not have at
least one IP address. We do not view this as a serious
limitation, since a router needs an IP address to meet the
manageability requirements of Chapter [8] even if the router is
connected only to point-to-point links.
IMPLEMENTATION
One possible method of choosing the router-id that fulfills this
requirement is to use the numerically smallest (or greatest) IP
address (treating the address as a 32-bit integer) that is
assigned to the router.
The IP header contains two reserved bits: one in the Type of Service
byte and the other in the Flags field. A router MUST NOT set either
of these bits to one in datagrams originated by the router. A router
MUST NOT drop (refuse to receive or forward) a packet merely because
one or more of these reserved bits has a non-zero value; i.e., the
router MUST NOT check the values of thes bits.
DISCUSSION
Future revisions to the IP protocol may make use of these unused
bits. These rules are intended to ensure that these revisions can
be deployed without having to simultaneously upgrade all routers
in the Internet.
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The Type-of-Service byte in the IP header is divided into three
sections: the Precedence field (high-order 3 bits), a field that is
customarily called Type of Service or TOS (next 4 bits), and a
reserved bit (the low order bit).
Rules governing the reserved bit were described in Section [4.2.2.3].
A more extensive discussion of the TOS field and its use can be found
in [ROUTE:11].
The description of the IP Precedence field is superseded by Section
[5.3.3]. RFC 795, Service Mappings, is obsolete and SHOULD NOT be
implemented.
As stated in Section [5.2.2], a router MUST verify the IP checksum of
any packet that is received, and MUST discard messages containing
invalid checksums. The router MUST NOT provide a means to disable
this checksum verification.
A router MAY use incremental IP header checksum updating when the
only change to the IP header is the time to live. This will reduce
the possibility of undetected corruption of the IP header by the
router. See [INTERNET:6] for a discussion of incrementally updating
the checksum.
IMPLEMENTATION
A more extensive description of the IP checksum, including
extensive implementation hints, can be found in [INTERNET:6] and
[INTERNET:7].
A router MUST ignore IP options which it does not recognize. A
corollary of this requirement is that a router MUST implement the End
of Option List option and the No Operation option, since neither
contains an explicit length.
DISCUSSION
All future IP options will include an explicit length.
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Fragmentation, as described in [INTERNET:1], MUST be supported by a
router.
When a router fragments an IP datagram, it SHOULD minimize the number
of fragments. When a router fragments an IP datagram, it SHOULD send
the fragments in order. A fragmentation method that may generate one
IP fragment that is significantly smaller than the other MAY cause
the first IP fragment to be the smaller one.
DISCUSSION
There are several fragmentation techniques in common use in the
Internet. One involves splitting the IP datagram into IP
fragments with the first being MTU sized, and the others being
approximately the same size, smaller than the MTU. The reason for
this is twofold. The first IP fragment in the sequence will be
the effective MTU of the current path between the hosts, and the
following IP fragments are sized to minimize the further
fragmentation of the IP datagram. Another technique is to split
the IP datagram into MTU sized IP fragments, with the last
fragment being the only one smaller, as described in [INTERNET:1].
A common trick used by some implementations of TCP/IP is to
fragment an IP datagram into IP fragments that are no larger than
576 bytes when the IP datagram is to travel through a router.
This is intended to allow the resulting IP fragments to pass the
rest of the path without further fragmentation. This would,
though, create more of a load on the destination host, since it
would have a larger number of IP fragments to reassemble into one
IP datagram. It would also not be efficient on networks where the
MTU only changes once and stays much larger than 576 bytes.
Examples include LAN networks such as an IEEE 802.5 network with a
MTU of 2048 or an Ethernet network with an MTU of 1500).
One other fragmentation technique discussed was splitting the IP
datagram into approximately equal sized IP fragments, with the
size less than or equal to the next hop network's MTU. This is
intended to minimize the number of fragments that would result
from additional fragmentation further down the path, and assure
equal delay for each fragment.
Routers SHOULD generate the least possible number of IP fragments.
Work with slow machines leads us to believe that if it is
necessary to fragment messages, sending the small IP fragment
first maximizes the chance of a host with a slow interface of
receiving all the fragments.
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Time to Live (TTL) handling for packets originated or received by the
router is governed by [INTRO:2]; this section changes none of its
stipulations. However, since the remainder of the IP Protocol
section of [INTRO:2] is rewritten, this section is as well.
Note in particular that a router MUST NOT check the TTL of a packet
except when forwarding it.
A router MUST NOT originate or forward a datagram with a Time-to-Live
(TTL) value of zero.
A router MUST NOT discard a datagram just because it was received
with TTL equal to zero or one; if it is to the router and otherwise
valid, the router MUST attempt to receive it.
On messages the router originates, the IP layer MUST provide a means
for the transport layer to set the TTL field of every datagram that
is sent. When a fixed TTL value is used, it MUST be configurable.
The number SHOULD exceed the typical internet diameter, and current
wisdom suggests that it should exceed twice the internet diameter to
allow for growth. Current suggested values are normally posted in
the Assigned Numbers RFC. The TTL field has two functions: limit the
lifetime of TCP segments (see RFC 793 [TCP:1], p. 28), and terminate
Internet routing loops. Although TTL is a time in seconds, it also
has some attributes of a hop-count, since each router is required to
reduce the TTL field by at least one.
TTL expiration is intended to cause datagrams to be discarded by
routers, but not by the destination host. Hosts that act as routers
by forwarding datagrams must therefore follow the router's rules for
TTL.
A higher-layer protocol may want to set the TTL in order to implement
an "expanding scope" search for some Internet resource. This is used
by some diagnostic tools, and is expected to be useful for locating
the "nearest" server of a given class using IP multicasting, for
example. A particular transport protocol may also want to specify
its own TTL bound on maximum datagram lifetime.
A fixed default value must be at least big enough for the Internet
"diameter," i.e., the longest possible path. A reasonable value is
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about twice the diameter, to allow for continued Internet growth. As
of this writing, messages crossing the United States frequently
traverse 15 to 20 routers; this argues for a default TTL value in
excess of 40, and 64 is a common value.
As noted in 2.2.5.1, there are now five classes of IP addresses:
Class A through Class E. Class D addresses are used for IP
multicasting [INTERNET:4], while Class E addresses are reserved for
experimental use. The distinction between Class A, B, and C
addresses is no longer important; they are used as generalized
unicast network prefixes with only historical interest in their
class.
An IP multicast address is a 28-bit logical address that stands for a
group of hosts, and may be either permanent or transient. Permanent
multicast addresses are allocated by the Internet Assigned Number
Authority [INTRO:7], while transient addresses may be allocated
dynamically to transient groups. Group membership is determined
dynamically using IGMP [INTERNET:4].
We now summarize the important special cases for general purpose
unicast IP addresses, using the following notation for an IP address:
{ <Network-prefix>, <Host-number> }
and the notation -1 for a field that contains all 1 bits and the
notation 0 for a field that contains all 0 bits.
(a) { 0, 0 }
This host on this network. It MUST NOT be used as a source
address by routers, except the router MAY use this as a source
address as part of an initialization procedure (e.g., if the
router is using BOOTP to load its configuration information).
Incoming datagrams with a source address of { 0, 0 } which are
received for local delivery (see Section [5.2.3]), MUST be
accepted if the router implements the associated protocol and
that protocol clearly defines appropriate action to be taken.
Otherwise, a router MUST silently discard any locally-delivered
datagram whose source address is { 0, 0 }.
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DISCUSSION
Some protocols define specific actions to take in response to a
received datagram whose source address is { 0, 0 }. Two examples
are BOOTP and ICMP Mask Request. The proper operation of these
protocols often depends on the ability to receive datagrams whose
source address is { 0, 0 }. For most protocols, however, it is
best to ignore datagrams having a source address of { 0, 0 } since
they were probably generated by a misconfigured host or router.
Thus, if a router knows how to deal with a given datagram having a
{ 0, 0 } source address, the router MUST accept it. Otherwise,
the router MUST discard it.
See also Section [4.2.3.1] for a non-standard use of { 0, 0 }.
(b) { 0, <Host-number> }
Specified host on this network. It MUST NOT be sent by routers
except that the router MAY use this as a source address as part
of an initialization procedure by which the it learns its own
IP address.
(c) { -1, -1 }
Limited broadcast. It MUST NOT be used as a source address.
A datagram with this destination address will be received by
every host and router on the connected physical network, but
will not be forwarded outside that network.
(d) { <Network-prefix>, -1 }
Directed Broadcast - a broadcast directed to the specified
network prefix. It MUST NOT be used as a source address. A
router MAY originate Network Directed Broadcast packets. A
router MUST receive Network Directed Broadcast packets; however
a router MAY have a configuration option to prevent reception
of these packets. Such an option MUST default to allowing
reception.
(e) { 127, <any> }
Internal host loopback address. Addresses of this form MUST
NOT appear outside a host.
The <Network-prefix> is administratively assigned so that its value
will be unique in the routing domain to which the device is
connected.
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IP addresses are not permitted to have the value 0 or -1 for the
<Host-number> or <Network-prefix> fields except in the special cases
listed above. This implies that each of these fields will be at
least two bits long.
DISCUSSION
Previous versions of this document also noted that subnet numbers
must be neither 0 nor -1, and must be at least two bits in length.
In a CIDR world, the subnet number is clearly an extension of the
network prefix and cannot be interpreted without the remainder of
the prefix. This restriction of subnet numbers is therefore
meaningless in view of CIDR and may be safely ignored.
For further discussion of broadcast addresses, see Section [4.2.3.1].
When a router originates any datagram, the IP source address MUST be
one of its own IP addresses (but not a broadcast or multicast
address). The only exception is during initialization.
For most purposes, a datagram addressed to a broadcast or multicast
destination is processed as if it had been addressed to one of the
router's IP addresses; that is to say:
o A router MUST receive and process normally any packets with a
broadcast destination address.
o A router MUST receive and process normally any packets sent to a
multicast destination address that the router has asked to
receive.
The term specific-destination address means the equivalent local IP
address of the host. The specific-destination address is defined to
be the destination address in the IP header unless the header
contains a broadcast or multicast address, in which case the
specific-destination is an IP address assigned to the physical
interface on which the datagram arrived.
A router MUST silently discard any received datagram containing an IP
source address that is invalid by the rules of this section. This
validation could be done either by the IP layer or (when appropriate)
by each protocol in the transport layer. As with any datagram a
router discards, the datagram discard SHOULD be counted.
DISCUSSION
A misaddressed datagram might be caused by a Link Layer broadcast
of a unicast datagram or by another router or host that is
confused or misconfigured.
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For historical reasons, there are a number of IP addresses (some
standard and some not) which are used to indicate that an IP packet
is an IP broadcast. A router
(1) MUST treat as IP broadcasts packets addressed to 255.255.255.255
or { <Network-prefix>, -1 }.
(2) SHOULD silently discard on receipt (i.e., do not even deliver to
applications in the router) any packet addressed to 0.0.0.0 or {
<Network-prefix>, 0 }. If these packets are not silently
discarded, they MUST be treated as IP broadcasts (see Section
[5.3.5]). There MAY be a configuration option to allow receipt
of these packets. This option SHOULD default to discarding
them.
(3) SHOULD (by default) use the limited broadcast address
(255.255.255.255) when originating an IP broadcast destined for
a connected (sub)network (except when sending an ICMP Address
Mask Reply, as discussed in Section [4.3.3.9]). A router MUST
receive limited broadcasts.
(4) SHOULD NOT originate datagrams addressed to 0.0.0.0 or {
<Network-prefix>, 0 }. There MAY be a configuration option to
allow generation of these packets (instead of using the relevant
1s format broadcast). This option SHOULD default to not
generating them.
DISCUSSION
In the second bullet, the router obviously cannot recognize
addresses of the form { <Network-prefix>, 0 } if the router has no
interface to that network prefix. In that case, the rules of the
second bullet do not apply because, from the point of view of the
router, the packet is not an IP broadcast packet.
An IP router SHOULD satisfy the Host Requirements with respect to IP
multicasting, as specified in [INTRO:2]. An IP router SHOULD support
local IP multicasting on all connected networks. When a mapping from
IP multicast addresses to link-layer addresses has been specified
(see the various IP-over-xxx specifications), it SHOULD use that
mapping, and MAY be configurable to use the link layer broadcast
instead. On point-to-point links and all other interfaces,
multicasts are encapsulated as link layer broadcasts. Support for
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local IP multicasting includes originating multicast datagrams,
joining multicast groups and receiving multicast datagrams, and
leaving multicast groups. This implies support for all of
[INTERNET:4] including IGMP (see Section [4.4]).
DISCUSSION
Although [INTERNET:4] is entitled Host Extensions for IP
Multicasting, it applies to all IP systems, both hosts and
routers. In particular, since routers may join multicast groups,
it is correct for them to perform the host part of IGMP, reporting
their group memberships to any multicast routers that may be
present on their attached networks (whether or not they themselves
are multicast routers).
Some router protocols may specifically require support for IP
multicasting (e.g., OSPF [ROUTE:1]), or may recommend it (e.g.,
ICMP Router Discovery [INTERNET:13]).
To eliminate fragmentation or minimize it, it is desirable to know
what is the path MTU along the path from the source to destination.
The path MTU is the minimum of the MTUs of each hop in the path.
[INTERNET:14] describes a technique for dynamically discovering the
maximum transmission unit (MTU) of an arbitrary internet path. For a
path that passes through a router that does not support
[INTERNET:14], this technique might not discover the correct Path
MTU, but it will always choose a Path MTU as accurate as, and in many
cases more accurate than, the Path MTU that would be chosen by older
techniques or the current practice.
When a router is originating an IP datagram, it SHOULD use the scheme
described in [INTERNET:14] to limit the datagram's size. If the
router's route to the datagram's destination was learned from a
routing protocol that provides Path MTU information, the scheme
described in [INTERNET:14] is still used, but the Path MTU
information from the routing protocol SHOULD be used as the initial
guess as to the Path MTU and also as an upper bound on the Path MTU.
Under certain circumstances, it may be desirable to support subnets
of a particular network being interconnected only through a path that
is not part of the subnetted network. This is known as discontiguous
subnetwork support.
Routers MUST support discontiguous subnetworks.
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IMPLEMENTATION
In classical IP networks, this was very difficult to achieve; in
CIDR networks, it is a natural by-product. Therefore, a router
SHOULD NOT make assumptions about subnet architecture, but SHOULD
treat each route as a generalized network prefix.
DISCUSSION The Internet has been growing at a tremendous rate of
late. This has been placing severe strains on the IP addressing
technology. A major factor in this strain is the strict IP
Address class boundaries. These make it difficult to efficiently
size network prefixes to their networks and aggregate several
network prefixes into a single route advertisement. By
eliminating the strict class boundaries of the IP address and
treating each route as a generalized network prefix, these strains
may be greatly reduced.
The technology for currently doing this is Classless Inter Domain
Routing (CIDR) [INTERNET:15].
For similar reasons, an address block associated with a given network
prefix could be subdivided into subblocks of different sizes, so that
the network prefixes associated with the subblocks would have
different length. For example, within a block whose network prefix
is 8 bits long, one subblock may have a 16 bit network prefix,
another may have an 18 bit network prefix, and a third a 14 bit
network prefix.
Routers MUST support variable length network prefixes in both their
interface configurations and their routing databases.
ICMP is an auxiliary protocol, which provides routing, diagnostic and
error functionality for IP. It is described in [INTERNET:8]. A
router MUST support ICMP.
ICMP messages are grouped in two classes that are discussed in the
following sections:
ICMP error messages:
Destination Unreachable Section 4.3.3.1
Redirect Section 4.3.3.2
Source Quench Section 4.3.3.3
Time Exceeded Section 4.3.3.4
Parameter Problem Section 4.3.3.5
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ICMP query messages:
Echo Section 4.3.3.6
Information Section 4.3.3.7
Timestamp Section 4.3.3.8
Address Mask Section 4.3.3.9
Router Discovery Section 4.3.3.10
General ICMP requirements and discussion are in the next section.
If an ICMP message of unknown type is received, it MUST be passed to
the ICMP user interface (if the router has one) or silently discarded
(if the router does not have one).
When originating an ICMP message, the router MUST initialize the TTL.
The TTL for ICMP responses must not be taken from the packet that
triggered the response.
Historically, every ICMP error message has included the Internet
header and at least the first 8 data bytes of the datagram that
triggered the error. This is no longer adequate, due to the use of
IP-in-IP tunneling and other technologies. Therefore, the ICMP
datagram SHOULD contain as much of the original datagram as possible
without the length of the ICMP datagram exceeding 576 bytes. The
returned IP header (and user data) MUST be identical to that which
was received, except that the router is not required to undo any
modifications to the IP header that are normally performed in
forwarding that were performed before the error was detected (e.g.,
decrementing the TTL, or updating options). Note that the
requirements of Section [4.3.3.5] supersede this requirement in some
cases (i.e., for a Parameter Problem message, if the problem is in a
modified field, the router must undo the modification). See Section
[4.3.3.5]).
Except where this document specifies otherwise, the IP source address
in an ICMP message originated by the router MUST be one of the IP
addresses associated with the physical interface over which the ICMP
message is transmitted. If the interface has no IP addresses
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associated with it, the router's router-id (see Section [5.2.5]) is
used instead.
ICMP error messages SHOULD have their TOS bits set to the same value
as the TOS bits in the packet that provoked the sending of the ICMP
error message, unless setting them to that value would cause the ICMP
error message to be immediately discarded because it could not be
routed to its destination. Otherwise, ICMP error messages MUST be
sent with a normal (i.e., zero) TOS. An ICMP reply message SHOULD
have its TOS bits set to the same value as the TOS bits in the ICMP
request that provoked the reply.
ICMP Source Quench error messages, if sent at all, MUST have their IP
Precedence field set to the same value as the IP Precedence field in
the packet that provoked the sending of the ICMP Source Quench
message. All other ICMP error messages (Destination Unreachable,
Redirect, Time Exceeded, and Parameter Problem) SHOULD have their
precedence value set to 6 (INTERNETWORK CONTROL) or 7 (NETWORK
CONTROL). The IP Precedence value for these error messages MAY be
settable.
An ICMP reply message MUST have its IP Precedence field set to the
same value as the IP Precedence field in the ICMP request that
provoked the reply.
If the packet which provokes the sending of an ICMP error message
contains a source route option, the ICMP error message SHOULD also
contain a source route option of the same type (strict or loose),
created by reversing the portion before the pointer of the route
recorded in the source route option of the original packet UNLESS the
ICMP error message is an ICMP Parameter Problem complaining about a
source route option in the original packet, or unless the router is
aware of policy that would prevent the delivery of the ICMP error
message.
DISCUSSION
In environments which use the U.S. Department of Defense security
option (defined in [INTERNET:5]), ICMP messages may need to
include a security option. Detailed information on this topic
should be available from the Defense Communications Agency.
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An ICMP error message MUST NOT be sent as the result of receiving:
o An ICMP error message, or
o A packet which fails the IP header validation tests described in
Section [5.2.2] (except where that section specifically permits
the sending of an ICMP error message), or
o A packet destined to an IP broadcast or IP multicast address, or
o A packet sent as a Link Layer broadcast or multicast, or
o A packet whose source address has a network prefix of zero or is an
invalid source address (as defined in Section [5.3.7]), or
o Any fragment of a datagram other then the first fragment (i.e., a
packet for which the fragment offset in the IP header is nonzero).
Furthermore, an ICMP error message MUST NOT be sent in any case where
this memo states that a packet is to be silently discarded.
NOTE: THESE RESTRICTIONS TAKE PRECEDENCE OVER ANY REQUIREMENT
ELSEWHERE IN THIS DOCUMENT FOR SENDING ICMP ERROR MESSAGES.
DISCUSSION
These rules aim to prevent the broadcast storms that have resulted
from routers or hosts returning ICMP error messages in response to
broadcast packets. For example, a broadcast UDP packet to a non-
existent port could trigger a flood of ICMP Destination
Unreachable datagrams from all devices that do not have a client
for that destination port. On a large Ethernet, the resulting
collisions can render the network useless for a second or more.
Every packet that is broadcast on the connected network should
have a valid IP broadcast address as its IP destination (see
Section [5.3.4] and [INTRO:2]). However, some devices violate
this rule. To be certain to detect broadcast packets, therefore,
routers are required to check for a link-layer broadcast as well
as an IP-layer address.
IMPLEMENTATION+ This requires that the link layer inform the IP layer
when a link-layer broadcast packet has been received; see Section
[3.1].
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A router which sends ICMP Source Quench messages MUST be able to
limit the rate at which the messages can be generated. A router
SHOULD also be able to limit the rate at which it sends other sorts
of ICMP error messages (Destination Unreachable, Redirect, Time
Exceeded, Parameter Problem). The rate limit parameters SHOULD be
settable as part of the configuration of the router. How the limits
are applied (e.g., per router or per interface) is left to the
implementor's discretion.
DISCUSSION
Two problems for a router sending ICMP error message are:
(1) The consumption of bandwidth on the reverse path, and
(2) The use of router resources (e.g., memory, CPU time)
To help solve these problems a router can limit the frequency with
which it generates ICMP error messages. For similar reasons, a
router may limit the frequency at which some other sorts of
messages, such as ICMP Echo Replies, are generated.
IMPLEMENTATION
Various mechanisms have been used or proposed for limiting the
rate at which ICMP messages are sent:
(1) Count-based - for example, send an ICMP error message for
every N dropped packets overall or per given source host.
This mechanism might be appropriate for ICMP Source Quench,
if used, but probably not for other types of ICMP messages.
(2) Timer-based - for example, send an ICMP error message to a
given source host or overall at most once per T milliseconds.
(3) Bandwidth-based - for example, limit the rate at which ICMP
messages are sent over a particular interface to some
fraction of the attached network's bandwidth.
If a router cannot forward a packet because it has no routes at all
(including no default route) to the destination specified in the
packet, then the router MUST generate a Destination Unreachable, Code
0 (Network Unreachable) ICMP message. If the router does have routes
to the destination network specified in the packet but the TOS
specified for the routes is neither the default TOS (0000) nor the
TOS of the packet that the router is attempting to route, then the
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router MUST generate a Destination Unreachable, Code 11 (Network
Unreachable for TOS) ICMP message.
If a packet is to be forwarded to a host on a network that is
directly connected to the router (i.e., the router is the last-hop
router) and the router has ascertained that there is no path to the
destination host then the router MUST generate a Destination
Unreachable, Code 1 (Host Unreachable) ICMP message. If a packet is
to be forwarded to a host that is on a network that is directly
connected to the router and the router cannot forward the packet
because no route to the destination has a TOS that is either equal to
the TOS requested in the packet or is the default TOS (0000) then the
router MUST generate a Destination Unreachable, Code 12 (Host
Unreachable for TOS) ICMP message.
DISCUSSION
The intent is that a router generates the "generic" host/network
unreachable if it has no path at all (including default routes) to
the destination. If the router has one or more paths to the
destination, but none of those paths have an acceptable TOS, then
the router generates the "unreachable for TOS" message.
The ICMP Redirect message is generated to inform a local host that it
should use a different next hop router for certain traffic.
Contrary to [INTRO:2], a router MAY ignore ICMP Redirects when
choosing a path for a packet originated by the router if the router
is running a routing protocol or if forwarding is enabled on the
router and on the interface over which the packet is being sent.
A router SHOULD NOT originate ICMP Source Quench messages. As
specified in Section [4.3.2], a router that does originate Source
Quench messages MUST be able to limit the rate at which they are
generated.
DISCUSSION
Research seems to suggest that Source Quench consumes network
bandwidth but is an ineffective (and unfair) antidote to
congestion. See, for example, [INTERNET:9] and [INTERNET:10].
Section [5.3.6] discusses the current thinking on how routers
ought to deal with overload and network congestion.
A router MAY ignore any ICMP Source Quench messages it receives.
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DISCUSSION
A router itself may receive a Source Quench as the result of
originating a packet sent to another router or host. Such
datagrams might be, e.g., an EGP update sent to another router, or
a telnet stream sent to a host. A mechanism has been proposed
([INTERNET:11], [INTERNET:12]) to make the IP layer respond
directly to Source Quench by controlling the rate at which packets
are sent, however, this proposal is currently experimental and not
currently recommended.
When a router is forwarding a packet and the TTL field of the packet
is reduced to 0, the requirements of section [5.2.3.8] apply.
When the router is reassembling a packet that is destined for the
router, it is acting as an Internet host. [INTRO:2]'s reassembly
requirements therefore apply.
When the router receives (i.e., is destined for the router) a Time
Exceeded message, it MUST comply with [INTRO:2].
A router MUST generate a Parameter Problem message for any error not
specifically covered by another ICMP message. The IP header field or
IP option including the byte indicated by the pointer field MUST be
included unchanged in the IP header returned with this ICMP message.
Section [4.3.2] defines an exception to this requirement.
A new variant of the Parameter Problem message was defined in
[INTRO:2]:
Code 1 = required option is missing.
DISCUSSION
This variant is currently in use in the military community for a
missing security option.
A router MUST implement an ICMP Echo server function that receives
Echo Requests sent to the router, and sends corresponding Echo
Replies. A router MUST be prepared to receive, reassemble and echo
an ICMP Echo Request datagram at least as the maximum of 576 and the
MTUs of all the connected networks.
The Echo server function MAY choose not to respond to ICMP echo
requests addressed to IP broadcast or IP multicast addresses.
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A router SHOULD have a configuration option that, if enabled, causes
the router to silently ignore all ICMP echo requests; if provided,
this option MUST default to allowing responses.
DISCUSSION
The neutral provision about responding to broadcast and multicast
Echo Requests derives from [INTRO:2]'s "Echo Request/Reply"
section.
As stated in Section [10.3.3], a router MUST also implement a
user/application-layer interface for sending an Echo Request and
receiving an Echo Reply, for diagnostic purposes. All ICMP Echo
Reply messages MUST be passed to this interface.
The IP source address in an ICMP Echo Reply MUST be the same as the
specific-destination address of the corresponding ICMP Echo Request
message.
Data received in an ICMP Echo Request MUST be entirely included in
the resulting Echo Reply.
If a Record Route and/or Timestamp option is received in an ICMP Echo
Request, this option (these options) SHOULD be updated to include the
current router and included in the IP header of the Echo Reply
message, without truncation. Thus, the recorded route will be for
the entire round trip.
If a Source Route option is received in an ICMP Echo Request, the
return route MUST be reversed and used as a Source Route option for
the Echo Reply message, unless the router is aware of policy that
would prevent the delivery of the message.
A router SHOULD NOT originate or respond to these messages.
DISCUSSION
The Information Request/Reply pair was intended to support self-
configuring systems such as diskless workstations, to allow them
to discover their IP network prefixes at boot time. However,
these messages are now obsolete. The RARP and BOOTP protocols
provide better mechanisms for a host to discover its own IP
address.
A router MAY implement Timestamp and Timestamp Reply. If they are
implemented then:
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o The ICMP Timestamp server function MUST return a Timestamp Reply to
every Timestamp message that is received. It SHOULD be designed
for minimum variability in delay.
o An ICMP Timestamp Request message to an IP broadcast or IP
multicast address MAY be silently discarded.
o The IP source address in an ICMP Timestamp Reply MUST be the same
as the specific-destination address of the corresponding Timestamp
Request message.
o If a Source Route option is received in an ICMP Timestamp Request,
the return route MUST be reversed and used as a Source Route
option for the Timestamp Reply message, unless the router is aware
of policy that would prevent the delivery of the message.
o If a Record Route and/or Timestamp option is received in a
Timestamp Request, this (these) option(s) SHOULD be updated to
include the current router and included in the IP header of the
Timestamp Reply message.
o If the router provides an application-layer interface for sending
Timestamp Request messages then incoming Timestamp Reply messages
MUST be passed up to the ICMP user interface.
The preferred form for a timestamp value (the standard value) is
milliseconds since midnight, Universal Time. However, it may be
difficult to provide this value with millisecond resolution. For
example, many systems use clocks that update only at line frequency,
50 or 60 times per second. Therefore, some latitude is allowed in a
standard value:
(a) A standard value MUST be updated at least 16 times per second
(i.e., at most the six low-order bits of the value may be
undefined).
(b) The accuracy of a standard value MUST approximate that of
operator-set CPU clocks, i.e., correct within a few minutes.
IMPLEMENTATION
To meet the second condition, a router may need to query some time
server when the router is booted or restarted. It is recommended
that the UDP Time Server Protocol be used for this purpose. A
more advanced implementation would use the Network Time Protocol
(NTP) to achieve nearly millisecond clock synchronization;
however, this is not required.
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A router MUST implement support for receiving ICMP Address Mask
Request messages and responding with ICMP Address Mask Reply
messages. These messages are defined in [INTERNET:2].
A router SHOULD have a configuration option for each logical
interface specifying whether the router is allowed to answer Address
Mask Requests for that interface; this option MUST default to
allowing responses. A router MUST NOT respond to an Address Mask
Request before the router knows the correct address mask.
A router MUST NOT respond to an Address Mask Request that has a
source address of 0.0.0.0 and which arrives on a physical interface
that has associated with it multiple logical interfaces and the
address masks for those interfaces are not all the same.
A router SHOULD examine all ICMP Address Mask Replies that it
receives to determine whether the information it contains matches the
router's knowledge of the address mask. If the ICMP Address Mask
Reply appears to be in error, the router SHOULD log the address mask
and the sender's IP address. A router MUST NOT use the contents of
an ICMP Address Mask Reply to determine the correct address mask.
Because hosts may not be able to learn the address mask if a router
is down when the host boots up, a router MAY broadcast a gratuitous
ICMP Address Mask Reply on each of its logical interfaces after it
has configured its own address masks. However, this feature can be
dangerous in environments that use variable length address masks.
Therefore, if this feature is implemented, gratuitous Address Mask
Replies MUST NOT be broadcast over any logical interface(s) which
either:
o Are not configured to send gratuitous Address Mask Replies. Each
logical interface MUST have a configuration parameter controlling
this, and that parameter MUST default to not sending the
gratuitous Address Mask Replies.
o Share subsuming (but not identical) network prefixes and physical
interface.
The { <Network-prefix>, -1 } form of the IP broadcast address MUST be
used for broadcast Address Mask Replies.
DISCUSSION
The ability to disable sending Address Mask Replies by routers is
required at a few sites that intentionally lie to their hosts
about the address mask. The need for this is expected to go away
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as more and more hosts become compliant with the Host Requirements
standards.
The reason for both the second bullet above and the requirement
about which IP broadcast address to use is to prevent problems
when multiple IP network prefixes are in use on the same physical
network.
An IP router MUST support the router part of the ICMP Router
Discovery Protocol [INTERNET:13] on all connected networks on which
the router supports either IP multicast or IP broadcast addressing.
The implementation MUST include all the configuration variables
specified for routers, with the specified defaults.
DISCUSSION
Routers are not required to implement the host part of the ICMP
Router Discovery Protocol, but might find it useful for operation
while IP forwarding is disabled (i.e., when operating as a host).
DISCUSSION We note that it is quite common for hosts to use RIP
Version 1 as the router discovery protocol. Such hosts listen to
RIP traffic and use and use information extracted from that
traffic to discover routers and to make decisions as to which
router to use as a first-hop router for a given destination.
While this behavior is discouraged, it is still common and
implementors should be aware of it.
IGMP [INTERNET:4] is a protocol used between hosts and multicast
routers on a single physical network to establish hosts' membership
in particular multicast groups. Multicast routers use this
information, in conjunction with a multicast routing protocol, to
support IP multicast forwarding across the Internet.
A router SHOULD implement the host part of IGMP.
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There is no separate specification of the forwarding function in IP.
Instead, forwarding is covered by the protocol specifications for the
internet layer protocols ([INTERNET:1], [INTERNET:2], [INTERNET:3],
[INTERNET:8], and [ROUTE:11]).
Since none of the primary protocol documents describe the forwarding
algorithm in any detail, we present it here. This is just a general
outline, and omits important details, such as handling of congestion,
that are dealt with in later sections.
It is not required that an implementation follow exactly the
algorithms given in sections [5.2.1.1], [5.2.1.2], and [5.2.1.3].
Much of the challenge of writing router software is to maximize the
rate at which the router can forward packets while still achieving
the same effect of the algorithm. Details of how to do that are
beyond the scope of this document, in part because they are heavily
dependent on the architecture of the router. Instead, we merely
point out the order dependencies among the steps:
(1) A router MUST verify the IP header, as described in section
[5.2.2], before performing any actions based on the contents of
the header. This allows the router to detect and discard bad
packets before the expenditure of other resources.
(2) Processing of certain IP options requires that the router insert
its IP address into the option. As noted in Section [5.2.4],
the address inserted MUST be the address of the logical
interface on which the packet is sent or the router's router-id
if the packet is sent over an unnumbered interface. Thus,
processing of these options cannot be completed until after the
output interface is chosen.
(3) The router cannot check and decrement the TTL before checking
whether the packet should be delivered to the router itself, for
reasons mentioned in Section [4.2.2.9].
(4) More generally, when a packet is delivered locally to the router,
its IP header MUST NOT be modified in any way (except that a
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router may be required to insert a timestamp into any Timestamp
options in the IP header). Thus, before the router determines
whether the packet is to be delivered locally to the router, it
cannot update the IP header in any way that it is not prepared
to undo.
This section covers the general forwarding algorithm. This algorithm
applies to all forms of packets to be forwarded: unicast, multicast,
and broadcast.
(1) The router receives the IP packet (plus additional information
about it, as described in Section [3.1]) from the Link Layer.
(2) The router validates the IP header, as described in Section
[5.2.2]. Note that IP reassembly is not done, except on IP
fragments to be queued for local delivery in step (4).
(3) The router performs most of the processing of any IP options. As
described in Section [5.2.4], some IP options require additional
processing after the routing decision has been made.
(4) The router examines the destination IP address of the IP
datagram, as described in Section [5.2.3], to determine how it
should continue to process the IP datagram. There are three
possibilities:
o The IP datagram is destined for the router, and should be
queued for local delivery, doing reassembly if needed.
o The IP datagram is not destined for the router, and should be
queued for forwarding.
o The IP datagram should be queued for forwarding, but (a copy)
must also be queued for local delivery.
Since the local delivery case is well covered by [INTRO:2], the
following assumes that the IP datagram was queued for forwarding. If
the destination is an IP unicast address:
(5) The forwarder determines the next hop IP address for the packet,
usually by looking up the packet's destination in the router's
routing table. This procedure is described in more detail in
Section [5.2.4]. This procedure also decides which network
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interface should be used to send the packet.
(6) The forwarder verifies that forwarding the packet is permitted.
The source and destination addresses should be valid, as
described in Section [5.3.7] and Section [5.3.4] If the router
supports administrative constraints on forwarding, such as those
described in Section [5.3.9], those constraints must be
satisfied.
(7) The forwarder decrements (by at least one) and checks the
packet's TTL, as described in Section [5.3.1].
(8) The forwarder performs any IP option processing that could not be
completed in step 3.
(9) The forwarder performs any necessary IP fragmentation, as
described in Section [4.2.2.7]. Since this step occurs after
outbound interface selection (step 5), all fragments of the same
datagram will be transmitted out the same interface.
(10) The forwarder determines the Link Layer address of the packet's
next hop. The mechanisms for doing this are Link Layer-
dependent (see chapter 3).
(11) The forwarder encapsulates the IP datagram (or each of the
fragments thereof) in an appropriate Link Layer frame and queues
it for output on the interface selected in step 5.
(12) The forwarder sends an ICMP redirect if necessary, as described
in Section [4.3.3.2].
If the destination is an IP multicast, the following steps are taken.
Note that the main differences between the forwarding of IP unicasts
and the forwarding of IP multicasts are
o IP multicasts are usually forwarded based on both the datagram's
source and destination IP addresses,
o IP multicast uses an expanding ring search,
o IP multicasts are forwarded as Link Level multicasts, and
o ICMP errors are never sent in response to IP multicast datagrams.
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Note that the forwarding of IP multicasts is still somewhat
experimental. As a result, the algorithm presented below is not
mandatory, and is provided as an example only.
(5a) Based on the IP source and destination addresses found in the
datagram header, the router determines whether the datagram has
been received on the proper interface for forwarding. If not,
the datagram is dropped silently. The method for determining
the proper receiving interface depends on the multicast routing
algorithm(s) in use. In one of the simplest algorithms, reverse
path forwarding (RPF), the proper interface is the one that
would be used to forward unicasts back to the datagram source.
(6a) Based on the IP source and destination addresses found in the
datagram header, the router determines the datagram's outgoing
interfaces. To implement IP multicast's expanding ring search
(see [INTERNET:4]) a minimum TTL value is specified for each
outgoing interface. A copy of the multicast datagram is
forwarded out each outgoing interface whose minimum TTL value is
less than or equal to the TTL value in the datagram header, by
separately applying the remaining steps on each such interface.
(7a) The router decrements the packet's TTL by one.
(8a) The forwarder performs any IP option processing that could not
be completed in step (3).
(9a) The forwarder performs any necessary IP fragmentation, as
described in Section [4.2.2.7].
(10a) The forwarder determines the Link Layer address to use in the
Link Level encapsulation. The mechanisms for doing this are
Link Layer-dependent. On LANs a Link Level multicast or
broadcast is selected, as an algorithmic translation of the
datagrams' IP multicast address. See the various IP-over-xxx
specifications for more details.
(11a) The forwarder encapsulates the packet (or each of the fragments
thereof) in an appropriate Link Layer frame and queues it for
output on the appropriate interface.
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Before a router can process any IP packet, it MUST perform a the
following basic validity checks on the packet's IP header to ensure
that the header is meaningful. If the packet fails any of the
following tests, it MUST be silently discarded, and the error SHOULD
be logged.
(1) The packet length reported by the Link Layer must be large enough
to hold the minimum length legal IP datagram (20 bytes).
(2) The IP checksum must be correct.
(3) The IP version number must be 4. If the version number is not 4
then the packet may be another version of IP, such as IPng or
ST-II.
(4) The IP header length field must be large enough to hold the
minimum length legal IP datagram (20 bytes = 5 words).
(5) The IP total length field must be large enough to hold the IP
datagram header, whose length is specified in the IP header
length field.
A router MUST NOT have a configuration option that allows disabling
any of these tests.
If the packet passes the second and third tests, the IP header length
field is at least 4, and both the IP total length field and the
packet length reported by the Link Layer are at least 16 then,
despite the above rule, the router MAY respond with an ICMP Parameter
Problem message, whose pointer points at the IP header length field
(if it failed the fourth test) or the IP total length field (if it
failed the fifth test). However, it still MUST discard the packet
and still SHOULD log the error.
These rules (and this entire document) apply only to version 4 of the
Internet Protocol. These rules should not be construed as
prohibiting routers from supporting other versions of IP.
Furthermore, if a router can truly classify a packet as being some
other version of IP then it ought not treat that packet as an error
packet within the context of this memo.
IMPLEMENTATION
It is desirable for purposes of error reporting, though not always
entirely possible, to determine why a header was invalid. There
are four possible reasons:
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o The Link Layer truncated the IP header
o The datagram is using a version of IP other than the standard
one (version 4).
o The IP header has been corrupted in transit.
o The sender generated an illegal IP header.
It is probably desirable to perform the checks in the order
listed, since we believe that this ordering is most likely to
correctly categorize the cause of the error. For purposes of
error reporting, it may also be desirable to check if a packet
that fails these tests has an IP version number indicating IPng or
ST-II; these should be handled according to their respective
specifications.
Additionally, the router SHOULD verify that the packet length
reported by the Link Layer is at least as large as the IP total
length recorded in the packet's IP header. If it appears that the
packet has been truncated, the packet MUST be discarded, the error
SHOULD be logged, and the router SHOULD respond with an ICMP
Parameter Problem message whose pointer points at the IP total length
field.
DISCUSSION
Because any higher layer protocol that concerns itself with data
corruption will detect truncation of the packet data when it
reaches its final destination, it is not absolutely necessary for
routers to perform the check suggested above to maintain protocol
correctness. However, by making this check a router can simplify
considerably the task of determining which hop in the path is
truncating the packets. It will also reduce the expenditure of
resources down-stream from the router in that down-stream systems
will not need to deal with the packet.
Finally, if the destination address in the IP header is not one of
the addresses of the router, the router SHOULD verify that the packet
does not contain a Strict Source and Record Route option. If a
packet fails this test (if it contains a strict source route option),
the router SHOULD log the error and SHOULD respond with an ICMP
Parameter Problem error with the pointer pointing at the offending
packet's IP destination address.
DISCUSSION
Some people might suggest that the router should respond with a
Bad Source Route message instead of a Parameter Problem message.
However, when a packet fails this test, it usually indicates a
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protocol error by the previous hop router, whereas Bad Source
Route would suggest that the source host had requested a
nonexistent or broken path through the network.
When a router receives an IP packet, it must decide whether the
packet is addressed to the router (and should be delivered locally)
or the packet is addressed to another system (and should be handled
by the forwarder). There is also a hybrid case, where certain IP
broadcasts and IP multicasts are both delivered locally and
forwarded. A router MUST determine which of the these three cases
applies using the following rules.
o An unexpired source route option is one whose pointer value does
not point past the last entry in the source route. If the packet
contains an unexpired source route option, the pointer in the
option is advanced until either the pointer does point past the
last address in the option or else the next address is not one of
the router's own addresses. In the latter (normal) case, the
packet is forwarded (and not delivered locally) regardless of the
rules below.
o The packet is delivered locally and not considered for forwarding
in the following cases:
- The packet's destination address exactly matches one of the
router's IP addresses,
- The packet's destination address is a limited broadcast address
({-1, -1}), or
- The packet's destination is an IP multicast address which is
never forwarded (such as 224.0.0.1 or 224.0.0.2) and (at least)
one of the logical interfaces associated with the physical
interface on which the packet arrived is a member of the
destination multicast group.
o The packet is passed to the forwarder AND delivered locally in the
following cases:
- The packet's destination address is an IP broadcast address that
addresses at least one of the router's logical interfaces but
does not address any of the logical interfaces associated with
the physical interface on which the packet arrived
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- The packet's destination is an IP multicast address which is
permitted to be forwarded (unlike 224.0.0.1 and 224.0.0.2) and
(at least) one of the logical interfaces associated with the
physical interface on which the packet arrived is a member of
the destination multicast group.
o The packet is delivered locally if the packet's destination address
is an IP broadcast address (other than a limited broadcast
address) that addresses at least one of the logical interfaces
associated with the physical interface on which the packet
arrived. The packet is ALSO passed to the forwarder unless the
link on which the packet arrived uses an IP encapsulation that
does not encapsulate broadcasts differently than unicasts (e.g.,
by using different Link Layer destination addresses).
o The packet is passed to the forwarder in all other cases.
DISCUSSION
The purpose of the requirement in the last sentence of the fourth
bullet is to deal with a directed broadcast to another network
prefix on the same physical cable. Normally, this works as
expected: the sender sends the broadcast to the router as a Link
Layer unicast. The router notes that it arrived as a unicast, and
therefore must be destined for a different network prefix than the
sender sent it on. Therefore, the router can safely send it as a
Link Layer broadcast out the same (physical) interface over which
it arrived. However, if the router can't tell whether the packet
was received as a Link Layer unicast, the sentence ensures that
the router does the safe but wrong thing rather than the unsafe
but right thing.
IMPLEMENTATION
As described in Section [5.3.4], packets received as Link Layer
broadcasts are generally not forwarded. It may be advantageous to
avoid passing to the forwarder packets it would later discard
because of the rules in that section.
Some Link Layers (either because of the hardware or because of
special code in the drivers) can deliver to the router copies of
all Link Layer broadcasts and multicasts it transmits. Use of
this feature can simplify the implementation of cases where a
packet has to both be passed to the forwarder and delivered
locally, since forwarding the packet will automatically cause the
router to receive a copy of the packet that it can then deliver
locally. One must use care in these circumstances to prevent
treating a received loop-back packet as a normal packet that was
received (and then being subject to the rules of forwarding,
etc.).
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Even without such a Link Layer, it is of course hardly necessary
to make a copy of an entire packet to queue it both for forwarding
and for local delivery, though care must be taken with fragments,
since reassembly is performed on locally delivered packets but not
on forwarded packets. One simple scheme is to associate a flag
with each packet on the router's output queue that indicates
whether it should be queued for local delivery after it has been
sent.
When a router is going to forward a packet, it must determine whether
it can send it directly to its destination, or whether it needs to
pass it through another router. If the latter, it needs to determine
which router to use. This section explains how these determinations
are made.
This section makes use of the following definitions:
o LSRR - IP Loose Source and Record Route option
o SSRR - IP Strict Source and Record Route option
o Source Route Option - an LSRR or an SSRR
o Ultimate Destination Address - where the packet is being sent to:
the last address in the source route of a source-routed packet, or
the destination address in the IP header of a non-source-routed
packet
o Adjacent - reachable without going through any IP routers
o Next Hop Address - the IP address of the adjacent host or router to
which the packet should be sent next
o IP Destination Address - the ultimate destination address, except
in source routed packets, where it is the next address specified
in the source route
o Immediate Destination - the node, System, router, end-system, or
whatever that is addressed by the IP Destination Address.
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If:
o the destination address in the IP header is one of the addresses of
the router,
o the packet contains a Source Route Option, and
o the pointer in the Source Route Option does not point past the end
of the option,
then the next IP Destination Address is the address pointed at by the
pointer in that option. If:
o the destination address in the IP header is one of the addresses of
the router,
o the packet contains a Source Route Option, and
o the pointer in the Source Route Option points past the end of the
option,
then the message is addressed to the system analyzing the message.
A router MUST use the IP Destination Address, not the Ultimate
Destination Address (the last address in the source route option),
when determining how to handle a packet.
It is an error for more than one source route option to appear in a
datagram. If it receives such a datagram, it SHOULD discard the
packet and reply with an ICMP Parameter Problem message whose pointer
points at the beginning of the second source route option.
After it has been determined that the IP packet needs to be forwarded
according to the rules specified in Section [5.2.3], the following
algorithm MUST be used to determine if the Immediate Destination is
directly accessible (see [INTERNET:2]).
(1) For each network interface that has not been assigned any IP
address (the unnumbered lines as described in Section [2.2.7]),
compare the router-id of the other end of the line to the IP
Destination Address. If they are exactly equal, the packet can
be transmitted through this interface.
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DISCUSSION
In other words, the router or host at the remote end of the line
is the destination of the packet or is the next step in the source
route of a source routed packet.
(2) If no network interface has been selected in the first step, for
each IP address assigned to the router:
(a) isolate the network prefix used by the interface.
IMPLEMENTATION
The result of this operation will usually have been computed and
saved during initialization.
(b) Isolate the corresponding set of bits from the IP Destination
Address of the packet.
(c) Compare the resulting network prefixes. If they are equal to
each other, the packet can be transmitted through the
corresponding network interface.
(3) If the destination was neither the router-id of a neighbor on an
unnumbered interface nor a member of a directly connected network
prefix, the IP Destination is accessible only through some other
router. The selection of the router and the next hop IP address
is described in Section [5.2.4.3]. In the case of a host that is
not also a router, this may be the configured default router.
Ongoing work in the IETF [ARCH:9, NRHP] considers some cases such as
when multiple IP (sub)networks are overlaid on the same link layer
network. Barring policy restrictions, hosts and routers using a
common link layer network can directly communicate even if they are
not in the same IP (sub)network, if there is adequate information
present. The Next Hop Routing Protocol (NHRP) enables IP entities to
determine the "optimal" link layer address to be used to traverse
such a link layer network towards a remote destination.
(4) If the selected "next hop" is reachable through an interface
configured to use NHRP, then the following additional steps apply:
(a) Compare the IP Destination Address to the destination addresses
in the NHRP cache. If the address is in the cache, then send
the datagram to the corresponding cached link layer address.
(b) If the address is not in the cache, then construct an NHRP
request packet containing the IP Destination Address. This
message is sent to the NHRP server configured for that
interface. This may be a logically separate process or entity
in the router itself.
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(c) The NHRP server will respond with the proper link layer address
to use to transmit the datagram and subsequent datagrams to the
same destination. The system MAY transmit the datagram(s) to
the traditional "next hop" router while awaiting the NHRP reply.
EDITORS+COMMENTS
The router applies the algorithm in the previous section to
determine if the IP Destination Address is adjacent. If so, the
next hop address is the same as the IP Destination Address.
Otherwise, the packet must be forwarded through another router to
reach its Immediate Destination. The selection of this router is
the topic of this section.
If the packet contains an SSRR, the router MUST discard the packet
and reply with an ICMP Bad Source Route error. Otherwise, the
router looks up the IP Destination Address in its routing table to
determine an appropriate next hop address.
DISCUSSION
Per the IP specification, a Strict Source Route must specify a
sequence of nodes through which the packet must traverse; the
packet must go from one node of the source route to the next,
traversing intermediate networks only. Thus, if the router is not
adjacent to the next step of the source route, the source route
can not be fulfilled. Therefore, the router rejects such with an
ICMP Bad Source Route error.
The goal of the next-hop selection process is to examine the entries
in the router's Forwarding Information Base (FIB) and select the best
route (if there is one) for the packet from those available in the
FIB.
Conceptually, any route lookup algorithm starts out with a set of
candidate routes that consists of the entire contents of the FIB.
The algorithm consists of a series of steps that discard routes from
the set. These steps are referred to as Pruning Rules. Normally,
when the algorithm terminates there is exactly one route remaining in
the set. If the set ever becomes empty, the packet is discarded
because the destination is unreachable. It is also possible for the
algorithm to terminate when more than one route remains in the set.
In this case, the router may arbitrarily discard all but one of them,
or may perform "load-splitting" by choosing whichever of the routes
has been least recently used.
With the exception of rule 3 (Weak TOS), a router MUST use the
following Pruning Rules when selecting a next hop for a packet. If a
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router does consider TOS when making next-hop decisions, the Rule 3
must be applied in the order indicated below. These rules MUST be
(conceptually) applied to the FIB in the order that they are
presented. (For some historical perspective, additional pruning
rules, and other common algorithms in use, see Appendix E.)
DISCUSSION
Rule 3 is optional in that Section [5.3.2] says that a router only
SHOULD consider TOS when making forwarding decisions.
(1) Basic Match
This rule discards any routes to destinations other than the
IP Destination Address of the packet. For example, if a
packet's IP Destination Address is 10.144.2.5, this step
would discard a route to net 128.12.0.0/16 but would retain
any routes to the network prefixes 10.0.0.0/8 and
10.144.0.0/16, and any default routes.
More precisely, we assume that each route has a destination
attribute, called route.dest and a corresponding prefix
length, called route.length, to specify which bits of
route.dest are significant. The IP Destination Address of
the packet being forwarded is ip.dest. This rule discards
all routes from the set of candidates except those for which
the most significant route.length bits of route.dest and
ip.dest are equal.
For example, if a packet's IP Destination Address is
10.144.2.5 and there are network prefixes 10.144.1.0/24,
10.144.2.0/24, and 10.144.3.0/24, this rule would keep only
10.144.2.0/24; it is the only route whose prefix has the same
value as the corresponding bits in the IP Destination Address
of the packet.
(2) Longest Match
Longest Match is a refinement of Basic Match, described
above. After performing Basic Match pruning, the algorithm
examines the remaining routes to determine which among them
have the largest route.length values. All except these are
discarded.
For example, if a packet's IP Destination Address is
10.144.2.5 and there are network prefixes 10.144.2.0/24,
10.144.0.0/16, and 10.0.0.0/8, then this rule would keep only
the first (10.144.2.0/24) because its prefix length is
longest.
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(3) Weak TOS
Each route has a type of service attribute, called route.tos,
whose possible values are assumed to be identical to those
used in the TOS field of the IP header. Routing protocols
that distribute TOS information fill in route.tos
appropriately in routes they add to the FIB; routes from
other routing protocols are treated as if they have the
default TOS (0000). The TOS field in the IP header of the
packet being routed is called ip.tos.
The set of candidate routes is examined to determine if it
contains any routes for which route.tos = ip.tos. If so, all
routes except those for which route.tos = ip.tos are
discarded. If not, all routes except those for which
route.tos = 0000 are discarded from the set of candidate
routes.
Additional discussion of routing based on Weak TOS may be
found in [ROUTE:11].
DISCUSSION
The effect of this rule is to select only those routes that have a
TOS that matches the TOS requested in the packet. If no such
routes exist then routes with the default TOS are considered.
Routes with a non-default TOS that is not the TOS requested in the
packet are never used, even if such routes are the only available
routes that go to the packet's destination.
(4) Best Metric
Each route has a metric attribute, called route.metric, and a
routing domain identifier, called route.domain. Each member
of the set of candidate routes is compared with each other
member of the set. If route.domain is equal for the two
routes and route.metric is strictly inferior for one when
compared with the other, then the one with the inferior metric
is discarded from the set. The determination of inferior is
usually by a simple arithmetic comparison, though some
protocols may have structured metrics requiring more complex
comparisons.
(5) Vendor Policy
Vendor Policy is sort of a catch-all to make up for the fact
that the previously listed rules are often inadequate to
choose from the possible routes. Vendor Policy pruning rules
are extremely vendor-specific. See section [5.2.4.4].
This algorithm has two distinct disadvantages. Presumably, a
router implementor might develop techniques to deal with these
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disadvantages and make them a part of the Vendor Policy pruning
rule.
(1) IS-IS and OSPF route classes are not directly handled.
(2) Path properties other than type of service (e.g., MTU) are
ignored.
It is also worth noting a deficiency in the way that TOS is
supported: routing protocols that support TOS are implicitly
preferred when forwarding packets that have non-zero TOS values.
The Basic Match and Longest Match pruning rules generalize the
treatment of a number of particular types of routes. These routes
are selected in the following, decreasing, order of preference:
(1) Host Route: This is a route to a specific end system.
(2) Hierarchical Network Prefix Routes: This is a route to a
particular network prefix. Note that the FIB may contain
several routes to network prefixes that subsume each other
(one prefix is the other prefix with additional bits). These
are selected in order of decreasing prefix length.
(5) Default Route: This is a route to all networks for which there
are no explicit routes. It is by definition the route whose
prefix length is zero.
If, after application of the pruning rules, the set of routes is
empty (i.e., no routes were found), the packet MUST be discarded
and an appropriate ICMP error generated (ICMP Bad Source Route if
the IP Destination Address came from a source route option;
otherwise, whichever of ICMP Destination Host Unreachable or
Destination Network Unreachable is appropriate, as described in
Section [4.3.3.1]).
One suggested mechanism for the Vendor Policy Pruning Rule is to
use administrative preference, which is a simple prioritization
algorithm. The idea is to manually prioritize the routes that one
might need to select among.
Each route has associated with it a preference value, based on
various attributes of the route (specific mechanisms for assignment
of preference values are suggested below). This preference value
is an integer in the range [0..255], with zero being the most
preferred and 254 being the least preferred. 255 is a special
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value that means that the route should never be used. The first
step in the Vendor Policy pruning rule discards all but the most
preferable routes (and always discards routes whose preference
value is 255).
This policy is not safe in that it can easily be misused to create
routing loops. Since no protocol ensures that the preferences
configured for a router is consistent with the preferences
configured in its neighbors, network managers must exercise care in
configuring preferences.
o Address Match
It is useful to be able to assign a single preference value to
all routes (learned from the same routing domain) to any of a
specified set of destinations, where the set of destinations is
all destinations that match a specified network prefix.
o Route Class
For routing protocols which maintain the distinction, it is
useful to be able to assign a single preference value to all
routes (learned from the same routing domain) which have a
particular route class (intra-area, inter-area, external with
internal metrics, or external with external metrics).
o Interface
It is useful to be able to assign a single preference value to
all routes (learned from a particular routing domain) that would
cause packets to be routed out a particular logical interface on
the router (logical interfaces generally map one-to-one onto the
router's network interfaces, except that any network interface
that has multiple IP addresses will have multiple logical
interfaces associated with it).
o Source router
It is useful to be able to assign a single preference value to
all routes (learned from the same routing domain) that were
learned from any of a set of routers, where the set of routers
are those whose updates have a source address that match a
specified network prefix.
o Originating AS
For routing protocols which provide the information, it is
useful to be able to assign a single preference value to all
routes (learned from a particular routing domain) which
originated in another particular routing domain. For BGP
routes, the originating AS is the first AS listed in the route's
AS_PATH attribute. For OSPF external routes, the originating AS
may be considered to be the low order 16 bits of the route's
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external route tag if the tag's Automatic bit is set and the
tag's Path Length is not equal to 3.
o External route tag
It is useful to be able to assign a single preference value to
all OSPF external routes (learned from the same routing domain)
whose external route tags match any of a list of specified
values. Because the external route tag may contain a structured
value, it may be useful to provide the ability to match
particular subfields of the tag.
o AS path
It may be useful to be able to assign a single preference value
to all BGP routes (learned from the same routing domain) whose
AS path "matches" any of a set of specified values. It is not
yet clear exactly what kinds of matches are most useful. A
simple option would be to allow matching of all routes for which
a particular AS number appears (or alternatively, does not
appear) anywhere in the route's AS_PATH attribute. A more
general but somewhat more difficult alternative would be to
allow matching all routes for which the AS path matches a
specified regular expression.
At the end of the Next-hop selection process, multiple routes may
still remain. A router has several options when this occurs. It
may arbitrarily discard some of the routes. It may reduce the
number of candidate routes by comparing metrics of routes from
routing domains that are not considered equivalent. It may retain
more than one route and employ a load-splitting mechanism to divide
traffic among them. Perhaps the only thing that can be said about
the relative merits of the options is that load-splitting is useful
in some situations but not in others, so a wise implementor who
implements load-splitting will also provide a way for the network
manager to disable it.
The IP header contains several reserved bits, in the Type of
Service field and in the Flags field. Routers MUST NOT drop
packets merely because one or more of these reserved bits has a
non-zero value.
Routers MUST ignore and MUST pass through unchanged the values of
these reserved bits. If a router fragments a packet, it MUST copy
these bits into each fragment.
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DISCUSSION
Future revisions to the IP protocol may make use of these unused
bits. These rules are intended to ensure that these revisions can
be deployed without having to simultaneously upgrade all routers
in the Internet.
As was discussed in Section [4.2.2.7], a router MUST support IP
fragmentation.
A router MUST NOT reassemble any datagram before forwarding it.
DISCUSSION
A few people have suggested that there might be some topologies
where reassembly of transit datagrams by routers might improve
performance. The fact that fragments may take different paths to
the destination precludes safe use of such a feature.
Nothing in this section should be construed to control or limit
fragmentation or reassembly performed as a link layer function by
the router.
Similarly, if an IP datagram is encapsulated in another IP
datagram (e.g., it is tunnelled), that datagram is in turn
fragmented, the fragments must be reassembled in order to forward
the original datagram. This section does not preclude this.
The ICMP Destination Unreachable message is sent by a router in
response to a packet which it cannot forward because the destination
(or next hop) is unreachable or a service is unavailable. Examples
of such cases include a message addressed to a host which is not
there and therefore does not respond to ARP requests, and messages
addressed to network prefixes for which the router has no valid
route.
A router MUST be able to generate ICMP Destination Unreachable
messages and SHOULD choose a response code that most closely matches
the reason the message is being generated.
The following codes are defined in [INTERNET:8] and [INTRO:2]:
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0 = Network Unreachable - generated by a router if a forwarding path
(route) to the destination network is not available;
1 = Host Unreachable - generated by a router if a forwarding path
(route) to the destination host on a directly connected network
is not available (does not respond to ARP);
2 = Protocol Unreachable - generated if the transport protocol
designated in a datagram is not supported in the transport layer
of the final destination;
3 = Port Unreachable - generated if the designated transport protocol
(e.g., UDP) is unable to demultiplex the datagram in the
transport layer of the final destination but has no protocol
mechanism to inform the sender;
4 = Fragmentation Needed and DF Set - generated if a router needs to
fragment a datagram but cannot since the DF flag is set;
5 = Source Route Failed - generated if a router cannot forward a
packet to the next hop in a source route option;
6 = Destination Network Unknown - This code SHOULD NOT be generated
since it would imply on the part of the router that the
destination network does not exist (net unreachable code 0
SHOULD be used in place of code 6);
7 = Destination Host Unknown - generated only when a router can
determine (from link layer advice) that the destination host
does not exist;
11 = Network Unreachable For Type Of Service - generated by a router
if a forwarding path (route) to the destination network with the
requested or default TOS is not available;
12 = Host Unreachable For Type Of Service - generated if a router
cannot forward a packet because its route(s) to the destination
do not match either the TOS requested in the datagram or the
default TOS (0).
The following additional codes are hereby defined:
13 = Communication Administratively Prohibited - generated if a
router cannot forward a packet due to administrative filtering;
14 = Host Precedence Violation. Sent by the first hop router to a
host to indicate that a requested precedence is not permitted
for the particular combination of source/destination host or
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network, upper layer protocol, and source/destination port;
15 = Precedence cutoff in effect. The network operators have imposed
a minimum level of precedence required for operation, the
datagram was sent with a precedence below this level;
NOTE: [INTRO:2] defined Code 8 for source host isolated. Routers
SHOULD NOT generate Code 8; whichever of Codes 0 (Network
Unreachable) and 1 (Host Unreachable) is appropriate SHOULD be used
instead. [INTRO:2] also defined Code 9 for communication with
destination network administratively prohibited and Code 10 for
communication with destination host administratively prohibited.
These codes were intended for use by end-to-end encryption devices
used by U.S military agencies. Routers SHOULD use the newly defined
Code 13 (Communication Administratively Prohibited) if they
administratively filter packets.
Routers MAY have a configuration option that causes Code 13
(Communication Administratively Prohibited) messages not to be
generated. When this option is enabled, no ICMP error message is
sent in response to a packet that is dropped because its forwarding
is administratively prohibited.
Similarly, routers MAY have a configuration option that causes Code
14 (Host Precedence Violation) and Code 15 (Precedence Cutoff in
Effect) messages not to be generated. When this option is enabled,
no ICMP error message is sent in response to a packet that is dropped
because of a precedence violation.
Routers MUST use Host Unreachable or Destination Host Unknown codes
whenever other hosts on the same destination network might be
reachable; otherwise, the source host may erroneously conclude that
all hosts on the network are unreachable, and that may not be the
case.
[INTERNET:14] describes a slight modification the form of Destination
Unreachable messages containing Code 4 (Fragmentation needed and DF
set). A router MUST use this modified form when originating Code 4
Destination Unreachable messages.
The ICMP Redirect message is generated to inform a local host the it
should use a different next hop router for a certain class of
traffic.
Routers MUST NOT generate the Redirect for Network or Redirect for
Network and Type of Service messages (Codes 0 and 2) specified in
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[INTERNET:8]. Routers MUST be able to generate the Redirect for Host
message (Code 1) and SHOULD be able to generate the Redirect for Type
of Service and Host message (Code 3) specified in [INTERNET:8].
DISCUSSION
If the directly connected network is not subnetted (in the
classical sense), a router can normally generate a network
Redirect that applies to all hosts on a specified remote network.
Using a network rather than a host Redirect may economize slightly
on network traffic and on host routing table storage. However,
the savings are not significant, and subnets create an ambiguity
about the subnet mask to be used to interpret a network Redirect.
In a CIDR environment, it is difficult to specify precisely the
cases in which network Redirects can be used. Therefore, routers
must send only host (or host and type of service) Redirects.
A Code 3 (Redirect for Host and Type of Service) message is generated
when the packet provoking the redirect has a destination for which
the path chosen by the router would depend (in part) on the TOS
requested.
Routers that can generate Code 3 redirects (Host and Type of Service)
MUST have a configuration option (which defaults to on) to enable
Code 1 (Host) redirects to be substituted for Code 3 redirects. A
router MUST send a Code 1 Redirect in place of a Code 3 Redirect if
it has been configured to do so.
If a router is not able to generate Code 3 Redirects then it MUST
generate Code 1 Redirects in situations where a Code 3 Redirect is
called for.
Routers MUST NOT generate a Redirect Message unless all the following
conditions are met:
o The packet is being forwarded out the same physical interface that
it was received from,
o The IP source address in the packet is on the same Logical IP
(sub)network as the next-hop IP address, and
o The packet does not contain an IP source route option.
The source address used in the ICMP Redirect MUST belong to the same
logical (sub)net as the destination address.
A router using a routing protocol (other than static routes) MUST NOT
consider paths learned from ICMP Redirects when forwarding a packet.
If a router is not using a routing protocol, a router MAY have a
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configuration that, if set, allows the router to consider routes
learned through ICMP Redirects when forwarding packets.
DISCUSSION
ICMP Redirect is a mechanism for routers to convey routing
information to hosts. Routers use other mechanisms to learn
routing information, and therefore have no reason to obey
redirects. Believing a redirect which contradicted the router's
other information would likely create routing loops.
On the other hand, when a router is not acting as a router, it
MUST comply with the behavior required of a host.
A router MUST generate a Time Exceeded message Code 0 (In Transit)
when it discards a packet due to an expired TTL field. A router MAY
have a per-interface option to disable origination of these messages
on that interface, but that option MUST default to allowing the
messages to be originated.
IGMP [INTERNET:4] is a protocol used between hosts and multicast
routers on a single physical network to establish hosts' membership
in particular multicast groups. Multicast routers use this
information, in conjunction with a multicast routing protocol, to
support IP multicast forwarding across the Internet.
A router SHOULD implement the multicast router part of IGMP.
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The Time-to-Live (TTL) field of the IP header is defined to be a
timer limiting the lifetime of a datagram. It is an 8-bit field and
the units are seconds. Each router (or other module) that handles a
packet MUST decrement the TTL by at least one, even if the elapsed
time was much less than a second. Since this is very often the case,
the TTL is effectively a hop count limit on how far a datagram can
propagate through the Internet.
When a router forwards a packet, it MUST reduce the TTL by at least
one. If it holds a packet for more than one second, it MAY decrement
the TTL by one for each second.
If the TTL is reduced to zero (or less), the packet MUST be
discarded, and if the destination is not a multicast address the
router MUST send an ICMP Time Exceeded message, Code 0 (TTL Exceeded
in Transit) message to the source. Note that a router MUST NOT
discard an IP unicast or broadcast packet with a non-zero TTL merely
because it can predict that another router on the path to the
packet's final destination will decrement the TTL to zero. However,
a router MAY do so for IP multicasts, in order to more efficiently
implement IP multicast's expanding ring search algorithm (see
[INTERNET:4]).
DISCUSSION
The IP TTL is used, somewhat schizophrenically, as both a hop
count limit and a time limit. Its hop count function is critical
to ensuring that routing problems can't melt down the network by
causing packets to loop infinitely in the network. The time limit
function is used by transport protocols such as TCP to ensure
reliable data transfer. Many current implementations treat TTL as
a pure hop count, and in parts of the Internet community there is
a strong sentiment that the time limit function should instead be
performed by the transport protocols that need it.
In this specification, we have reluctantly decided to follow the
strong belief among the router vendors that the time limit
function should be optional. They argued that implementation of
the time limit function is difficult enough that it is currently
not generally done. They further pointed to the lack of
documented cases where this shortcut has caused TCP to corrupt
data (of course, we would expect the problems created to be rare
and difficult to reproduce, so the lack of documented cases
provides little reassurance that there haven't been a number of
undocumented cases).
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IP multicast notions such as the expanding ring search may not
work as expected unless the TTL is treated as a pure hop count.
The same thing is somewhat true of traceroute.
ICMP Time Exceeded messages are required because the traceroute
diagnostic tool depends on them.
Thus, the tradeoff is between severely crippling, if not
eliminating, two very useful tools and avoiding a very rare and
transient data transport problem that may not occur at all. We
have chosen to preserve the tools.
The Type-of-Service byte in the IP header is divided into three
sections: the Precedence field (high-order 3 bits), a field that
is customarily called Type of Service or "TOS (next 4 bits), and a
reserved bit (the low order bit). Rules governing the reserved
bit were described in Section [4.2.2.3]. The Precedence field
will be discussed in Section [5.3.3]. A more extensive discussion
of the TOS field and its use can be found in [ROUTE:11].
A router SHOULD consider the TOS field in a packet's IP header
when deciding how to forward it. The remainder of this section
describes the rules that apply to routers that conform to this
requirement.
A router MUST maintain a TOS value for each route in its routing
table. Routes learned through a routing protocol that does not
support TOS MUST be assigned a TOS of zero (the default TOS).
To choose a route to a destination, a router MUST use an algorithm
equivalent to the following:
(1) The router locates in its routing table all available routes
to the destination (see Section [5.2.4]).
(2) If there are none, the router drops the packet because the
destination is unreachable. See section [5.2.4].
(3) If one or more of those routes have a TOS that exactly matches
the TOS specified in the packet, the router chooses the route
with the best metric.
(4) Otherwise, the router repeats the above step, except looking
at routes whose TOS is zero.
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(5) If no route was chosen above, the router drops the packet
because the destination is unreachable. The router returns
an ICMP Destination Unreachable error specifying the
appropriate code: either Network Unreachable with Type of
Service (code 11) or Host Unreachable with Type of Service
(code 12).
DISCUSSION
Although TOS has been little used in the past, its use by hosts is
now mandated by the Requirements for Internet Hosts RFCs
([INTRO:2] and [INTRO:3]). Support for TOS in routers may become
a MUST in the future, but is a SHOULD for now until we get more
experience with it and can better judge both its benefits and its
costs.
Various people have proposed that TOS should affect other aspects
of the forwarding function. For example:
(1) A router could place packets that have the Low Delay bit set
ahead of other packets in its output queues.
(2) a router is forced to discard packets, it could try to avoid
discarding those which have the High Reliability bit set.
These ideas have been explored in more detail in [INTERNET:17] but
we don't yet have enough experience with such schemes to make
requirements in this area.
This section specifies requirements and guidelines for appropriate
processing of the IP Precedence field in routers. Precedence is a
scheme for allocating resources in the network based on the
relative importance of different traffic flows. The IP
specification defines specific values to be used in this field for
various types of traffic.
The basic mechanisms for precedence processing in a router are
preferential resource allocation, including both precedence-
ordered queue service and precedence-based congestion control, and
selection of Link Layer priority features. The router also
selects the IP precedence for routing, management and control
traffic it originates. For a more extensive discussion of IP
Precedence and its implementation see [FORWARD:6].
Precedence-ordered queue service, as discussed in this section,
includes but is not limited to the queue for the forwarding
process and queues for outgoing links. It is intended that a
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router supporting precedence should also use the precedence
indication at whatever points in its processing are concerned with
allocation of finite resources, such as packet buffers or Link
Layer connections. The set of such points is implementation-
dependent.
DISCUSSION
Although the Precedence field was originally provided for use in
DOD systems where large traffic surges or major damage to the
network are viewed as inherent threats, it has useful applications
for many non-military IP networks. Although the traffic handling
capacity of networks has grown greatly in recent years, the
traffic generating ability of the users has also grown, and
network overload conditions still occur at times. Since IP-based
routing and management protocols have become more critical to the
successful operation of the Internet, overloads present two
additional risks to the network:
(1) High delays may result in routing protocol packets being lost.
This may cause the routing protocol to falsely deduce a
topology change and propagate this false information to other
routers. Not only can this cause routes to oscillate, but an
extra processing burden may be placed on other routers.
(2) High delays may interfere with the use of network management
tools to analyze and perhaps correct or relieve the problem
in the network that caused the overload condition to occur.
Implementation and appropriate use of the Precedence mechanism
alleviates both of these problems.
Routers SHOULD implement precedence-ordered queue service.
Precedence-ordered queue service means that when a packet is selected
for output on a (logical) link, the packet of highest precedence that
has been queued for that link is sent. Routers that implement
precedence-ordered queue service MUST also have a configuration
option to suppress precedence-ordered queue service in the Internet
Layer.
Any router MAY implement other policy-based throughput management
procedures that result in other than strict precedence ordering, but
it MUST be configurable to suppress them (i.e., use strict ordering).
As detailed in Section [5.3.6], routers that implement precedence-
ordered queue service discard low precedence packets before
discarding high precedence packets for congestion control purposes.
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Preemption (interruption of processing or transmission of a packet)
is not envisioned as a function of the Internet Layer. Some
protocols at other layers may provide preemption features.
Routers that implement precedence-ordered queuing MUST IMPLEMENT, and
other routers SHOULD IMPLEMENT, Lower Layer Precedence Mapping.
A router that implements Lower Layer Precedence Mapping:
o MUST be able to map IP Precedence to Link Layer priority mechanisms
for link layers that have such a feature defined.
o MUST have a configuration option to select the Link Layer's default
priority treatment for all IP traffic
o SHOULD be able to configure specific nonstandard mappings of IP
precedence values to Link Layer priority values for each
interface.
DISCUSSION
Some research questions the workability of the priority features
of some Link Layer protocols, and some networks may have faulty
implementations of the link layer priority mechanism. It seems
prudent to provide an escape mechanism in case such problems show
up in a network.
On the other hand, there are proposals to use novel queuing
strategies to implement special services such as multimedia
bandwidth reservation or low-delay service. Special services and
queuing strategies to support them are current research subjects
and are in the process of standardization.
Implementors may wish to consider that correct link layer mapping
of IP precedence is required by DOD policy for TCP/IP systems used
on DOD networks. Since these requirements are intended to
encourage (but not force) the use of precedence features in the
hope of providing better Internet service to all users, routers
supporting precedence-ordered queue service should default to
maintaining strict precedence ordering regardless of the type of
service requested.
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A router (whether or not it employs precedence-ordered queue
service):
(1) MUST accept and process incoming traffic of all precedence levels
normally, unless it has been administratively configured to do
otherwise.
(2) MAY implement a validation filter to administratively restrict
the use of precedence levels by particular traffic sources. If
provided, this filter MUST NOT filter out or cut off the
following sorts of ICMP error messages: Destination Unreachable,
Redirect, Time Exceeded, and Parameter Problem. If this filter
is provided, the procedures required for packet filtering by
addresses are required for this filter also.
DISCUSSION
Precedence filtering should be applicable to specific
source/destination IP Address pairs, specific protocols, specific
ports, and so on.
An ICMP Destination Unreachable message with code 14 SHOULD be sent
when a packet is dropped by the validation filter, unless this has
been suppressed by configuration choice.
(3) MAY implement a cutoff function that allows the router to be set
to refuse or drop traffic with precedence below a specified
level. This function may be activated by management actions or
by some implementation dependent heuristics, but there MUST be a
configuration option to disable any heuristic mechanism that
operates without human intervention. An ICMP Destination
Unreachable message with code 15 SHOULD be sent when a packet is
dropped by the cutoff function, unless this has been suppressed
by configuration choice.
A router MUST NOT refuse to forward datagrams with IP precedence
of 6 (Internetwork Control) or 7 (Network Control) solely due to
precedence cutoff. However, other criteria may be used in
conjunction with precedence cutoff to filter high precedence
traffic.
DISCUSSION
Unrestricted precedence cutoff could result in an unintentional
cutoff of routing and control traffic. In the general case, host
traffic should be restricted to a value of 5 (CRITIC/ECP) or
below; this is not a requirement and may not be correct in certain
systems.
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(4) MUST NOT change precedence settings on packets it did not
originate.
(5) SHOULD be able to configure distinct precedence values to be used
for each routing or management protocol supported (except for
those protocols, such as OSPF, which specify which precedence
value must be used).
(6) MAY be able to configure routing or management traffic precedence
values independently for each peer address.
(7) MUST respond appropriately to Link Layer precedence-related error
indications where provided. An ICMP Destination Unreachable
message with code 15 SHOULD be sent when a packet is dropped
because a link cannot accept it due to a precedence-related
condition, unless this has been suppressed by configuration
choice.
DISCUSSION
The precedence cutoff mechanism described in (3) is somewhat
controversial. Depending on the topological location of the area
affected by the cutoff, transit traffic may be directed by routing
protocols into the area of the cutoff, where it will be dropped.
This is only a problem if another path that is unaffected by the
cutoff exists between the communicating points. Proposed ways of
avoiding this problem include providing some minimum bandwidth to
all precedence levels even under overload conditions, or
propagating cutoff information in routing protocols. In the
absence of a widely accepted (and implemented) solution to this
problem, great caution is recommended in activating cutoff
mechanisms in transit networks.
A transport layer relay could legitimately provide the function
prohibited by (4) above. Changing precedence levels may cause
subtle interactions with TCP and perhaps other protocols; a
correct design is a non-trivial task.
The intent of (5) and (6) (and the discussion of IP Precedence in
ICMP messages in Section [4.3.2]) is that the IP precedence bits
should be appropriately set, whether or not this router acts upon
those bits in any other way. We expect that in the future
specifications for routing protocols and network management
protocols will specify how the IP Precedence should be set for
messages sent by those protocols.
The appropriate response for (7) depends on the link layer
protocol in use. Typically, the router should stop trying to send
offensive traffic to that destination for some period of time, and
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should return an ICMP Destination Unreachable message with code 15
(service not available for precedence requested) to the traffic
source. It also should not try to reestablish a preempted Link
Layer connection for some time.
The encapsulation of IP packets in most Link Layer protocols (except
PPP) allows a receiver to distinguish broadcasts and multicasts from
unicasts simply by examining the Link Layer protocol headers (most
commonly, the Link Layer destination address). The rules in this
section that refer to Link Layer broadcasts apply only to Link Layer
protocols that allow broadcasts to be distinguished; likewise, the
rules that refer to Link Layer multicasts apply only to Link Layer
protocols that allow multicasts to be distinguished.
A router MUST NOT forward any packet that the router received as a
Link Layer broadcast, unless it is directed to an IP Multicast
address. In this latter case, one would presume that link layer
broadcast was used due to the lack of an effective multicast service.
A router MUST NOT forward any packet which the router received as a
Link Layer multicast unless the packet's destination address is an IP
multicast address.
A router SHOULD silently discard a packet that is received via a Link
Layer broadcast but does not specify an IP multicast or IP broadcast
destination address.
When a router sends a packet as a Link Layer broadcast, the IP
destination address MUST be a legal IP broadcast or IP multicast
address.
There are two major types of IP broadcast addresses; limited
broadcast and directed broadcast. In addition, there are three
subtypes of directed broadcast: a broadcast directed to a specified
network prefix, a broadcast directed to a specified subnetwork, and a
broadcast directed to all subnets of a specified network.
Classification by a router of a broadcast into one of these
categories depends on the broadcast address and on the router's
understanding (if any) of the subnet structure of the destination
network. The same broadcast will be classified differently by
different routers.
A limited IP broadcast address is defined to be all-ones: { -1, -1 }
or 255.255.255.255.
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A network-prefix-directed broadcast is composed of the network prefix
of the IP address with a local part of all-ones or { <Network-
prefix>, -1 }. For example, a Class A net broadcast address is
net.255.255.255, a Class B net broadcast address is net.net.255.255
and a Class C net broadcast address is net.net.net.255 where net is a
byte of the network address.
The all-subnets-directed-broadcast is not well defined in a CIDR
environment, and was deprecated in version 1 of this memo.
As was described in Section [4.2.3.1], a router may encounter certain
non-standard IP broadcast addresses:
o 0.0.0.0 is an obsolete form of the limited broadcast address
o { <Network-prefix>, 0 } is an obsolete form of a network-prefix-
directed broadcast address.
As was described in that section, packets addressed to any of these
addresses SHOULD be silently discarded, but if they are not, they
MUST be treated according to the same rules that apply to packets
addressed to the non-obsolete forms of the broadcast addresses
described above. These rules are described in the next few sections.
Limited broadcasts MUST NOT be forwarded. Limited broadcasts MUST
NOT be discarded. Limited broadcasts MAY be sent and SHOULD be sent
instead of directed broadcasts where limited broadcasts will suffice.
DISCUSSION
Some routers contain UDP servers which function by resending the
requests (as unicasts or directed broadcasts) to other servers.
This requirement should not be interpreted as prohibiting such
servers. Note, however, that such servers can easily cause packet
looping if misconfigured. Thus, providers of such servers would
probably be well advised to document their setup carefully and to
consider carefully the TTL on packets that are sent.
A router MUST classify as network-prefix-directed broadcasts all
valid, directed broadcasts destined for a remote network or an
attached nonsubnetted network. Note that in view of CIDR, such
appear to be host addresses within the network prefix; we preclude
inspection of the host part of such network prefixes. Given a route
and no overriding policy, then, a router MUST forward network-
prefix-directed broadcasts. Network-Prefix-Directed broadcasts MAY
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be sent.
A router MAY have an option to disable receiving network-prefix-
directed broadcasts on an interface and MUST have an option to
disable forwarding network-prefix-directed broadcasts. These options
MUST default to permit receiving and forwarding network-prefix-
directed broadcasts.
DISCUSSION
There has been some debate about forwarding or not forwarding
directed broadcasts. In this memo we have made the forwarding
decision depend on the router's knowledge of the destination
network prefix. Routers cannot determine that a message is
unicast or directed broadcast apart from this knowledge. The
decision to forward or not forward the message is by definition
only possible in the last hop router.
The first version of this memo described an algorithm for
distributing a directed broadcast to all the subnets of a classical
network number. This algorithm was stated to be "broken," and
certain failure cases were specified.
In a CIDR routing domain, wherein classical IP network numbers are
meaningless, the concept of an all-subnets-directed-broadcast is also
meaningless. To the knowledge of the working group, the facility was
never implemented or deployed, and is now relegated to the dustbin of
history.
The first version of this memo spelled out procedures for dealing
with subnet-directed-broadcasts. In a CIDR routing domain, these are
indistinguishable from net-drected-broadcasts. The two are therefore
treated together in section [5.3.5.2 Directed Broadcasts], and should
be viewed as network-prefix directed broadcasts.
Congestion in a network is loosely defined as a condition where
demand for resources (usually bandwidth or CPU time) exceeds
capacity. Congestion avoidance tries to prevent demand from
exceeding capacity, while congestion recovery tries to restore an
operative state. It is possible for a router to contribute to both
of these mechanisms. A great deal of effort has been spent studying
the problem. The reader is encouraged to read [FORWARD:2] for a
survey of the work. Important papers on the subject include
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[FORWARD:3], [FORWARD:4], [FORWARD:5], [FORWARD:10], [FORWARD:11],
[FORWARD:12], [FORWARD:13], [FORWARD:14], and [INTERNET:10], among
others.
The amount of storage that router should have available to handle
peak instantaneous demand when hosts use reasonable congestion
policies, such as described in [FORWARD:5], is a function of the
product of the bandwidth of the link times the path delay of the
flows using the link, and therefore storage should increase as this
Bandwidth*Delay product increases. The exact function relating
storage capacity to probability of discard is not known.
When a router receives a packet beyond its storage capacity it must
(by definition, not by decree) discard it or some other packet or
packets. Which packet to discard is the subject of much study but,
unfortunately, little agreement so far. The best wisdom to date
suggests discarding a packet from the data stream most heavily using
the link. However, a number of additional factors may be relevant,
including the precedence of the traffic, active bandwidth
reservation, and the complexity associated with selecting that
packet.
A router MAY discard the packet it has just received; this is the
simplest but not the best policy. Ideally, the router should select
a packet from one of the sessions most heavily abusing the link,
given that the applicable Quality of Service policy permits this. A
recommended policy in datagram environments using FIFO queues is to
discard a packet randomly selected from the queue (see [FORWARD:5]).
An equivalent algorithm in routers using fair queues is to discard
from the longest queue or that using the greatest virtual time (see
[FORWARD:13]). A router MAY use these algorithms to determine which
packet to discard.
If a router implements a discard policy (such as Random Drop) under
which it chooses a packet to discard from a pool of eligible packets:
o If precedence-ordered queue service (described in Section
[5.3.3.1]) is implemented and enabled, the router MUST NOT discard
a packet whose IP precedence is higher than that of a packet that
is not discarded.
o A router MAY protect packets whose IP headers request the maximize
reliability TOS, except where doing so would be in violation of
the previous rule.
o A router MAY protect fragmented IP packets, on the theory that
dropping a fragment of a datagram may increase congestion by
causing all fragments of the datagram to be retransmitted by the
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source.
o To help prevent routing perturbations or disruption of management
functions, the router MAY protect packets used for routing
control, link control, or network management from being discarded.
Dedicated routers (i.e., routers that are not also general purpose
hosts, terminal servers, etc.) can achieve an approximation of
this rule by protecting packets whose source or destination is the
router itself.
Advanced methods of congestion control include a notion of fairness,
so that the 'user' that is penalized by losing a packet is the one
that contributed the most to the congestion. No matter what
mechanism is implemented to deal with bandwidth congestion control,
it is important that the CPU effort expended be sufficiently small
that the router is not driven into CPU congestion also.
As described in Section [4.3.3.3], this document recommends that a
router SHOULD NOT send a Source Quench to the sender of the packet
that it is discarding. ICMP Source Quench is a very weak mechanism,
so it is not necessary for a router to send it, and host software
should not use it exclusively as an indicator of congestion.
An IP source address is invalid if it is a special IP address, as
defined in 4.2.2.11 or 5.3.7, or is not a unicast address.
An IP destination address is invalid if it is among those defined as
illegal destinations in 4.2.3.1, or is a Class E address (except
255.255.255.255).
A router SHOULD NOT forward any packet that has an invalid IP source
address or a source address on network 0. A router SHOULD NOT
forward, except over a loopback interface, any packet that has a
source address on network 127. A router MAY have a switch that
allows the network manager to disable these checks. If such a switch
is provided, it MUST default to performing the checks.
A router SHOULD NOT forward any packet that has an invalid IP
destination address or a destination address on network 0. A router
SHOULD NOT forward, except over a loopback interface, any packet that
has a destination address on network 127. A router MAY have a switch
that allows the network manager to disable these checks. If such a
switch is provided, it MUST default to performing the checks.
If a router discards a packet because of these rules, it SHOULD log
at least the IP source address, the IP destination address, and, if
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the problem was with the source address, the physical interface on
which the packet was received and the Link Layer address of the host
or router from which the packet was received.
A router SHOULD IMPLEMENT the ability to filter traffic based on a
comparison of the source address of a packet and the forwarding table
for a logical interface on which the packet was received. If this
filtering is enabled, the router MUST silently discard a packet if
the interface on which the packet was received is not the interface
on which a packet would be forwarded to reach the address contained
in the source address. In simpler terms, if a router wouldn't route
a packet containing this address through a particular interface, it
shouldn't believe the address if it appears as a source address in a
packet read from this interface.
If this feature is implemented, it MUST be disabled by default.
DISCUSSION
This feature can provide useful security improvements in some
situations, but can erroneously discard valid packets in
situations where paths are asymmetric.
As a means of providing security and/or limiting traffic through
portions of a network a router SHOULD provide the ability to
selectively forward (or filter) packets. If this capability is
provided, filtering of packets SHOULD be configurable either to
forward all packets or to selectively forward them based upon the
source and destination prefixes, and MAY filter on other message
attributes. Each source and destination address SHOULD allow
specification of an arbitrary prefix length.
DISCUSSION
This feature can provide a measure of privacy, where systems
outside a boundary are not permitted to exchange certain protocols
with systems inside the boundary, or are limited as to which
systems they may communicate with. It can also help prevent
certain classes of security breach, wherein a system outside a
boundary masquerades as a system inside the boundary and mimics a
session with it.
If supported, a router SHOULD be configurable to allow one of an
o Include list - specification of a list of message definitions to be
forwarded, or an
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o Exclude list - specification of a list of message definitions NOT
to be forwarded.
A "message definition", in this context, specifies the source and
destination network prefix, and may include other identifying
information such as IP Protocol Type or TCP port number.
A router MAY provide a configuration switch that allows a choice
between specifying an include or an exclude list, or other equivalent
controls.
A value matching any address (e.g., a keyword any, an address with a
mask of all 0's, or a network prefix whose length is zero) MUST be
allowed as a source and/or destination address.
In addition to address pairs, the router MAY allow any combination of
transport and/or application protocol and source and destination
ports to be specified.
The router MUST allow packets to be silently discarded (i.e.,
discarded without an ICMP error message being sent).
The router SHOULD allow an appropriate ICMP unreachable message to be
sent when a packet is discarded. The ICMP message SHOULD specify
Communication Administratively Prohibited (code 13) as the reason for
the destination being unreachable.
The router SHOULD allow the sending of ICMP destination unreachable
messages (code 13) to be configured for each combination of address
pairs, protocol types, and ports it allows to be specified.
The router SHOULD count and SHOULD allow selective logging of packets
not forwarded.
An IP router SHOULD support forwarding of IP multicast packets, based
either on static multicast routes or on routes dynamically determined
by a multicast routing protocol (e.g., DVMRP [ROUTE:9]). A router
that forwards IP multicast packets is called a multicast router.
For each physical interface, a router SHOULD have a configuration
option that specifies whether forwarding is enabled on that
interface. When forwarding on an interface is disabled, the router:
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o MUST silently discard any packets which are received on that
interface but are not addressed to the router
o MUST NOT send packets out that interface, except for datagrams
originated by the router
o MUST NOT announce via any routing protocols the availability of
paths through the interface
DISCUSSION
This feature allows the network manager to essentially turn off an
interface but leaves it accessible for network management.
Ideally, this control would apply to logical rather than physical
interfaces. It cannot, because there is no known way for a router
to determine which logical interface a packet arrived absent a
one-to-one correspondence between logical and physical interfaces.
During router operation, interfaces may fail or be manually disabled,
or may become available for use by the router. Similarly, forwarding
may be disabled for a particular interface or for the entire router
or may be (re)enabled. While such transitions are (usually)
uncommon, it is important that routers handle them correctly.
When a router ceases forwarding it MUST stop advertising all routes,
except for third party routes. It MAY continue to receive and use
routes from other routers in its routing domains. If the forwarding
database is retained, the router MUST NOT cease timing the routes in
the forwarding database. If routes that have been received from
other routers are remembered, the router MUST NOT cease timing the
routes that it has remembered. It MUST discard any routes whose
timers expire while forwarding is disabled, just as it would do if
forwarding were enabled.
DISCUSSION
When a router ceases forwarding, it essentially ceases being a
router. It is still a host, and must follow all of the
requirements of Host Requirements [INTRO:2]. The router may still
be a passive member of one or more routing domains, however. As
such, it is allowed to maintain its forwarding database by
listening to other routers in its routing domain. It may not,
however, advertise any of the routes in its forwarding database,
since it itself is doing no forwarding. The only exception to
this rule is when the router is advertising a route that uses only
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some other router, but which this router has been asked to
advertise.
A router MAY send ICMP destination unreachable (host unreachable)
messages to the senders of packets that it is unable to forward. It
SHOULD NOT send ICMP redirect messages.
DISCUSSION
Note that sending an ICMP destination unreachable (host
unreachable) is a router action. This message should not be sent
by hosts. This exception to the rules for hosts is allowed so
that packets may be rerouted in the shortest possible time, and so
that black holes are avoided.
When a router begins forwarding, it SHOULD expedite the sending of
new routing information to all routers with which it normally
exchanges routing information.
If an interface fails or is disabled a router MUST remove and stop
advertising all routes in its forwarding database that make use of
that interface. It MUST disable all static routes that make use of
that interface. If other routes to the same destination and TOS are
learned or remembered by the router, the router MUST choose the best
alternate, and add it to its forwarding database. The router SHOULD
send ICMP destination unreachable or ICMP redirect messages, as
appropriate, in reply to all packets that it is unable to forward due
to the interface being unavailable.
If an interface that had not been available becomes available, a
router MUST reenable any static routes that use that interface. If
routes that would use that interface are learned by the router, then
these routes MUST be evaluated along with all the other learned
routes, and the router MUST make a decision as to which routes should
be placed in the forwarding database. The implementor is referred to
Chapter [7], Application Layer - Routing Protocols for further
information on how this decision is made.
A router SHOULD expedite the sending of new routing information to
all routers with which it normally exchanges routing information.
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Several options, such as Record Route and Timestamp, contain slots
into which a router inserts its address when forwarding the packet.
However, each such option has a finite number of slots, and therefore
a router may find that there is not free slot into which it can
insert its address. No requirement listed below should be construed
as requiring a router to insert its address into an option that has
no remaining slot to insert it into. Section [5.2.5] discusses how a
router must choose which of its addresses to insert into an option.
Some environments require the Security option in every packet; such a
requirement is outside the scope of this document and the IP standard
specification. Note, however, that the security options described in
[INTERNET:1] and [INTERNET:16] are obsolete. Routers SHOULD
IMPLEMENT the revised security option described in [INTERNET:5].
DISCUSSION
Routers intended for use in networks with multiple security levels
should support packet filtering based on IPSO (RFC-1108) labels.
To implement this support, the router would need to permit the
router administrator to configure both a lower sensitivity limit
(e.g. Unclassified) and an upper sensitivity limit (e.g. Secret)
on each interface. It is commonly but not always the case that
the two limits are the same (e.g. a single-level interface).
Packets caught by an IPSO filter as being out of range should be
silently dropped and a counter should note the number of packets
dropped because of out of range IPSO labels.
This option is obsolete. If the Stream Identifier option is present
in a packet forwarded by the router, the option MUST be ignored and
passed through unchanged.
A router MUST implement support for source route options in forwarded
packets. A router MAY implement a configuration option that, when
enabled, causes all source-routed packets to be discarded. However,
such an option MUST NOT be enabled by default.
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DISCUSSION
The ability to source route datagrams through the Internet is
important to various network diagnostic tools. However, source
routing may be used to bypass administrative and security controls
within a network. Specifically, those cases where manipulation of
routing tables is used to provide administrative separation in
lieu of other methods such as packet filtering may be vulnerable
through source routed packets.
EDITORS+COMMENTS
Packet filtering can be defeated by source routing as well, if it
is applied in any router except one on the final leg of the source
routed path. Neither route nor packet filters constitute a
complete solution for security.
Routers MUST support the Record Route option in forwarded packets.
A router MAY provide a configuration option that, if enabled, will
cause the router to ignore (i.e., pass through unchanged) Record
Route options in forwarded packets. If provided, such an option MUST
default to enabling the record-route. This option should not affect
the processing of Record Route options in datagrams received by the
router itself (in particular, Record Route options in ICMP echo
requests will still be processed according to Section [4.3.3.6]).
DISCUSSION
There are some people who believe that Record Route is a security
problem because it discloses information about the topology of the
network. Thus, this document allows it to be disabled.
Routers MUST support the timestamp option in forwarded packets. A
timestamp value MUST follow the rules given [INTRO:2].
If the flags field = 3 (timestamp and prespecified address), the
router MUST add its timestamp if the next prespecified address
matches any of the router's IP addresses. It is not necessary that
the prespecified address be either the address of the interface on
which the packet arrived or the address of the interface over which
it will be sent.
IMPLEMENTATION
To maximize the utility of the timestamps contained in the
timestamp option, it is suggested that the timestamp inserted be,
as nearly as practical, the time at which the packet arrived at
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the router. For datagrams originated by the router, the timestamp
inserted should be, as nearly as practical, the time at which the
datagram was passed to the network layer for transmission.
A router MAY provide a configuration option which, if enabled, will
cause the router to ignore (i.e., pass through unchanged) Timestamp
options in forwarded datagrams when the flag word is set to zero
(timestamps only) or one (timestamp and registering IP address). If
provided, such an option MUST default to off (that is, the router
does not ignore the timestamp). This option should not affect the
processing of Timestamp options in datagrams received by the router
itself (in particular, a router will insert timestamps into Timestamp
options in datagrams received by the router, and Timestamp options in
ICMP echo requests will still be processed according to Section
[4.3.3.6]).
DISCUSSION
Like the Record Route option, the Timestamp option can reveal
information about a network's topology. Some people consider this
to be a security concern.
A router is not required to implement any Transport Layer protocols
except those required to support Application Layer protocols
supported by the router. In practice, this means that most routers
implement both the Transmission Control Protocol (TCP) and the User
Datagram Protocol (UDP).
The User Datagram Protocol (UDP) is specified in [TRANS:1].
A router that implements UDP MUST be compliant, and SHOULD be
unconditionally compliant, with the requirements of [INTRO:2], except
that:
o This specification does not specify the interfaces between the
various protocol layers. Thus, a router's interfaces need not
comply with [INTRO:2], except where compliance is required for
proper functioning of Application Layer protocols supported by the
router.
o Contrary to [INTRO:2], an application SHOULD NOT disable generation
of UDP checksums.
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DISCUSSION
Although a particular application protocol may require that UDP
datagrams it receives must contain a UDP checksum, there is no
general requirement that received UDP datagrams contain UDP
checksums. Of course, if a UDP checksum is present in a received
datagram, the checksum must be verified and the datagram discarded
if the checksum is incorrect.
The Transmission Control Protocol (TCP) is specified in [TRANS:2].
A router that implements TCP MUST be compliant, and SHOULD be
unconditionally compliant, with the requirements of [INTRO:2], except
that:
o This specification does not specify the interfaces between the
various protocol layers. Thus, a router need not comply with the
following requirements of [INTRO:2] (except of course where
compliance is required for proper functioning of Application Layer
protocols supported by the router):
Use of Push: RFC-793 Section 2.8:
Passing a received PSH flag to the application layer is now
OPTIONAL.
Urgent Pointer: RFC-793 Section 3.1:
A TCP MUST inform the application layer asynchronously
whenever it receives an Urgent pointer and there was
previously no pending urgent data, or whenever the Urgent
pointer advances in the data stream. There MUST be a way for
the application to learn how much urgent data remains to be
read from the connection, or at least to determine whether or
not more urgent data remains to be read.
TCP Connection Failures:
An application MUST be able to set the value for R2 for a
particular connection. For example, an interactive
application might set R2 to ``infinity,'' giving the user
control over when to disconnect.
TCP Multihoming:
If an application on a multihomed host does not specify the
local IP address when actively opening a TCP connection, then
the TCP MUST ask the IP layer to select a local IP address
before sending the (first) SYN. See the function
GET_SRCADDR() in Section 3.4.
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IP Options:
An application MUST be able to specify a source route when it
actively opens a TCP connection, and this MUST take
precedence over a source route received in a datagram.
o For similar reasons, a router need not comply with any of the
requirements of [INTRO:2].
o The requirements concerning the Maximum Segment Size Option in
[INTRO:2] are amended as follows: a router that implements the
host portion of MTU discovery (discussed in Section [4.2.3.3] of
this memo) uses 536 as the default value of SendMSS only if the
path MTU is unknown; if the path MTU is known, the default value
for SendMSS is the path MTU - 40.
o The requirements concerning the Maximum Segment Size Option in
[INTRO:2] are amended as follows: ICMP Destination Unreachable
codes 11 and 12 are additional soft error conditions. Therefore,
these message MUST NOT cause TCP to abort a connection.
DISCUSSION
It should particularly be noted that a TCP implementation in a
router must conform to the following requirements of [INTRO:2]:
o Providing a configurable TTL. [Time to Live: RFC-793 Section
3.9]
o Providing an interface to configure keep-alive behavior, if
keep-alives are used at all. [TCP Keep-Alives]
o Providing an error reporting mechanism, and the ability to
manage it. [Asynchronous Reports]
o Specifying type of service. [Type-of-Service]
The general paradigm applied is that if a particular interface is
visible outside the router, then all requirements for the
interface must be followed. For example, if a router provides a
telnet function, then it will be generating traffic, likely to be
routed in the external networks. Therefore, it must be able to
set the type of service correctly or else the telnet traffic may
not get through.
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For technical, managerial, and sometimes political reasons, the
Internet routing system consists of two components - interior routing
and exterior routing. The concept of an Autonomous System (AS), as
define in Section 2.2.4 of this document, plays a key role in
separating interior from an exterior routing, as this concept allows
to deliniate the set of routers where a change from interior to
exterior routing occurs. An IP datagram may have to traverse the
routers of two or more Autonomous Systems to reach its destination,
and the Autonomous Systems must provide each other with topology
information to allow such forwarding. Interior gateway protocols
(IGPs) are used to distribute routing information within an AS (i.e.,
intra-AS routing). Exterior gateway protocols are used to exchange
routing information among ASs (i.e., inter-AS routing).
Routing is one of the few places where the Robustness Principle (be
liberal in what you accept) does not apply. Routers should be
relatively suspicious in accepting routing data from other routing
systems.
A router SHOULD provide the ability to rank routing information
sources from most trustworthy to least trustworthy and to accept
routing information about any particular destination from the most
trustworthy sources first. This was implicit in the original
core/stub autonomous system routing model using EGP and various
interior routing protocols. It is even more important with the
demise of a central, trusted core.
A router SHOULD provide a mechanism to filter out obviously invalid
routes (such as those for net 127).
Routers MUST NOT by default redistribute routing data they do not
themselves use, trust or otherwise consider valid. In rare cases, it
may be necessary to redistribute suspicious information, but this
should only happen under direct intercession by some human agency.
Routers must be at least a little paranoid about accepting routing
data from anyone, and must be especially careful when they distribute
routing information provided to them by another party. See below for
specific guidelines.
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Except where the specification for a particular routing protocol
specifies otherwise, a router SHOULD set the IP Precedence value for
IP datagrams carrying routing traffic it originates to 6
(INTERNETWORK CONTROL).
DISCUSSION
Routing traffic with VERY FEW exceptions should be the highest
precedence traffic on any network. If a system's routing traffic
can't get through, chances are nothing else will.
Peer-to-peer authentication involves several tests. The application
of message passwords and explicit acceptable neighbor lists has in
the past improved the robustness of the route database. Routers
SHOULD IMPLEMENT management controls that enable explicit listing of
valid routing neighbors. Routers SHOULD IMPLEMENT peer-to-peer
authentication for those routing protocols that support them.
Routers SHOULD validate routing neighbors based on their source
address and the interface a message is received on; neighbors in a
directly attached subnet SHOULD be restricted to communicate with the
router via the interface that subnet is posited on or via unnumbered
interfaces. Messages received on other interfaces SHOULD be silently
discarded.
DISCUSSION
Security breaches and numerous routing problems are avoided by
this basic testing.
An Interior Gateway Protocol (IGP) is used to distribute routing
information between the various routers in a particular AS.
Independent of the algorithm used to implement a particular IGP, it
should perform the following functions:
(1) Respond quickly to changes in the internal topology of an AS
(2) Provide a mechanism such that circuit flapping does not cause
continuous routing updates
(3) Provide quick convergence to loop-free routing
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(4) Utilize minimal bandwidth
(5) Provide equal cost routes to enable load-splitting
(6) Provide a means for authentication of routing updates
Current IGPs used in the internet today are characterized as either
being based on a distance-vector or a link-state algorithm.
Several IGPs are detailed in this section, including those most
commonly used and some recently developed protocols that may be
widely used in the future. Numerous other protocols intended for use
in intra-AS routing exist in the Internet community.
A router that implements any routing protocol (other than static
routes) MUST IMPLEMENT OSPF (see Section [7.2.2]). A router MAY
implement additional IGPs.
Shortest Path First (SPF) based routing protocols are a class of
link-state algorithms that are based on the shortest-path algorithm
of Dijkstra. Although SPF based algorithms have been around since
the inception of the ARPANET, it is only recently that they have
achieved popularity both inside both the IP and the OSI communities.
In an SPF based system, each router obtains the entire topology
database through a process known as flooding. Flooding insures a
reliable transfer of the information. Each router then runs the SPF
algorithm on its database to build the IP routing table. The OSPF
routing protocol is an implementation of an SPF algorithm. The
current version, OSPF version 2, is specified in [ROUTE:1]. Note
that RFC-1131, which describes OSPF version 1, is obsolete.
Note that to comply with Section [8.3] of this memo, a router that
implements OSPF MUST implement the OSPF MIB [MGT:14].
The American National Standards Institute (ANSI) X3S3.3 committee has
defined an intra-domain routing protocol. This protocol is titled
Intermediate System to Intermediate System Routeing Exchange
Protocol.
Its application to an IP network has been defined in [ROUTE:2], and
is referred to as Dual IS-IS (or sometimes as Integrated IS-IS).
IS-IS is based on a link-state (SPF) routing algorithm and shares all
the advantages for this class of protocols.
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Exterior Gateway Protocols are utilized for inter-Autonomous System
routing to exchange reachability information for a set of networks
internal to a particular autonomous system to a neighboring
autonomous system.
The area of inter-AS routing is a current topic of research inside
the Internet Engineering Task Force. The Exterior Gateway Protocol
(EGP) described in Section [Appendix F.1] has traditionally been the
inter-AS protocol of choice, but is now historical. The Border
Gateway Protocol (BGP) eliminates many of the restrictions and
limitations of EGP, and is therefore growing rapidly in popularity.
A router is not required to implement any inter-AS routing protocol.
However, if a router does implement EGP it also MUST IMPLEMENT BGP.
Although it was not designed as an exterior gateway protocol, RIP
(described in Section [7.2.4]) is sometimes used for inter-AS
routing.
The Border Gateway Protocol (BGP-4) is an inter-AS routing protocol
that exchanges network reachability information with other BGP
speakers. The information for a network includes the complete list
of ASs that traffic must transit to reach that network. This
information can then be used to insure loop-free paths. This
information is sufficient to construct a graph of AS connectivity
from which routing loops may be pruned and some policy decisions at
the AS level may be enforced.
BGP is defined by [ROUTE:4]. [ROUTE:5] specifies the proper usage of
BGP in the Internet, and provides some useful implementation hints
and guidelines. [ROUTE:12] and [ROUTE:13] provide additional useful
information.
To comply with Section [8.3] of this memo, a router that implements
BGP is required to implement the BGP MIB [MGT:15].
To characterize the set of policy decisions that can be enforced
using BGP, one must focus on the rule that an AS advertises to its
neighbor ASs only those routes that it itself uses. This rule
reflects the hop-by-hop routing paradigm generally used throughout
the current Internet. Note that some policies cannot be supported by
the hop-by-hop routing paradigm and thus require techniques such as
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source routing to enforce. For example, BGP does not enable one AS
to send traffic to a neighbor AS intending that traffic take a
different route from that taken by traffic originating in the
neighbor AS. On the other hand, BGP can support any policy
conforming to the hop-by-hop routing paradigm.
Implementors of BGP are strongly encouraged to follow the
recommendations outlined in Section 6 of [ROUTE:5].
While BGP provides support for quite complex routing policies (as an
example see Section 4.2 in [ROUTE:5]), it is not required for all BGP
implementors to support such policies. At a minimum, however, a BGP
implementation:
(1) SHOULD allow an AS to control announcements of the BGP learned
routes to adjacent AS's. Implementations SHOULD support such
control with at least the granularity of a single network.
Implementations SHOULD also support such control with the
granularity of an autonomous system, where the autonomous system
may be either the autonomous system that originated the route,
or the autonomous system that advertised the route to the local
system (adjacent autonomous system).
(2) SHOULD allow an AS to prefer a particular path to a destination
(when more than one path is available). Such function SHOULD be
implemented by allowing system administrator to assign weights
to Autonomous Systems, and making route selection process to
select a route with the lowest weight (where weight of a route
is defined as a sum of weights of all AS's in the AS_PATH path
attribute associated with that route).
(3) SHOULD allow an AS to ignore routes with certain AS's in the
AS_PATH path attribute. Such function can be implemented by
using technique outlined in (2), and by assigning infinity as
weights for such AS's. The route selection process must ignore
routes that have weight equal to infinity.
It is possible to exchange routing information between two autonomous
systems or routing domains without using a standard exterior routing
protocol between two separate, standard interior routing protocols.
The most common way of doing this is to run both interior protocols
independently in one of the border routers with an exchange of route
information between the two processes.
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As with the exchange of information from an EGP to an IGP, without
appropriate controls these exchanges of routing information between
two IGPs in a single router are subject to creation of routing loops.
Static routing provides a means of explicitly defining the next hop
from a router for a particular destination. A router SHOULD provide
a means for defining a static route to a destination, where the
destination is defined by a network prefix. The mechanism SHOULD
also allow for a metric to be specified for each static route.
A router that supports a dynamic routing protocol MUST allow static
routes to be defined with any metric valid for the routing protocol
used. The router MUST provide the ability for the user to specify a
list of static routes that may or may not be propagated through the
routing protocol. In addition, a router SHOULD support the following
additional information if it supports a routing protocol that could
make use of the information. They are:
o TOS,
o Subnet Mask, or
o Prefix Length, or
o A metric specific to a given routing protocol that can import the
route.
DISCUSSION
We intend that one needs to support only the things useful to the
given routing protocol. The need for TOS should not require the
vendor to implement the other parts if they are not used.
Whether a router prefers a static route over a dynamic route (or
vice versa) or whether the associated metrics are used to choose
between conflicting static and dynamic routes SHOULD be
configurable for each static route.
A router MUST allow a metric to be assigned to a static route for
each routing domain that it supports. Each such metric MUST be
explicitly assigned to a specific routing domain. For example:
route 10.0.0.0/8 via 192.0.2.3 rip metric 3
route 10.21.0.0/16 via 192.0.2.4 ospf inter-area metric 27
route 10.22.0.0/16 via 192.0.2.5 egp 123 metric 99
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DISCUSSION
It has been suggested that, ideally, static routes should have
preference values rather than metrics (since metrics can only be
compared with metrics of other routes in the same routing domain,
the metric of a static route could only be compared with metrics
of other static routes). This is contrary to some current
implementations, where static routes really do have metrics, and
those metrics are used to determine whether a particular dynamic
route overrides the static route to the same destination. Thus,
this document uses the term metric rather than preference.
This technique essentially makes the static route into a RIP
route, or an OSPF route (or whatever, depending on the domain of
the metric). Thus, the route lookup algorithm of that domain
applies. However, this is NOT route leaking, in that coercing a
static route into a dynamic routing domain does not authorize the
router to redistribute the route into the dynamic routing domain.
For static routes not put into a specific routing domain, the
route lookup algorithm is:
(1) Basic match
(2) Longest match
(3) Weak TOS (if TOS supported)
(4) Best metric (where metric are implementation-defined)
The last step may not be necessary, but it's useful in the case
where you want to have a primary static route over one interface
and a secondary static route over an alternate interface, with
failover to the alternate path if the interface for the primary
route fails.
Each router within a network makes forwarding decisions based upon
information contained within its forwarding database. In a simple
network the contents of the database may be configured statically.
As the network grows more complex, the need for dynamic updating of
the forwarding database becomes critical to the efficient operation
of the network.
If the data flow through a network is to be as efficient as possible,
it is necessary to provide a mechanism for controlling the
propagation of the information a router uses to build its forwarding
database. This control takes the form of choosing which sources of
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routing information should be trusted and selecting which pieces of
the information to believe. The resulting forwarding database is a
filtered version of the available routing information.
In addition to efficiency, controlling the propagation of routing
information can reduce instability by preventing the spread of
incorrect or bad routing information.
In some cases local policy may require that complete routing
information not be widely propagated.
These filtering requirements apply only to non-SPF-based protocols
(and therefore not at all to routers which don't implement any
distance vector protocols).
A router SHOULD log as an error any routing update advertising a
route that violates the specifications of this memo, unless the
routing protocol from which the update was received uses those values
to encode special routes (such as default routes).
Filtering of routing information allows control of paths used by a
router to forward packets it receives. A router should be selective
in which sources of routing information it listens to and what routes
it believes. Therefore, a router MUST provide the ability to
specify:
o On which logical interfaces routing information will be accepted
and which routes will be accepted from each logical interface.
o Whether all routes or only a default route is advertised on a
logical interface.
Some routing protocols do not recognize logical interfaces as a
source of routing information. In such cases the router MUST provide
the ability to specify
o from which other routers routing information will be accepted.
For example, assume a router connecting one or more leaf networks to
the main portion or backbone of a larger network. Since each of the
leaf networks has only one path in and out, the router can simply
send a default route to them. It advertises the leaf networks to the
main network.
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As the topology of a network grows more complex, the need for more
complex route filtering arises. Therefore, a router SHOULD provide
the ability to specify independently for each routing protocol:
o Which logical interfaces or routers routing information (routes)
will be accepted from and which routes will be believed from each
other router or logical interface,
o Which routes will be sent via which logical interface(s), and
o Which routers routing information will be sent to, if this is
supported by the routing protocol in use.
In many situations it is desirable to assign a reliability ordering
to routing information received from another router instead of the
simple believe or don't believe choice listed in the first bullet
above. A router MAY provide the ability to specify:
o A reliability or preference to be assigned to each route received.
A route with higher reliability will be chosen over one with lower
reliability regardless of the routing metric associated with each
route.
If a router supports assignment of preferences, the router MUST NOT
propagate any routes it does not prefer as first party information.
If the routing protocol being used to propagate the routes does not
support distinguishing between first and third party information, the
router MUST NOT propagate any routes it does not prefer.
DISCUSSION
For example, assume a router receives a route to network C from
router R and a route to the same network from router S. If router
R is considered more reliable than router S traffic destined for
network C will be forwarded to router R regardless of the route
received from router S.
Routing information for routes which the router does not use (router
S in the above example) MUST NOT be passed to any other router.
Routers MUST be able to exchange routing information between separate
IP interior routing protocols, if independent IP routing processes
can run in the same router. Routers MUST provide some mechanism for
avoiding routing loops when routers are configured for bi-directional
exchange of routing information between two separate interior routing
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processes. Routers MUST provide some priority mechanism for choosing
routes from independent routing processes. Routers SHOULD provide
administrative control of IGP-IGP exchange when used across
administrative boundaries.
Routers SHOULD provide some mechanism for translating or transforming
metrics on a per network basis. Routers (or routing protocols) MAY
allow for global preference of exterior routes imported into an IGP.
DISCUSSION
Different IGPs use different metrics, requiring some translation
technique when introducing information from one protocol into
another protocol with a different form of metric. Some IGPs can
run multiple instances within the same router or set of routers.
In this case metric information can be preserved exactly or
translated.
There are at least two techniques for translation between
different routing processes. The static (or reachability)
approach uses the existence of a route advertisement in one IGP to
generate a route advertisement in the other IGP with a given
metric. The translation or tabular approach uses the metric in
one IGP to create a metric in the other IGP through use of either
a function (such as adding a constant) or a table lookup.
Bi-directional exchange of routing information is dangerous
without control mechanisms to limit feedback. This is the same
problem that distance vector routing protocols must address with
the split horizon technique and that EGP addresses with the
third-party rule. Routing loops can be avoided explicitly through
use of tables or lists of permitted/denied routes or implicitly
through use of a split horizon rule, a no-third-party rule, or a
route tagging mechanism. Vendors are encouraged to use implicit
techniques where possible to make administration easier for
network operators.
Routers MUST be manageable by SNMP [MGT:3]. The SNMP MUST operate
using UDP/IP as its transport and network protocols. Others MAY be
supported (e.g., see [MGT:25, MGT:26, MGT:27, and MGT:28]). SNMP
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management operations MUST operate as if the SNMP was implemented on
the router itself. Specifically, management operations MUST be
effected by sending SNMP management requests to any of the IP
addresses assigned to any of the router's interfaces. The actual
management operation may be performed either by the router or by a
proxy for the router.
DISCUSSION
This wording is intended to allow management either by proxy,
where the proxy device responds to SNMP packets that have one of
the router's IP addresses in the packets destination address
field, or the SNMP is implemented directly in the router itself
and receives packets and responds to them in the proper manner.
It is important that management operations can be sent to one of
the router's IP Addresses. In diagnosing network problems the
only thing identifying the router that is available may be one of
the router's IP address; obtained perhaps by looking through
another router's routing table.
All SNMP operations (get, get-next, get-response, set, and trap) MUST
be implemented.
Routers MUST provide a mechanism for rate-limiting the generation of
SNMP trap messages. Routers MAY provide this mechanism through the
algorithms for asynchronous alert management described in [MGT:5].
DISCUSSION
Although there is general agreement about the need to rate-limit
traps, there is not yet consensus on how this is best achieved.
The reference cited is considered experimental.
For the purposes of this specification, we assume that there is an
abstract `community table' in the router. This table contains
several entries, each entry for a specific community and containing
the parameters necessary to completely define the attributes of that
community. The actual implementation method of the abstract
community table is, of course, implementation specific.
A router's community table MUST allow for at least one entry and
SHOULD allow for at least two entries.
DISCUSSION
A community table with zero capacity is useless. It means that
the router will not recognize any communities and, therefore, all
SNMP operations will be rejected.
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Therefore, one entry is the minimal useful size of the table.
Having two entries allows one entry to be limited to read-only
access while the other would have write capabilities.
Routers MUST allow the user to manually (i.e., without using SNMP)
examine, add, delete and change entries in the SNMP community table.
The user MUST be able to set the community name or construct a MIB
view. The user MUST be able to configure communities as read-only
(i.e., they do not allow SETs) or read-write (i.e., they do allow
SETs).
The user MUST be able to define at least one IP address to which
notifications are sent for each community or MIB view, if traps are
used. These addresses SHOULD be definable on a community or MIB view
basis. It SHOULD be possible to enable or disable notifications on a
community or MIB view basis.
A router SHOULD provide the ability to specify a list of valid
network managers for any particular community. If enabled, a router
MUST validate the source address of the SNMP datagram against the
list and MUST discard the datagram if its address does not appear.
If the datagram is discarded the router MUST take all actions
appropriate to an SNMP authentication failure.
DISCUSSION
This is a rather limited authentication system, but coupled with
various forms of packet filtering may provide some small measure
of increased security.
The community table MUST be saved in non-volatile storage.
The initial state of the community table SHOULD contain one entry,
with the community name string public and read-only access. The
default state of this entry MUST NOT send traps. If it is
implemented, then this entry MUST remain in the community table until
the administrator changes it or deletes it.
DISCUSSION
By default, traps are not sent to this community. Trap PDUs are
sent to unicast IP addresses. This address must be configured
into the router in some manner. Before the configuration occurs,
there is no such address, so to whom should the trap be sent?
Therefore trap sending to the public community defaults to be
disabled. This can, of course, be changed by an administrative
operation once the router is operational.
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All MIBS relevant to a router's configuration are to be implemented.
To wit:
o The System, Interface, IP, ICMP, and UDP groups of MIB-II [MGT:2]
MUST be implemented.
o The Interface Extensions MIB [MGT:18] MUST be implemented.
o The IP Forwarding Table MIB [MGT:20] MUST be implemented.
o If the router implements TCP (e.g., for Telnet) then the TCP group
of MIB-II [MGT:2] MUST be implemented.
o If the router implements EGP then the EGP group of MIB-II [MGT:2]
MUST be implemented.
o If the router supports OSPF then the OSPF MIB [MGT:14] MUST be
implemented.
o If the router supports BGP then the BGP MIB [MGT:15] MUST be
implemented.
o If the router has Ethernet, 802.3, or StarLan interfaces then the
Ethernet-Like MIB [MGT:6] MUST be implemented.
o If the router has 802.4 interfaces then the 802.4 MIB [MGT:7] MUST
be implemented.
o If the router has 802.5 interfaces then the 802.5 MIB [MGT:8] MUST
be implemented.
o If the router has FDDI interfaces that implement ANSI SMT 7.3 then
the FDDI MIB [MGT:9] MUST be implemented.
o If the router has FDDI interfaces that implement ANSI SMT 6.2 then
the FDDI MIB [MGT:29] MUST be implemented.
o If the router has interfaces that use V.24 signalling, such as RS-
232, V.10, V.11, V.35, V.36, or RS-422/423/449, then the RS-232
[MGT:10] MIB MUST be implemented.
o If the router has T1/DS1 interfaces then the T1/DS1 MIB [MGT:16]
MUST be implemented.
o If the router has T3/DS3 interfaces then the T3/DS3 MIB [MGT:17]
MUST be implemented.
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o If the router has SMDS interfaces then the SMDS Interface Protocol
MIB [MGT:19] MUST be implemented.
o If the router supports PPP over any of its interfaces then the PPP
MIBs [MGT:11], [MGT:12], and [MGT:13] MUST be implemented.
o If the router supports RIP Version 2 then the RIP Version 2 MIB
[MGT:21] MUST be implemented.
o If the router supports X.25 over any of its interfaces then the
X.25 MIBs [MGT:22, MGT:23 and MGT:24] MUST be implemented.
The Internet Standard and Experimental MIBs do not cover the entire
range of statistical, state, configuration and control information
that may be available in a network element. This information is,
nevertheless, extremely useful. Vendors of routers (and other
network devices) generally have developed MIB extensions that cover
this information. These MIB extensions are called Vendor Specific
MIBs.
The Vendor Specific MIB for the router MUST provide access to all
statistical, state, configuration, and control information that is
not available through the Standard and Experimental MIBs that have
been implemented. This information MUST be available for both
monitoring and control operations.
DISCUSSION
The intent of this requirement is to provide the ability to do
anything on the router through SNMP that can be done through a
console, and vice versa. A certain minimal amount of
configuration is necessary before SNMP can operate (e.g., the
router must have an IP address). This initial configuration can
not be done through SNMP. However, once the initial configuration
is done, full capabilities ought to be available through network
management.
The vendor SHOULD make available the specifications for all Vendor
Specific MIB variables. These specifications MUST conform to the SMI
[MGT:1] and the descriptions MUST be in the form specified in
[MGT:4].
DISCUSSION
Making the Vendor Specific MIB available to the user is necessary.
Without this information the users would not be able to configure
their network management systems to be able to access the Vendor
Specific parameters. These parameters would then be useless.
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ne 2 The format of the MIB specification is also specified.
Parsers that read MIB specifications and generate the needed
tables for the network management station are available. These
parsers generally understand only the standard MIB specification
format.
Parameters altered by SNMP MAY be saved to non-volatile storage.
DISCUSSION
Reasons why this requirement is a MAY:
o The exact physical nature of non-volatile storage is not
specified in this document. Hence, parameters may be saved in
NVRAM/EEPROM, local floppy or hard disk, or in some TFTP file
server or BOOTP server, etc. Suppose that this information is
in a file that is retrieved through TFTP. In that case, a
change made to a configuration parameter on the router would
need to be propagated back to the file server holding the
configuration file. Alternatively, the SNMP operation would
need to be directed to the file server, and then the change
somehow propagated to the router. The answer to this problem
does not seem obvious.
This also places more requirements on the host holding the
configuration information than just having an available TFTP
server, so much more that its probably unsafe for a vendor to
assume that any potential customer will have a suitable host
available.
o The timing of committing changed parameters to non-volatile
storage is still an issue for debate. Some prefer to commit
all changes immediately. Others prefer to commit changes to
non-volatile storage only upon an explicit command.
For all additional application protocols that a router implements,
the router MUST be compliant and SHOULD be unconditionally compliant
with the relevant requirements of [INTRO:3].
The Bootstrap Protocol (BOOTP) is a UDP/IP-based protocol that allows
a booting host to configure itself dynamically and without user
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supervision. BOOTP provides a means to notify a host of its assigned
IP address, the IP address of a boot server host, and the name of a
file to be loaded into memory and executed ([APPL:1]). Other
configuration information such as the local prefix length or subnet
mask, the local time offset, the addresses of default routers, and
the addresses of various Internet servers can also be communicated to
a host using BOOTP ([APPL:2]).
In many cases, BOOTP clients and their associated BOOTP server(s) do
not reside on the same IP (sub)network. In such cases, a third-party
agent is required to transfer BOOTP messages between clients and
servers. Such an agent was originally referred to as a BOOTP
forwarding agent. However, to avoid confusion with the IP forwarding
function of a router, the name BOOTP relay agent has been adopted
instead.
DISCUSSION
A BOOTP relay agent performs a task that is distinct from a
router's normal IP forwarding function. While a router normally
switches IP datagrams between networks more-or-less transparently,
a BOOTP relay agent may more properly be thought to receive BOOTP
messages as a final destination and then generate new BOOTP
messages as a result. One should resist the notion of simply
forwarding a BOOTP message straight through like a regular packet.
This relay-agent functionality is most conveniently located in the
routers that interconnect the clients and servers (although it may
alternatively be located in a host that is directly connected to the
client (sub)net).
A router MAY provide BOOTP relay-agent capability. If it does, it
MUST conform to the specifications in [APPL:3].
Section [5.2.3] discussed the circumstances under which a packet is
delivered locally (to the router). All locally delivered UDP
messages whose UDP destination port number is BOOTPS (67) are
considered for special processing by the router's logical BOOTP relay
agent.
Sections [4.2.2.11] and [5.3.7] discussed invalid IP source
addresses. According to these rules, a router must not forward any
received datagram whose IP source address is 0.0.0.0. However,
routers that support a BOOTP relay agent MUST accept for local
delivery to the relay agent BOOTREQUEST messages whose IP source
address is 0.0.0.0.
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This chapter supersedes any requirements of [INTRO:3] relating to
"Extensions to the IP Module."
Facilities to support operation and maintenance (O&M) activities form
an essential part of any router implementation. Although these
functions do not seem to relate directly to interoperability, they
are essential to the network manager who must make the router
interoperate and must track down problems when it doesn't. This
chapter also includes some discussion of router initialization and of
facilities to assist network managers in securing and accounting for
their networks.
The following kinds of activities are included under router O&M:
o Diagnosing hardware problems in the router's processor, in its
network interfaces, or in its connected networks, modems, or
communication lines.
o Installing new hardware
o Installing new software.
o Restarting or rebooting the router after a crash.
o Configuring (or reconfiguring) the router.
o Detecting and diagnosing Internet problems such as congestion,
routing loops, bad IP addresses, black holes, packet avalanches,
and misbehaved hosts.
o Changing network topology, either temporarily (e.g., to bypass a
communication line problem) or permanently.
o Monitoring the status and performance of the routers and the
connected networks.
o Collecting traffic statistics for use in (Inter-)network planning.
o Coordinating the above activities with appropriate vendors and
telecommunications specialists.
Routers and their connected communication lines are often operated as
a system by a centralized O&M organization. This organization may
maintain a (Inter-)network operation center, or NOC, to carry out its
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O&M functions. It is essential that routers support remote control
and monitoring from such a NOC through an Internet path, since
routers might not be connected to the same network as their NOC.
Since a network failure may temporarily preclude network access, many
NOCs insist that routers be accessible for network management through
an alternative means, often dial-up modems attached to console ports
on the routers.
Since an IP packet traversing an internet will often use routers
under the control of more than one NOC, Internet problem diagnosis
will often involve cooperation of personnel of more than one NOC. In
some cases, the same router may need to be monitored by more than one
NOC, but only if necessary, because excessive monitoring could impact
a router's performance.
The tools available for monitoring at a NOC may cover a wide range of
sophistication. Current implementations include multi-window,
dynamic displays of the entire router system. The use of AI
techniques for automatic problem diagnosis is proposed for the
future.
Router O&M facilities discussed here are only a part of the large and
difficult problem of Internet management. These problems encompass
not only multiple management organizations, but also multiple
protocol layers. For example, at the current stage of evolution of
the Internet architecture, there is a strong coupling between host
TCP implementations and eventual IP-level congestion in the router
system [OPER:1]. Therefore, diagnosis of congestion problems will
sometimes require the monitoring of TCP statistics in hosts. There
are currently a number of R&D efforts in progress in the area of
Internet management and more specifically router O&M. These R&D
efforts have already produced standards for router O&M. This is also
an area in which vendor creativity can make a significant
contribution.
There exists a minimum set of conditions that must be satisfied
before a router may forward packets. A router MUST NOT enable
forwarding on any physical interface unless either:
(1) The router knows the IP address and associated subnet mask or
network prefix length of at least one logical interface
associated with that physical interface, or
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(2) The router knows that the interface is an unnumbered interface
and knows its router-id.
These parameters MUST be explicitly configured:
o A router MUST NOT use factory-configured default values for its IP
addresses, prefix lengths, or router-id, and
o A router MUST NOT assume that an unconfigured interface is an
unnumbered interface.
DISCUSSION
There have been instances in which routers have been shipped with
vendor-installed default addresses for interfaces. In a few
cases, this has resulted in routers advertising these default
addresses into active networks.
A router MUST allow its IP addresses and their address masks or
prefix lengths to be statically configured and saved in non-volatile
storage.
A router MAY obtain its IP addresses and their corresponding address
masks dynamically as a side effect of the system initialization
process (see Section 10.2.3]);
If the dynamic method is provided, the choice of method to be used in
a particular router MUST be configurable.
As was described in Section [4.2.2.11], IP addresses are not
permitted to have the value 0 or -1 in the <Host-number> or
<Network-prefix> fields. Therefore, a router SHOULD NOT allow an IP
address or address mask to be set to a value that would make any of
the these fields above have the value zero or -1.
DISCUSSION
It is possible using arbitrary address masks to create situations
in which routing is ambiguous (i.e., two routes with different but
equally specific subnet masks match a particular destination
address). This is one of the strongest arguments for the use of
network prefixes, and the reason the use of discontiguous subnet
masks is not permitted.
A router SHOULD make the following checks on any address mask it
installs:
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o The mask is neither all ones nor all zeroes (the prefix length is
neither zero nor 32).
o The bits which correspond to the network prefix part of the address
are all set to 1.
o The bits that correspond to the network prefix are contiguous.
DISCUSSION
The masks associated with routes are also sometimes called subnet
masks, this test should not be applied to them.
There has been much discussion of how routers can and should be
booted from the network. These discussions have revolved around
BOOTP and TFTP. Currently, there are routers that boot with TFTP
from the network. There is no reason that BOOTP could not be used
for locating the server that the boot image should be loaded from.
BOOTP is a protocol used to boot end systems, and requires some
stretching to accommodate its use with routers. If a router is using
BOOTP to locate the current boot host, it should send a BOOTP Request
with its hardware address for its first interface, or, if it has been
previously configured otherwise, with either another interface's
hardware address, or another number to put in the hardware address
field of the BOOTP packet. This is to allow routers without hardware
addresses (like synchronous line only routers) to use BOOTP for
bootload discovery. TFTP can then be used to retrieve the image
found in the BOOTP Reply. If there are no configured interfaces or
numbers to use, a router MAY cycle through the interface hardware
addresses it has until a match is found by the BOOTP server.
A router SHOULD IMPLEMENT the ability to store parameters learned
through BOOTP into local non-volatile storage. A router MAY
implement the ability to store a system image loaded over the network
into local stable storage.
A router MAY have a facility to allow a remote user to request that
the router get a new boot image. Differentiation should be made
between getting the new boot image from one of three locations: the
one included in the request, from the last boot image server, and
using BOOTP to locate a server.
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There is a range of possible models for performing O&M functions on a
router. At one extreme is the local-only model, under which the O&M
functions can only be executed locally (e.g., from a terminal plugged
into the router machine). At the other extreme, the fully remote
model allows only an absolute minimum of functions to be performed
locally (e.g., forcing a boot), with most O&M being done remotely
from the NOC. There are intermediate models, such as one in which
NOC personnel can log into the router as a host, using the Telnet
protocol, to perform functions that can also be invoked locally. The
local-only model may be adequate in a few router installations, but
remote operation from a NOC is normally required, and therefore
remote O&M provisions are required for most routers.
Remote O&M functions may be exercised through a control agent
(program). In the direct approach, the router would support remote
O&M functions directly from the NOC using standard Internet protocols
(e.g., SNMP, UDP or TCP); in the indirect approach, the control agent
would support these protocols and control the router itself using
proprietary protocols. The direct approach is preferred, although
either approach is acceptable. The use of specialized host hardware
and/or software requiring significant additional investment is
discouraged; nevertheless, some vendors may elect to provide the
control agent as an integrated part of the network in which the
routers are a part. If this is the case, it is required that a means
be available to operate the control agent from a remote site using
Internet protocols and paths and with equivalent functionality with
respect to a local agent terminal.
It is desirable that a control agent and any other NOC software tools
that a vendor provides operate as user programs in a standard
operating system. The use of the standard Internet protocols UDP and
TCP for communicating with the routers should facilitate this.
Remote router monitoring and (especially) remote router control
present important access control problems that must be addressed.
Care must also be taken to ensure control of the use of router
resources for these functions. It is not desirable to let router
monitoring take more than some limited fraction of the router CPU
time, for example. On the other hand, O&M functions must receive
priority so they can be exercised when the router is congested, since
often that is when O&M is most needed.
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Routers MUST support Out-Of-Band (OOB) access. OOB access SHOULD
provide the same functionality as in-band access. This access SHOULD
implement access controls, to prevent unauthorized access.
DISCUSSION
This Out-Of-Band access will allow the NOC a way to access
isolated routers during times when network access is not
available.
Out-Of-Band access is an important management tool for the network
administrator. It allows the access of equipment independent of
the network connections. There are many ways to achieve this
access. Whichever one is used it is important that the access is
independent of the network connections. An example of Out-Of-Band
access would be a serial port connected to a modem that provides
dial up access to the router.
It is important that the OOB access provides the same
functionality as in-band access. In-band access, or accessing
equipment through the existing network connection, is limiting,
because most of the time, administrators need to reach equipment
to figure out why it is unreachable. In band access is still very
important for configuring a router, and for troubleshooting more
subtle problems.
Each router SHOULD operate as a stand-alone device for the purposes
of local hardware maintenance. Means SHOULD be available to run
diagnostic programs at the router site using only on-site tools. A
router SHOULD be able to run diagnostics in case of a fault. For
suggested hardware and software diagnostics see Section [10.3.3].
A router MUST include both in-band and out-of-band mechanisms to
allow the network manager to reload, stop, and restart the router. A
router SHOULD also contain a mechanism (such as a watchdog timer)
which will reboot the router automatically if it hangs due to a
software or hardware fault.
A router SHOULD IMPLEMENT a mechanism for dumping the contents of a
router's memory (and/or other state useful for vendor debugging after
a crash), and either saving them on a stable storage device local to
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the router or saving them on another host via an up-line dump
mechanism such as TFTP (see [OPER:2], [INTRO:3]).
Every router has configuration parameters that may need to be set.
It SHOULD be possible to update the parameters without rebooting the
router; at worst, a restart MAY be required. There may be cases when
it is not possible to change parameters without rebooting the router
(for instance, changing the IP address of an interface). In these
cases, care should be taken to minimize disruption to the router and
the surrounding network.
There SHOULD be a way to configure the router over the network either
manually or automatically. A router SHOULD be able to upload or
download its parameters from a host or another router. A means
SHOULD be provided, either as an application program or a router
function, to convert between the parameter format and a human-
editable format. A router SHOULD have some sort of stable storage
for its configuration. A router SHOULD NOT believe protocols such as
RARP, ICMP Address Mask Reply, and MAY not believe BOOTP.
DISCUSSION
It is necessary to note here that in the future RARP, ICMP Address
Mask Reply, BOOTP and other mechanisms may be needed to allow a
router to auto-configure. Although routers may in the future be
able to configure automatically, the intent here is to discourage
this practice in a production environment until auto-configuration
has been tested more thoroughly. The intent is NOT to discourage
auto-configuration all together. In cases where a router is
expected to get its configuration automatically it may be wise to
allow the router to believe these things as it comes up and then
ignore them after it has gotten its configuration.
A router SHOULD keep its system image in local non-volatile
storage such as PROM, NVRAM, or disk. It MAY also be able to load
its system software over the network from a host or another
router.
A router that can keep its system image in local non-volatile
storage MAY be configurable to boot its system image over the
network. A router that offers this option SHOULD be configurable
to boot the system image in its non-volatile local storage if it
is unable to boot its system image over the network.
Baker Standards Track [Page 128]
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DISCUSSION
It is important that the router be able to come up and run on its
own. NVRAM may be a particular solution for routers used in large
networks, since changing PROMs can be quite time consuming for a
network manager responsible for numerous or geographically
dispersed routers. It is important to be able to netboot the
system image because there should be an easy way for a router to
get a bug fix or new feature more quickly than getting PROMs
installed. Also if the router has NVRAM instead of PROMs, it will
netboot the image and then put it in NVRAM.
Routers SHOULD perform some basic consistency check on any image
loaded, to detect and perhaps prevent incorrect images.
A router MAY also be able to distinguish between different
configurations based on which software it is running. If
configuration commands change from one software version to another,
it would be helpful if the router could use the configuration that
was compatible with the software.
There MUST be mechanisms for detecting and responding to
misconfigurations. If a command is executed incorrectly, the router
SHOULD give an error message. The router SHOULD NOT accept a poorly
formed command as if it were correct.
DISCUSSION
There are cases where it is not possible to detect errors: the
command is correctly formed, but incorrect with respect to the
network. This may be detected by the router, but may not be
possible.
Another form of misconfiguration is misconfiguration of the network
to which the router is attached. A router MAY detect
misconfigurations in the network. The router MAY log these findings
to a file, either on the router or a host, so that the network
manager will see that there are possible problems on the network.
DISCUSSION
Examples of such misconfigurations might be another router with
the same address as the one in question or a router with the wrong
address mask. If a router detects such problems it is probably
not the best idea for the router to try to fix the situation.
That could cause more harm than good.
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Changing the configuration of a router SHOULD have minimal affect on
the network. Routing tables SHOULD NOT be unnecessarily flushed when
a simple change is made to the router. If a router is running
several routing protocols, stopping one routing protocol SHOULD NOT
disrupt other routing protocols, except in the case where one network
is learned by more than one routing protocol.
DISCUSSION
It is the goal of a network manager to run a network so that users
of the network get the best connectivity possible. Reloading a
router for simple configuration changes can cause disruptions in
routing and ultimately cause disruptions to the network and its
users. If routing tables are unnecessarily flushed, for instance,
the default route will be lost as well as specific routes to sites
within the network. This sort of disruption will cause
significant downtime for the users. It is the purpose of this
section to point out that whenever possible, these disruptions
should be avoided.
(1) A router MUST provide in-band network access, but (except as
required by Section [8.2]) for security considerations this
access SHOULD be disabled by default. Vendors MUST document
the default state of any in-band access. This access SHOULD
implement access controls, to prevent unauthorized access.
DISCUSSION
In-band access primarily refers to access through the normal
network protocols that may or may not affect the permanent
operational state of the router. This includes, but is not
limited to Telnet/RLOGIN console access and SNMP operations.
This was a point of contention between the operational out of the
box and secure out of The box contingents. Any automagic access
to the router may introduce insecurities, but it may be more
important for the customer to have a router that is accessible
over the network as soon as it is plugged in. At least one vendor
supplies routers without any external console access and depends
on being able to access the router through the network to complete
its configuration.
It is the vendors call whether in-band access is enabled by
default; but it is also the vendor's responsibility to make its
customers aware of possible insecurities.
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RFC 1812 Requirements for IP Version 4 Routers June 1995
(2) A router MUST provide the ability to initiate an ICMP echo.
The following options SHOULD be implemented:
o Choice of data patterns
o Choice of packet size
o Record route
and the following additional options MAY be implemented:
o Loose source route
o Strict source route
o Timestamps
(3) A router SHOULD provide the ability to initiate a traceroute.
If traceroute is provided, then the 3rd party traceroute
SHOULD be implemented.
Each of the above three facilities (if implemented) SHOULD have
access restrictions placed on it to prevent its abuse by unauthorized
persons.
Auditing and billing are the bane of the network operator, but are
the two features most requested by those in charge of network
security and those who are responsible for paying the bills. In the
context of security, auditing is desirable if it helps you keep your
network working and protects your resources from abuse, without
costing you more than those resources are worth.
(1) Configuration Changes
Router SHOULD provide a method for auditing a configuration
change of a router, even if it's something as simple as
recording the operator's initials and time of change.
DISCUSSION
Configuration change logging (who made a configuration change,
what was changed, and when) is very useful, especially when
traffic is suddenly routed through Alaska on its way across town.
So is the ability to revert to a previous configuration.
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(2) Packet Accounting
Vendors should strongly consider providing a system for
tracking traffic levels between pairs of hosts or networks.
A mechanism for limiting the collection of this information
to specific pairs of hosts or networks is also strongly
encouraged.
DISCUSSION
A host traffic matrix as described above can give the network
operator a glimpse of traffic trends not apparent from other
statistics. It can also identify hosts or networks that are
probing the structure of the attached networks - e.g., a single
external host that tries to send packets to every IP address in
the network address range for a connected network.
(3) Security Auditing
Routers MUST provide a method for auditing security related
failures or violations to include:
o Authorization Failures: bad passwords, invalid SNMP
communities, invalid authorization tokens,
o Violations of Policy Controls: Prohibited Source Routes,
Filtered Destinations, and
o Authorization Approvals: good passwords - Telnet in-band
access, console access.
Routers MUST provide a method of limiting or disabling such
auditing but auditing SHOULD be on by default. Possible
methods for auditing include listing violations to a console
if present, logging or counting them internally, or logging
them to a remote security server through the SNMP trap
mechanism or the Unix logging mechanism as appropriate. A
router MUST implement at least one of these reporting
mechanisms - it MAY implement more than one.
A vendor has a responsibility to use good configuration control
practices in the creation of the software/firmware loads for their
routers. In particular, if a vendor makes updates and loads
available for retrieval over the Internet, the vendor should also
provide a way for the customer to confirm the load is a valid one,
perhaps by the verification of a checksum over the load.
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DISCUSSION
Many vendors currently provide short notice updates of their
software products through the Internet. This a good trend and
should be encouraged, but provides a point of vulnerability in the
configuration control process.
If a vendor provides the ability for the customer to change the
configuration parameters of a router remotely, for example through a
Telnet session, the ability to do so SHOULD be configurable and
SHOULD default to off. The router SHOULD require valid
authentication before permitting remote reconfiguration. This
authentication procedure SHOULD NOT transmit the authentication
secret over the network. For example, if telnet is implemented, the
vendor SHOULD IMPLEMENT Kerberos, S-Key, or a similar authentication
procedure.
DISCUSSION
Allowing your properly identified network operator to twiddle with
your routers is necessary; allowing anyone else to do so is
foolhardy.
A router MUST NOT have undocumented back door access and master
passwords. A vendor MUST ensure any such access added for purposes
of debugging or product development are deleted before the product is
distributed to its customers.
DISCUSSION
A vendor has a responsibility to its customers to ensure they are
aware of the vulnerabilities present in its code by intention -
e.g., in-band access. Trap doors, back doors and master passwords
intentional or unintentional can turn a relatively secure router
into a major problem on an operational network. The supposed
operational benefits are not matched by the potential problems.
Implementors should be aware that Internet protocol standards are
occasionally updated. These references are current as of this
writing, but a cautious implementor will always check a recent
version of the RFC index to ensure that an RFC has not been updated
or superseded by another, more recent RFC. Reference [INTRO:6]
explains various ways to obtain a current RFC index.
APPL:1.
Croft, B., and J. Gilmore, "Bootstrap Protocol (BOOTP)", RFC
951, Stanford University, Sun Microsystems, September 1985.
Baker Standards Track [Page 133]
RFC 1812 Requirements for IP Version 4 Routers June 1995
APPL:2.
Alexander, S., and R. Droms, "DHCP Options and BOOTP Vendor
Extensions", RFC 1533, Lachman Technology, Inc., Bucknell
University, October 1993.
APPL:3.
Wimer, W., "Clarifications and Extensions for the Bootstrap
Protocol", RFC 1542, Carnegie Mellon University, October 1993.
ARCH:1.
DDN Protocol Handbook, NIC-50004, NIC-50005, NIC-50006 (three
volumes), DDN Network Information Center, SRI International,
Menlo Park, California, USA, December 1985.
ARCH:2.
V. Cerf and R. Kahn, "A Protocol for Packet Network
Intercommunication", IEEE Transactions on Communication, May
1974. Also included in [ARCH:1].
ARCH:3.
J. Postel, C. Sunshine, and D. Cohen, "The ARPA Internet
Protocol", Computer Networks, volume 5, number 4, July 1981.
Also included in [ARCH:1].
ARCH:4.
B. Leiner, J. Postel, R. Cole, and D. Mills, :The DARPA
Internet Protocol Suite", Proceedings of INFOCOM '85, IEEE,
Washington, DC, March 1985. Also in: IEEE Communications
Magazine, March 1985. Also available from the Information
Sciences Institute, University of Southern California as
Technical Report ISI-RS-85-153.
ARCH:5.
D. Comer, "Internetworking With TCP/IP Volume 1: Principles,
Protocols, and Architecture", Prentice Hall, Englewood Cliffs,
NJ, 1991.
ARCH:6.
W. Stallings, "Handbook of Computer-Communications Standards
Volume 3: The TCP/IP Protocol Suite", Macmillan, New York, NY,
1990.
ARCH:7.
Postel, J., "Internet Official Protocol Standards", STD 1, RFC
1780, Internet Architecture Board, March 1995.
Baker Standards Track [Page 134]
RFC 1812 Requirements for IP Version 4 Routers June 1995
ARCH:8.
Information processing systems - Open Systems Interconnection -
Basic Reference Model, ISO 7489, International Standards
Organization, 1984.
ARCH:9
R. Braden, J. Postel, Y. Rekhter, "Internet Architecture
Extensions for Shared Media", 05/20/1994
FORWARD:1.
IETF CIP Working Group (C. Topolcic, Editor), "Experimental
Internet Stream Protocol", Version 2 (ST-II), RFC 1190, October
1990.
FORWARD:2.
Mankin, A., and K. Ramakrishnan, Editors, "Gateway Congestion
Control Survey", RFC 1254, MITRE, Digital Equipment Corporation,
August 1991.
FORWARD:3.
J. Nagle, "On Packet Switches with Infinite Storage", IEEE
Transactions on Communications, volume COM-35, number 4, April
1987.
FORWARD:4.
R. Jain, K. Ramakrishnan, and D. Chiu, "Congestion Avoidance
in Computer Networks With a Connectionless Network Layer",
Technical Report DEC-TR-506, Digital Equipment Corporation.
FORWARD:5.
V. Jacobson, "Congestion Avoidance and Control", Proceedings of
SIGCOMM '88, Association for Computing Machinery, August 1988.
FORWARD:6.
W. Barns, "Precedence and Priority Access Implementation for
Department of Defense Data Networks", Technical Report MTR-
91W00029, The Mitre Corporation, McLean, Virginia, USA, July
1991.
FORWARD:7
Fang, Chen, Hutchins, "Simulation Results of TCP Performance
over ATM with and without Flow Control", presentation to the ATM
Forum, November 15, 1993.
FORWARD:8
V. Paxson, S. Floyd "Wide Area Traffic: the Failure of Poisson
Modeling", short version in SIGCOMM '94.
Baker Standards Track [Page 135]
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FORWARD:9
Leland, Taqqu, Willinger and Wilson, "On the Self-Similar Nature
of Ethernet Traffic", Proceedings of SIGCOMM '93, September,
1993.
FORWARD:10
S. Keshav "A Control Theoretic Approach to Flow Control",
SIGCOMM 91, pages 3-16
FORWARD:11
K.K. Ramakrishnan and R. Jain, "A Binary Feedback Scheme for
Congestion Avoidance in Computer Networks", ACM Transactions of
Computer Systems, volume 8, number 2, 1980.
FORWARD:12
H. Kanakia, P. Mishara, and A. Reibman]. "An adaptive
congestion control scheme for real-time packet video transport",
In Proceedings of ACM SIGCOMM 1994, pages 20-31, San Francisco,
California, September 1993.
FORWARD:13
A. Demers, S. Keshav, S. Shenker, "Analysis and Simulation of
a Fair Queuing Algorithm",
93 pages 1-12
FORWARD:14
Clark, D., Shenker, S., and L. Zhang, "Supporting Real-Time
Applications in an Integrated Services Packet Network:
Architecture and Mechanism", 92 pages 14-26
INTERNET:1.
Postel, J., "Internet Protocol", STD 5, RFC 791, USC/Information
Sciences Institute, September 1981.
INTERNET:2.
Mogul, J., and J. Postel, "Internet Standard Subnetting
Procedure", STD 5, RFC 950, Stanford, USC/Information Sciences
Institute, August 1985.
INTERNET:3.
Mogul, J., "Broadcasting Internet Datagrams in the Presence of
Subnets", STD 5, RFC 922, Stanford University, October 1984.
INTERNET:4.
Deering, S., "Host Extensions for IP Multicasting", STD 5, RFC
1112, Stanford University, August 1989.
Baker Standards Track [Page 136]
RFC 1812 Requirements for IP Version 4 Routers June 1995
INTERNET:5.
Kent, S., "U.S. Department of Defense Security Options for the
Internet Protocol", RFC 1108, BBN Communications, November 1991.
INTERNET:6.
Braden, R., Borman, D., and C. Partridge, "Computing the
Internet Checksum", RFC 1071, USC/Information Sciences
Institute, Cray Research, BBN Communications, September 1988.
INTERNET:7.
Mallory T., and A. Kullberg, "Incremental Updating of the
Internet Checksum", RFC 1141, BBN Communications, January 1990.
INTERNET:8.
Postel, J., "Internet Control Message Protocol", STD 5, RFC 792,
USC/Information Sciences Institute, September 1981.
INTERNET:9.
A. Mankin, G. Hollingsworth, G. Reichlen, K. Thompson, R.
Wilder, and R. Zahavi, "Evaluation of Internet Performance -
FY89", Technical Report MTR-89W00216, MITRE Corporation,
February, 1990.
INTERNET:10.
G. Finn, A "Connectionless Congestion Control Algorithm",
Computer Communications Review, volume 19, number 5, Association
for Computing Machinery, October 1989.
INTERNET:11.
Prue, W., and J. Postel, "The Source Quench Introduced Delay
(SQuID)", RFC 1016, USC/Information Sciences Institute, August
1987.
INTERNET:12.
McKenzie, A., "Some comments on SQuID", RFC 1018, BBN Labs,
August 1987.
INTERNET:13.
Deering, S., "ICMP Router Discovery Messages", RFC 1256, Xerox
PARC, September 1991.
INTERNET:14.
Mogul J., and S. Deering, "Path MTU Discovery", RFC 1191,
DECWRL, Stanford University, November 1990.
Baker Standards Track [Page 137]
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INTERNET:15
Fuller, V., Li, T., Yu, J., and K. Varadhan, "Classless Inter-
Domain Routing (CIDR): an Address Assignment and Aggregation
Strategy" RFC 1519, BARRNet, cisco, Merit, OARnet, September
1993.
INTERNET:16
St. Johns, M., "Draft Revised IP Security Option", RFC 1038,
IETF, January 1988.
INTERNET:17
Prue, W., and J. Postel, "Queuing Algorithm to Provide Type-
of-service For IP Links", RFC 1046, USC/Information Sciences
Institute, February 1988.
INTERNET:18
Postel, J., "Address Mappings", RFC 796, USC/Information
Sciences Institute, September 1981.
INTRO:1.
Braden, R., and J. Postel, "Requirements for Internet
Gateways", STD 4, RFC 1009, USC/Information Sciences Institute,
June 1987.
INTRO:2.
Internet Engineering Task Force (R. Braden, Editor),
"Requirements for Internet Hosts - Communication Layers", STD 3,
RFC 1122, USC/Information Sciences Institute, October 1989.
INTRO:3.
Internet Engineering Task Force (R. Braden, Editor),
"Requirements for Internet Hosts - Application and Support", STD
3, RFC 1123, USC/Information Sciences Institute, October 1989.
INTRO:4.
Clark, D., "Modularity and Efficiency in Protocol
Implementations", RFC 817, MIT Laboratory for Computer Science,
July 1982.
INTRO:5.
Clark, D., "The Structuring of Systems Using Upcalls",
Proceedings of 10th ACM SOSP, December 1985.
INTRO:6.
Jacobsen, O., and J. Postel, "Protocol Document Order
Information", RFC 980, SRI, USC/Information Sciences Institute,
March 1986.
Baker Standards Track [Page 138]
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INTRO:7.
Reynolds, J., and J. Postel, "Assigned Numbers", STD 2, RFC
1700, USC/Information Sciences Institute, October 1994. This
document is periodically updated and reissued with a new number.
It is wise to verify occasionally that the version you have is
still current.
INTRO:8.
DoD Trusted Computer System Evaluation Criteria, DoD publication
5200.28-STD, U.S. Department of Defense, December 1985.
INTRO:9
Malkin, G., and T. LaQuey Parker, Editors, "Internet Users'
Glossary", FYI 18, RFC 1392, Xylogics, Inc., UTexas, January
1993.
LINK:1.
Leffler, S., and M. Karels, "Trailer Encapsulations", RFC 893,
University of California at Berkeley, April 1984.
LINK:2
Simpson, W., "The Point-to-Point Protocol (PPP)", STD 51, RFC
1661, Daydreamer July 1994.
LINK:3
McGregor, G., "The PPP Internet Protocol Control Protocol
(IPCP)", RFC 1332, Merit May 1992.
LINK:4
Lloyd, B., and W. Simpson, "PPP Authentication Protocols", RFC
1334, L&A, Daydreamer, May 1992.
LINK:5
Simpson, W., "PPP Link Quality Monitoring", RFC 1333,
Daydreamer, May 1992.
MGT:1.
Rose, M., and K. McCloghrie, "Structure and Identification of
Management Information of TCP/IP-based Internets", STD 16, RFC
1155, Performance Systems International, Hughes LAN Systems, May
1990.
MGT:2.
McCloghrie, K., and M. Rose (Editors), "Management Information
Base of TCP/IP-Based Internets: MIB-II", STD 16, RFC 1213,
Hughes LAN Systems, Inc., Performance Systems International,
March 1991.
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MGT:3.
Case, J., Fedor, M., Schoffstall, M., and J. Davin, "Simple
Network Management Protocol", STD 15, RFC 1157, SNMP Research,
Performance Systems International, MIT Laboratory for Computer
Science, May 1990.
MGT:4.
Rose, M., and K. McCloghrie (Editors), "Towards Concise MIB
Definitions", STD 16, RFC 1212, Performance Systems
International, Hughes LAN Systems, March 1991.
MGT:5.
Steinberg, L., "Techniques for Managing Asynchronously Generated
Alerts", RFC 1224, IBM Corporation, May 1991.
MGT:6.
Kastenholz, F., "Definitions of Managed Objects for the
Ethernet-like Interface Types", RFC 1398, FTP Software, Inc.,
January 1993.
MGT:7.
McCloghrie, K., and R. Fox "IEEE 802.4 Token Bus MIB", RFC 1230,
Hughes LAN Systems, Inc., Synoptics, Inc., May 1991.
MGT:8.
McCloghrie, K., Fox R., and E. Decker, "IEEE 802.5 Token Ring
MIB", RFC 1231, Hughes LAN Systems, Inc., Synoptics, Inc., cisco
Systems, Inc., February 1993.
MGT:9.
Case, J., and A. Rijsinghani, "FDDI Management Information
Base", RFC 1512, The University of Tennesse and SNMP Research,
Digital Equipment Corporation, September 1993.
MGT:10.
Stewart, B., Editor "Definitions of Managed Objects for RS-232-
like Hardware Devices", RFC 1317, Xyplex, Inc., April 1992.
MGT:11.
Kastenholz, F., "Definitions of Managed Objects for the Link
Control Protocol of the Point-to-Point Protocol", RFC 1471, FTP
Software, Inc., June 1992.
MGT:12.
Kastenholz, F., "The Definitions of Managed Objects for the
Security Protocols of the Point-to-Point Protocol", RFC 1472,
FTP Software, Inc., June 1992.
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MGT:13.
Kastenholz, F., "The Definitions of Managed Objects for the IP
Network Control Protocol of the Point-to-Point Protocol", RFC
1473, FTP Software, Inc., June 1992.
MGT:14.
Baker, F., and R. Coltun, "OSPF Version 2 Management
Information Base", RFC 1253, ACC, Computer Science Center,
August 1991.
MGT:15.
Willis, S., and J. Burruss, "Definitions of Managed Objects for
the Border Gateway Protocol (Version 3)", RFC 1269, Wellfleet
Communications Inc., October 1991.
MGT:16.
Baker, F., and J. Watt, "Definitions of Managed Objects for the
DS1 and E1 Interface Types", RFC 1406, Advanced Computer
Communications, Newbridge Networks Corporation, January 1993.
MGT:17.
Cox, T., and K. Tesink, Editors "Definitions of Managed Objects
for the DS3/E3 Interface Types", RFC 1407, Bell Communications
Research, January 1993.
MGT:18.
McCloghrie, K., "Extensions to the Generic-Interface MIB", RFC
1229, Hughes LAN Systems, August 1992.
MGT:19.
Cox, T., and K. Tesink, "Definitions of Managed Objects for the
SIP Interface Type", RFC 1304, Bell Communications Research,
February 1992.
MGT:20
Baker, F., "IP Forwarding Table MIB", RFC 1354, ACC, July 1992.
MGT:21.
Malkin, G., and F. Baker, "RIP Version 2 MIB Extension", RFC
1724, Xylogics, Inc., Cisco Systems, November 1994
MGT:22.
Throop, D., "SNMP MIB Extension for the X.25 Packet Layer", RFC
1382, Data General Corporation, November 1992.
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MGT:23.
Throop, D., and F. Baker, "SNMP MIB Extension for X.25 LAPB",
RFC 1381, Data General Corporation, ACC, November 1992.
MGT:24.
Throop, D., and F. Baker, "SNMP MIB Extension for MultiProtocol
Interconnect over X.25", RFC 1461, Data General Corporation, May
1993.
MGT:25.
Rose, M., "SNMP over OSI", RFC 1418, Dover Beach Consulting,
Inc., March 1993.
MGT:26.
Minshall, G., and M. Ritter, "SNMP over AppleTalk", RFC 1419,
Novell, Inc., Apple Computer, Inc., March 1993.
MGT:27.
Bostock, S., "SNMP over IPX", RFC 1420, Novell, Inc., March
1993.
MGT:28.
Schoffstall, M., Davin, C., Fedor, M., and J. Case, "SNMP over
Ethernet", RFC 1089, Rensselaer Polytechnic Institute, MIT
Laboratory for Computer Science, NYSERNet, Inc., University of
Tennessee at Knoxville, February 1989.
MGT:29.
Case, J., "FDDI Management Information Base", RFC 1285, SNMP
Research, Incorporated, January 1992.
OPER:1.
Nagle, J., "Congestion Control in IP/TCP Internetworks", RFC
896, FACC, January 1984.
OPER:2.
Sollins, K., "TFTP Protocol (revision 2)", RFC 1350, MIT, July
1992.
ROUTE:1.
Moy, J., "OSPF Version 2", RFC 1583, Proteon, March 1994.
ROUTE:2.
Callon, R., "Use of OSI IS-IS for Routing in TCP/IP and Dual
Environments", RFC 1195, DEC, December 1990.
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ROUTE:3.
Hedrick, C., "Routing Information Protocol", RFC 1058, Rutgers
University, June 1988.
ROUTE:4.
Lougheed, K., and Y. Rekhter, "A Border Gateway Protocol 3
(BGP-3)", RFC 1267, cisco, T.J. Watson Research Center, IBM
Corp., October 1991.
ROUTE:5.
Gross, P, and Y. Rekhter, "Application of the Border Gateway
Protocol in the Internet", RFC 1772, T.J. Watson Research
Center, IBM Corp., MCI, March 1995.
ROUTE:6.
Mills, D., "Exterior Gateway Protocol Formal Specification", RFC
904, UDEL, April 1984.
ROUTE:7.
Rosen, E., "Exterior Gateway Protocol (EGP)", RFC 827, BBN,
October 1982.
ROUTE:8.
Seamonson, L, and E. Rosen, "STUB" "Exterior Gateway Protocol",
RFC 888, BBN, January 1984.
ROUTE:9.
Waitzman, D., Partridge, C., and S. Deering, "Distance Vector
Multicast Routing Protocol", RFC 1075, BBN, Stanford, November
1988.
ROUTE:10.
Deering, S., Multicast Routing in Internetworks and Extended
LANs, Proceedings of '88, Association for Computing Machinery,
August 1988.
ROUTE:11.
Almquist, P., "Type of Service in the Internet Protocol Suite",
RFC 1349, Consultant, July 1992.
ROUTE:12.
Rekhter, Y., "Experience with the BGP Protocol", RFC 1266, T.J.
Watson Research Center, IBM Corp., October 1991.
ROUTE:13.
Rekhter, Y., "BGP Protocol Analysis", RFC 1265, T.J. Watson
Research Center, IBM Corp., October 1991.
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TRANS:1.
Postel, J., "User Datagram Protocol", STD 6, RFC 768,
USC/Information Sciences Institute, August 1980.
TRANS:2.
Postel, J., "Transmission Control Protocol", STD 7, RFC 793,
USC/Information Sciences Institute, September 1981.
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APPENDIX A. REQUIREMENTS FOR SOURCE-ROUTING HOSTS
Subject to restrictions given below, a host MAY be able to act as an
intermediate hop in a source route, forwarding a source-routed
datagram to the next specified hop.
However, in performing this router-like function, the host MUST obey
all the relevant rules for a router forwarding source-routed
datagrams [INTRO:2]. This includes the following specific
provisions:
(A) TTL
The TTL field MUST be decremented and the datagram perhaps
discarded as specified for a router in [INTRO:2].
(B) ICMP Destination Unreachable
A host MUST be able to generate Destination Unreachable messages
with the following codes:
4 (Fragmentation Required but DF Set) when a source-routed
datagram cannot be fragmented to fit into the target network;
5 (Source Route Failed) when a source-routed datagram cannot be
forwarded, e.g., because of a routing problem or because the
next hop of a strict source route is not on a connected
network.
(C) IP Source Address
A source-routed datagram being forwarded MAY (and normally will)
have a source address that is not one of the IP addresses of the
forwarding host.
(D) Record Route Option
A host that is forwarding a source-routed datagram containing a
Record Route option MUST update that option, if it has room.
(E) Timestamp Option
A host that is forwarding a source-routed datagram containing a
Timestamp Option MUST add the current timestamp to that option,
according to the rules for this option.
To define the rules restricting host forwarding of source-routed
datagrams, we use the term local source-routing if the next hop will
be through the same physical interface through which the datagram
arrived; otherwise, it is non-local source-routing.
A host is permitted to perform local source-routing without
restriction.
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A host that supports non-local source-routing MUST have a
configurable switch to disable forwarding, and this switch MUST
default to disabled.
The host MUST satisfy all router requirements for configurable policy
filters [INTRO:2] restricting non-local forwarding.
If a host receives a datagram with an incomplete source route but
does not forward it for some reason, the host SHOULD return an ICMP
Destination Unreachable (code 5, Source Route Failed) message, unless
the datagram was itself an ICMP error message.
APPENDIX B. GLOSSARY
This Appendix defines specific terms used in this memo. It also
defines some general purpose terms that may be of interest. See also
[INTRO:9] for a more general set of definitions.
Autonomous System (AS)
An Autonomous System (AS) is a connected segment of a network
topology that consists of a collection of subnetworks (with
hosts attached) interconnected by a set of routes. The
subnetworks and the routers are expected to be under the control
of a single operations and maintenance (O&M) organization.
Within an AS routers may use one or more interior routing
protocols, and sometimes several sets of metrics. An AS is
expected to present to other ASs an appearence of a coherent
interior routing plan, and a consistent picture of the
destinations reachable through the AS. An AS is identified by
an Autonomous System number.
Connected Network
A network prefix to which a router is interfaced is often known
as a local network or the subnetwork of that router. However,
these terms can cause confusion, and therefore we use the term
Connected Network in this memo.
Connected (Sub)Network
A Connected (Sub)Network is an IP subnetwork to which a router
is interfaced, or a connected network if the connected network
is not subnetted. See also Connected Network.
Datagram
The unit transmitted between a pair of internet modules. Data,
called datagrams, from sources to destinations. The Internet
Protocol does not provide a reliable communication facility.
There are no acknowledgments either end-to-end or hop-by-hop.
There is no error no retransmissions. There is no flow control.
See IP.
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Default Route
A routing table entry that is used to direct any data addressed
to any network prefixes not explicitly listed in the routing
table.
Dense Mode
In multicast forwarding, two paradigms are possible: in Dense
Mode forwarding, a network multicast is forwarded as a data link
layer multicast to all interfaces except that on which it was
received, unless and until the router is instructed not to by a
multicast routing neighbor. See Sparse Mode.
EGP
Exterior Gateway Protocol A protocol that distributes routing
information to the gateways (routers) which connect autonomous
systems. See IGP.
EGP-2
Exterior Gateway Protocol version 2 This is an EGP routing
protocol developed to handle traffic between Autonomous Systems
in the Internet.
Forwarder
The logical entity within a router that is responsible for
switching packets among the router's interfaces. The Forwarder
also makes the decisions to queue a packet for local delivery,
to queue a packet for transmission out another interface, or
both.
Forwarding
Forwarding is the process a router goes through for each packet
received by the router. The packet may be consumed by the
router, it may be output on one or more interfaces of the
router, or both. Forwarding includes the process of deciding
what to do with the packet as well as queuing it up for
(possible) output or internal consumption.
Forwarding Information Base (FIB)
The table containing the information necessary to forward IP
Datagrams, in this document, is called the Forwarding
Information Base. At minimum, this contains the interface
identifier and next hop information for each reachable
destination network prefix.
Fragment
An IP datagram that represents a portion of a higher layer's
packet that was too large to be sent in its entirety over the
output network.
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General Purpose Serial Interface
A physical medium capable of connecting exactly two systems, and
therefore configurable as a point to point line, but also
configurable to support link layer networking using protocols
such as X.25 or Frame Relay. A link layer network connects
another system to a switch, and a higher communication layer
multiplexes virtual circuits on the connection. See Point to
Point Line.
IGP
Interior Gateway Protocol A protocol that distributes routing
information with an Autonomous System (AS). See EGP.
Interface IP Address
The IP Address and network prefix length that is assigned to a
specific interface of a router.
Internet Address
An assigned number that identifies a host in an internet. It
has two parts: an IP address and a prefix length. The prefix
length indicates how many of the most specific bits of the
address constitute the network prefix.
IP
Internet Protocol The network layer protocol for the Internet.
It is a packet switching, datagram protocol defined in RFC 791.
IP does not provide a reliable communications facility; that is,
there are no end-to-end of hop-by-hop acknowledgments.
IP Datagram
An IP Datagram is the unit of end-to-end transmission in the
Internet Protocol. An IP Datagram consists of an IP header
followed by all of higher-layer data (such as TCP, UDP, ICMP,
and the like). An IP Datagram is an IP header followed by a
message.
An IP Datagram is a complete IP end-to-end transmission unit.
An IP Datagram is composed of one or more IP Fragments.
In this memo, the unqualified term Datagram should be understood
to refer to an IP Datagram.
IP Fragment
An IP Fragment is a component of an IP Datagram. An IP Fragment
consists of an IP header followed by all or part of the higher-
layer of the original IP Datagram.
One or more IP Fragments comprises a single IP Datagram.
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In this memo, the unqualified term Fragment should be understood
to refer to an IP Fragment.
IP Packet
An IP Datagram or an IP Fragment.
In this memo, the unqualified term Packet should generally be
understood to refer to an IP Packet.
Logical [network] interface
We define a logical [network] interface to be a logical path,
distinguished by a unique IP address, to a connected network.
Martian Filtering
A packet that contains an invalid source or destination address
is considered to be martian and discarded.
MTU (Maximum Transmission Unit)
The size of the largest packet that can be transmitted or
received through a logical interface. This size includes the IP
header but does not include the size of any Link Layer headers
or framing.
Multicast
A packet that is destined for multiple hosts. See broadcast.
Multicast Address
A special type of address that is recognizable by multiple
hosts.
A Multicast Address is sometimes known as a Functional Address
or a Group Address.
Network Prefix
The portion of an IP Address that signifies a set of systems.
It is selected from the IP Address by logically ANDing a subnet
mask with the address, or (equivalently) setting the bits of the
address not among the most significant <prefix-length> bits of
the address to zero.
Originate
Packets can be transmitted by a router for one of two reasons:
1) the packet was received and is being forwarded or 2) the
router itself created the packet for transmission (such as route
advertisements). Packets that the router creates for
transmission are said to originate at the router.
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Packet
A packet is the unit of data passed across the interface between
the Internet Layer and the Link Layer. It includes an IP header
and data. A packet may be a complete IP datagram or a fragment
of an IP datagram.
Path
The sequence of routers and (sub-)networks that a packet
traverses from a particular router to a particular destination
host. Note that a path is uni-directional; it is not unusual to
have different paths in the two directions between a given host
pair.
Physical Network
A Physical Network is a network (or a piece of an internet)
which is contiguous at the Link Layer. Its internal structure
(if any) is transparent to the Internet Layer.
In this memo, several media components that are connected using
devices such as bridges or repeaters are considered to be a
single Physical Network since such devices are transparent to
the IP.
Physical Network Interface
This is a physical interface to a Connected Network and has a
(possibly unique) Link-Layer address. Multiple Physical Network
Interfaces on a single router may share the same Link-Layer
address, but the address must be unique for different routers on
the same Physical Network.
Point to Point Line
A physical medium capable of connecting exactly two systems. In
this document, it is only used to refer to such a line when used
to connect IP entities. See General Purpose Serial Interface.
router
A special-purpose dedicated computer that connects several
networks. Routers switch packets between these networks in a
process known as forwarding. This process may be repeated
several times on a single packet by multiple routers until the
packet can be delivered to the final destination - switching the
packet from router to router to router... until the packet gets
to its destination.
RPF
Reverse Path Forwarding - A method used to deduce the next hops
for broadcast and multicast packets.
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Silently Discard
This memo specifies several cases where a router is to Silently
Discard a received packet (or datagram). This means that the
router should discard the packet without further processing, and
that the router will not send any ICMP error message (see
Section [4.3.2]) as a result. However, for diagnosis of
problems, the router should provide the capability of logging
the error (see Section [1.3.3]), including the contents of the
silently discarded packet, and should record the event in a
statistics counter.
Silently Ignore
A router is said to Silently Ignore an error or condition if it
takes no action other than possibly generating an error report
in an error log or through some network management protocol, and
discarding, or ignoring, the source of the error. In
particular, the router does NOT generate an ICMP error message.
Sparse Mode
In multicast forwarding, two paradigms are possible: in Sparse
Mode forwarding, a network layer multicast datagram is forwarded
as a data link layer multicast frame to routers and hosts that
have asked for it. The initial forwarding state is the inverse
of dense-mode in that it assumes no part of the network wants
the data. See Dense Mode.
Specific-destination address
This is defined to be the destination address in the IP header
unless the header contains an IP broadcast or IP multicast
address, in which case the specific-destination is an IP address
assigned to the physical interface on which the packet arrived.
subnet
A portion of a network, which may be a physically independent
network, which shares a network address with other portions of
the network and is distinguished by a subnet number. A subnet
is to a network what a network is to an internet.
subnet number
A part of the internet address that designates a subnet. It is
ignored for the purposes internet routing, but is used for
intranet routing.
TOS
Type Of Service A field in the IP header that represents the
degree of reliability expected from the network layer by the
transport layer or application.
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TTL
Time To Live A field in the IP header that represents how long a
packet is considered valid. It is a combination hop count and
timer value.
APPENDIX C. FUTURE DIRECTIONS
This appendix lists work that future revisions of this document may
wish to address.
In the preparation of Router Requirements, we stumbled across several
other architectural issues. Each of these is dealt with somewhat in
the document, but still ought to be classified as an open issue in
the IP architecture.
Most of the he topics presented here generally indicate areas where
the technology is still relatively new and it is not appropriate to
develop specific requirements since the community is still gaining
operational experience.
Other topics represent areas of ongoing research and indicate areas
that the prudent developer would closely monitor.
(1) SNMP Version 2
(2) Additional SNMP MIBs
(7) More detailed requirements for leaking routes between routing
protocols
(8) Router system security
(9) Routing protocol security
(10) Internetwork Protocol layer security. There has been extensive
work refining the security of IP since the original work writing
this document. This security work should be included in here.
(12) Load Splitting
(13) Sending fragments along different paths
(15) Multiple logical (sub)nets on the same wire. Router
Requirements does not require support for this. We made some
attempt to identify pieces of the architecture (e.g., forwarding
of directed broadcasts and issuing of Redirects) where the
wording of the rules has to be done carefully to make the right
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thing happen, and tried to clearly distinguish logical
interfaces from physical interfaces. However, we did not study
this issue in detail, and we are not at all confident that all
the rules in the document are correct in the presence of
multiple logical (sub)nets on the same wire.
(15) Congestion control and resource management. On the advice of
the IETF's experts (Mankin and Ramakrishnan) we deprecated
(SHOULD NOT) Source Quench and said little else concrete
(Section 5.3.6).
(16) Developing a Link-Layer requirements document that would be
common for both routers and hosts.
(17) Developing a common PPP LQM algorithm.
(18) Investigate of other information (above and beyond section
[3.2]) that passes between the layers, such as physical network
MTU, mappings of IP precedence to Link Layer priority values,
etc.
(19) Should the Link Layer notify IP if address resolution failed
(just like it notifies IP when there is a Link Layer priority
value problem)?
(20) Should all routers be required to implement a DNS resolver?
(21) Should a human user be able to use a host name anywhere you can
use an IP address when configuring the router? Even in ping and
traceroute?
(22) Almquist's draft ruminations on the next hop and ruminations on
route leaking need to be reviewed, brought up to date, and
published.
(23) Investigation is needed to determine if a redirect message for
precedence is needed or not. If not, are the type-of-service
redirects acceptable?
(24) RIPv2 and RIP+CIDR and variable length network prefixes.
(25) BGP-4 CIDR is going to be important, and everyone is betting on
BGP-4. We can't avoid mentioning it. Probably need to describe
the differences between BGP-3 and BGP-4, and explore upgrade
issues...
(26) Loose Source Route Mobile IP and some multicasting may require
this. Perhaps it should be elevated to a SHOULD (per Fred
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Baker's Suggestion).
APPENDIX D. Multicast Routing Protocols
Multicasting is a relatively new technology within the Internet
Protocol family. It is not widely deployed or commonly in use yet.
Its importance, however, is expected to grow over the coming years.
This Appendix describes some of the technologies being investigated
for routing multicasts through the Internet.
A diligent implementor will keep abreast of developments in this area
to properly develop multicast facilities.
This Appendix does not specify any standards or requirements.
Multicast routing protocols enable the forwarding of IP multicast
datagrams throughout a TCP/IP internet. Generally these algorithms
forward the datagram based on its source and destination addresses.
Additionally, the datagram may need to be forwarded to several
multicast group members, at times requiring the datagram to be
replicated and sent out multiple interfaces.
The state of multicast routing protocols is less developed than the
protocols available for the forwarding of IP unicasts. Three
experimental multicast routing protocols have been documented for
TCP/IP. Each uses the IGMP protocol (discussed in Section [4.4]) to
monitor multicast group membership.
DVMRP, documented in [ROUTE:9], is based on Distance Vector or
Bellman-Ford technology. It routes multicast datagrams only, and
does so within a single Autonomous System. DVMRP is an
implementation of the Truncated Reverse Path Broadcasting algorithm
described in [ROUTE:10]. In addition, it specifies the tunneling of
IP multicasts through non-multicast-routing-capable IP domains.
MOSPF, currently under development, is a backward-compatible addition
to OSPF that allows the forwarding of both IP multicasts and unicasts
within an Autonomous System. MOSPF routers can be mixed with OSPF
routers within a routing domain, and they will interoperate in the
forwarding of unicasts. OSPF is a link-state or SPF-based protocol.
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By adding link state advertisements that pinpoint group membership,
MOSPF routers can calculate the path of a multicast datagram as a
tree rooted at the datagram source. Those branches that do not
contain group members can then be discarded, eliminating unnecessary
datagram forwarding hops.
PIM, currently under development, is a multicast routing protocol
that runs over an existing unicast infrastructure. PIM provides for
both dense and sparse group membership. It is different from other
protocols, since it uses an explicit join model for sparse groups.
Joining occurs on a shared tree and can switch to a per-source tree.
Where bandwidth is plentiful and group membership is dense, overhead
can be reduced by flooding data out all links and later pruning
exception cases where there are no group members.
APPENDIX E Additional Next-Hop Selection Algorithms
Section [5.2.4.3] specifies an algorithm that routers ought to use
when selecting a next-hop for a packet.
This appendix provides historical perspective for the next-hop
selection problem. It also presents several additional pruning rules
and next-hop selection algorithms that might be found in the
Internet.
This appendix presents material drawn from an earlier, unpublished,
work by Philip Almquist; Ruminations on the Next Hop.
This Appendix does not specify any standards or requirements.
It is useful to briefly review the history of the topic, beginning
with what is sometimes called the "classic model" of how a router
makes routing decisions. This model predates IP. In this model, a
router speaks some single routing protocol such as RIP. The protocol
completely determines the contents of the router's Forwarding
Information Base (FIB). The route lookup algorithm is trivial: the
router looks in the FIB for a route whose destination attribute
exactly matches the network prefix portion of the destination address
in the packet. If one is found, it is used; if none is found, the
destination is unreachable. Because the routing protocol keeps at
most one route to each destination, the problem of what to do when
there are multiple routes that match the same destination cannot
arise.
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Over the years, this classic model has been augmented in small ways.
With the deployment of default routes, subnets, and host routes, it
became possible to have more than one routing table entry which in
some sense matched the destination. This was easily resolved by a
consensus that there was a hierarchy of routes: host routes should be
preferred over subnet routes, subnet routes over net routes, and net
routes over default routes.
With the deployment of technologies supporting variable length subnet
masks (variable length network prefixes), the general approach
remained the same although its description became a little more
complicated; network prefixes were introduced as a conscious
simplification and regularization of the architecture. We now say
that each route to a network prefix route has a prefix length
associated with it. This prefix length indicates the number of bits
in the prefix. This may also be represented using the classical
subnet mask. A route cannot be used to route a packet unless each
significant bit in the route's network prefix matches the
corresponding bit in the packet's destination address. Routes with
more bits set in their masks are preferred over routes that have
fewer bits set in their masks. This is simply a generalization of
the hierarchy of routes described above, and will be referred to for
the rest of this memo as choosing a route by preferring longest
match.
Another way the classic model has been augmented is through a small
amount of relaxation of the notion that a routing protocol has
complete control over the contents of the routing table. First,
static routes were introduced. For the first time, it was possible
to simultaneously have two routes (one dynamic and one static) to the
same destination. When this happened, a router had to have a policy
(in some cases configurable, and in other cases chosen by the author
of the router's software) which determined whether the static route
or the dynamic route was preferred. However, this policy was only
used as a tie-breaker when longest match didn't uniquely determine
which route to use. Thus, for example, a static default route would
never be preferred over a dynamic net route even if the policy
preferred static routes over dynamic routes.
The classic model had to be further augmented when inter-domain
routing protocols were invented. Traditional routing protocols came
to be called "interior gateway protocols" (IGPs), and at each
Internet site there was a strange new beast called an "exterior
gateway", a router that spoke EGP to several "BBN Core Gateways" (the
routers that made up the Internet backbone at the time) at the same
time as it spoke its IGP to the other routers at its site. Both
protocols wanted to determine the contents of the router's routing
table. Theoretically, this could result in a router having three
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routes (EGP, IGP, and static) to the same destination. Because of
the Internet topology at the time, it was resolved with little debate
that routers would be best served by a policy of preferring IGP
routes over EGP routes. However, the sanctity of longest match
remained unquestioned: a default route learned from the IGP would
never be preferred over a net route from learned EGP.
Although the Internet topology, and consequently routing in the
Internet, have evolved considerably since then, this slightly
augmented version of the classic model has survived intact to this
day in the Internet (except that BGP has replaced EGP). Conceptually
(and often in implementation) each router has a routing table and one
or more routing protocol processes. Each of these processes can add
any entry that it pleases, and can delete or modify any entry that it
has created. When routing a packet, the router picks the best route
using longest match, augmented with a policy mechanism to break ties.
Although this augmented classic model has served us well, it has a
number of shortcomings:
o It ignores (although it could be augmented to consider) path
characteristics such as quality of service and MTU.
o It doesn't support routing protocols (such as OSPF and Integrated
IS-IS) that require route lookup algorithms different than pure
longest match.
o There has not been a firm consensus on what the tie-breaking
mechanism ought to be. Tie-breaking mechanisms have often been
found to be difficult if not impossible to configure in such a way
that the router will always pick what the network manger considers
to be the "correct" route.
Section [5.2.4.3] defined several pruning rules to use to select
routes from the FIB. There are other rules that could also be
used.
o OSPF Route Class
Routing protocols that have areas or make a distinction between
internal and external routes divide their routes into classes
by the type of information used to calculate the route. A
route is always chosen from the most preferred class unless
none is available, in which case one is chosen from the second
most preferred class, and so on. In OSPF, the classes (in
order from most preferred to least preferred) are intra-area,
inter-area, type 1 external (external routes with internal
metrics), and type 2 external. As an additional wrinkle, a
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router is configured to know what addresses ought to be
accessible using intra-area routes, and will not use inter-
area or external routes to reach these destinations even when
no intra-area route is available.
More precisely, we assume that each route has a class
attribute, called route.class, which is assigned by the routing
protocol. The set of candidate routes is examined to determine
if it contains any for which route.class = intra-area. If so,
all routes except those for which route.class = intra-area are
discarded. Otherwise, router checks whether the packet's
destination falls within the address ranges configured for the
local area. If so, the entire set of candidate routes is
deleted. Otherwise, the set of candidate routes is examined to
determine if it contains any for which route.class = inter-
area. If so, all routes except those for which route.class =
inter-area are discarded. Otherwise, the set of candidate
routes is examined to determine if it contains any for which
route.class = type 1 external. If so, all routes except those
for which route.class = type 1 external are discarded.
o IS-IS Route Class
IS-IS route classes work identically to OSPF's. However, the
set of classes defined by Integrated IS-IS is different, such
that there isn't a one-to-one mapping between IS-IS route
classes and OSPF route classes. The route classes used by
Integrated IS-IS are (in order from most preferred to least
preferred) intra-area, inter-area, and external.
The Integrated IS-IS internal class is equivalent to the OSPF
internal class. Likewise, the Integrated IS-IS external class
is equivalent to OSPF's type 2 external class. However,
Integrated IS-IS does not make a distinction between inter-area
routes and external routes with internal metrics - both are
considered to be inter-area routes. Thus, OSPF prefers true
inter-area routes over external routes with internal metrics,
whereas Integrated IS-IS gives the two types of routes equal
preference.
o IDPR Policy
A specific case of Policy. The IETF's Inter-domain Policy
Routing Working Group is devising a routing protocol called
Inter-Domain Policy Routing (IDPR) to support true policy-based
routing in the Internet. Packets with certain combinations of
header attributes (such as specific combinations of source and
destination addresses or special IDPR source route options) are
required to use routes provided by the IDPR protocol. Thus,
unlike other Policy pruning rules, IDPR Policy would have to be
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applied before any other pruning rules except Basic Match.
Specifically, IDPR Policy examines the packet being forwarded
to ascertain if its attributes require that it be forwarded
using policy-based routes. If so, IDPR Policy deletes all
routes not provided by the IDPR protocol.
This section examines several route lookup algorithms that are in
use or have been proposed. Each is described by giving the
sequence of pruning rules it uses. The strengths and weaknesses
of each algorithm are presented
The Revised Classic Algorithm is the form of the traditional
algorithm that was discussed in Section [E.1]. The steps of this
algorithm are:
1. Basic match
2. Longest match
3. Best metric
4. Policy
Some implementations omit the Policy step, since it is needed only
when routes may have metrics that are not comparable (because they
were learned from different routing domains).
The advantages of this algorithm are:
(1) It is widely implemented.
(2) Except for the Policy step (which an implementor can choose to
make arbitrarily complex) the algorithm is simple both to
understand and to implement.
Its disadvantages are:
(1) It does not handle IS-IS or OSPF route classes, and therefore
cannot be used for Integrated IS-IS or OSPF.
(2) It does not handle TOS or other path attributes.
(3) The policy mechanisms are not standardized in any way, and are
therefore are often implementation-specific. This causes
extra work for implementors (who must invent appropriate
policy mechanisms) and for users (who must learn how to use
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the mechanisms. This lack of a standardized mechanism also
makes it difficult to build consistent configurations for
routers from different vendors. This presents a significant
practical deterrent to multi-vendor interoperability.
(4) The proprietary policy mechanisms currently provided by
vendors are often inadequate in complex parts of the
Internet.
(5) The algorithm has not been written down in any generally
available document or standard. It is, in effect, a part of
the Internet Folklore.
Some Router Requirements Working Group members have proposed a
slight variant of the algorithm described in the Section
[5.2.4.3]. In this variant, matching the type of service
requested is considered to be more important, rather than less
important, than matching as much of the destination address as
possible. For example, this algorithm would prefer a default
route that had the correct type of service over a network route
that had the default type of service, whereas the algorithm in
[5.2.4.3] would make the opposite choice.
The steps of the algorithm are:
1. Basic match
2. Weak TOS
3. Longest match
4. Best metric
5. Policy
Debate between the proponents of this algorithm and the regular
Router Requirements Algorithm suggests that each side can show
cases where its algorithm leads to simpler, more intuitive routing
than the other's algorithm does. This variant has the same set of
advantages and disadvantages that the algorithm specified in
[5.2.4.3] does, except that pruning on Weak TOS before pruning on
Longest Match makes this algorithm less compatible with OSPF and
Integrated IS-IS than the standard Router Requirements Algorithm.
OSPF uses an algorithm that is virtually identical to the Router
Requirements Algorithm except for one crucial difference: OSPF
considers OSPF route classes.
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The algorithm is:
1. Basic match
2. OSPF route class
3. Longest match
4. Weak TOS
5. Best metric
6. Policy
Type of service support is not always present. If it is not
present then, of course, the fourth step would be omitted
This algorithm has some advantages over the Revised Classic
Algorithm:
(1) It supports type of service routing.
(2) Its rules are written down, rather than merely being a part of
the Internet folklore.
(3) It (obviously) works with OSPF.
However, this algorithm also retains some of the disadvantages of
the Revised Classic Algorithm:
(1) Path properties other than type of service (e.g., MTU) are
ignored.
(2) As in the Revised Classic Algorithm, the details (or even the
existence) of the Policy step are left to the discretion of
the implementor.
The OSPF Algorithm also has a further disadvantage (which is not
shared by the Revised Classic Algorithm). OSPF internal (intra-
area or inter-area) routes are always considered to be superior to
routes learned from other routing protocols, even in cases where
the OSPF route matches fewer bits of the destination address.
This is a policy decision that is inappropriate in some networks.
Finally, it is worth noting that the OSPF Algorithm's TOS support
suffers from a deficiency in that routing protocols that support
TOS are implicitly preferred when forwarding packets that have
non-zero TOS values. This may not be appropriate in some cases.
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Integrated IS-IS uses an algorithm that is similar to but not quite
identical to the OSPF Algorithm. Integrated IS-IS uses a different
set of route classes, and differs slightly in its handling of type of
service. The algorithm is:
1. Basic Match
2. IS-IS Route Classes
3. Longest Match
4. Weak TOS
5. Best Metric
6. Policy
Although Integrated IS-IS uses Weak TOS, the protocol is only capable
of carrying routes for a small specific subset of the possible values
for the TOS field in the IP header. Packets containing other values
in the TOS field are routed using the default TOS.
Type of service support is optional; if disabled, the fourth step
would be omitted. As in OSPF, the specification does not include the
Policy step.
This algorithm has some advantages over the Revised Classic
Algorithm:
(1) It supports type of service routing.
(2) Its rules are written down, rather than merely being a part of
the Internet folklore.
(3) It (obviously) works with Integrated IS-IS.
However, this algorithm also retains some of the disadvantages of the
Revised Classic Algorithm:
(1) Path properties other than type of service (e.g., MTU) are
ignored.
(2) As in the Revised Classic Algorithm, the details (or even the
existence) of the Policy step are left to the discretion of the
implementor.
(3) It doesn't work with OSPF because of the differences between IS-
IS route classes and OSPF route classes. Also, because IS-IS
supports only a subset of the possible TOS values, some obvious
implementations of the Integrated IS-IS algorithm would not
support OSPF's interpretation of TOS.
The Integrated IS-IS Algorithm also has a further disadvantage (which
is not shared by the Revised Classic Algorithm): IS-IS internal
(intra-area or inter-area) routes are always considered to be
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superior to routes learned from other routing protocols, even in
cases where the IS-IS route matches fewer bits of the destination
address and doesn't provide the requested type of service. This is a
policy decision that may not be appropriate in all cases.
Finally, it is worth noting that the Integrated IS-IS Algorithm's TOS
support suffers from the same deficiency noted for the OSPF
Algorithm.
Security Considerations
Although the focus of this document is interoperability rather than
security, there are obviously many sections of this document that
have some ramifications on network security.
Security means different things to different people. Security from a
router's point of view is anything that helps to keep its own
networks operational and in addition helps to keep the Internet as a
whole healthy. For the purposes of this document, the security
services we are concerned with are denial of service, integrity, and
authentication as it applies to the first two. Privacy as a security
service is important, but only peripherally a concern of a router -
at least as of the date of this document.
In several places in this document there are sections entitled ...
Security Considerations. These sections discuss specific
considerations that apply to the general topic under discussion.
Rarely does this document say do this and your router/network will be
secure. More likely, it says this is a good idea and if you do it,
it *may* improve the security of the Internet and your local system
in general.
Unfortunately, this is the state-of-the-art AT THIS TIME. Few if any
of the network protocols a router is concerned with have reasonable,
built-in security features. Industry and the protocol designers have
been and are continuing to struggle with these issues. There is
progress, but only small baby steps such as the peer-to-peer
authentication available in the BGP and OSPF routing protocols.
In particular, this document notes the current research into
developing and enhancing network security. Specific areas of
research, development, and engineering that are underway as of this
writing (December 1993) are in IP Security, SNMP Security, and common
authentication technologies.
Notwithstanding all the above, there are things both vendors and
users can do to improve the security of their router. Vendors should
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get a copy of Trusted Computer System Interpretation [INTRO:8]. Even
if a vendor decides not to submit their device for formal
verification under these guidelines, the publication provides
excellent guidance on general security design and practices for
computing devices.
APPENDIX F: HISTORICAL ROUTING PROTOCOLS
Certain routing protocols are common in the Internet, but the authors
of this document cannot in good conscience recommend their use. This
is not because they do not work correctly, but because the
characteristics of the Internet assumed in their design (simple
routing, no policy, a single "core router" network under common
administration, limited complexity, or limited network diameter) are
not attributes of today's Internet. Those parts of the Internet that
still use them are generally limited "fringe" domains with limited
complexity.
As a matter of good faith, collected wisdom concerning their
implementation is recorded in this section.
The Exterior Gateway Protocol (EGP) specifies an EGP that is used to
exchange reachability information between routers of the same or
differing autonomous systems. EGP is not considered a routing
protocol since there is no standard interpretation (i.e. metric) for
the distance fields in the EGP update message, so distances are
comparable only among routers of the same AS. It is however designed
to provide high-quality reachability information, both about neighbor
routers and about routes to non-neighbor routers.
EGP is defined by [ROUTE:6]. An implementor almost certainly wants
to read [ROUTE:7] and [ROUTE:8] as well, for they contain useful
explanations and background material.
DISCUSSION
The present EGP specification has serious limitations, most
importantly a restriction that limits routers to advertising only
those networks that are reachable from within the router's
autonomous system. This restriction against propagating third
party EGP information is to prevent long-lived routing loops.
This effectively limits EGP to a two-level hierarchy.
RFC-975 is not a part of the EGP specification, and should be
ignored.
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Indirect Neighbors: RFC-888, page 26
An implementation of EGP MUST include indirect neighbor
support.
Polling Intervals: RFC-904, page 10
The interval between Hello command retransmissions and the
interval between Poll retransmissions SHOULD be configurable
but there MUST be a minimum value defined.
The interval at which an implementation will respond to Hello
commands and Poll commands SHOULD be configurable but there
MUST be a minimum value defined.
Network Reachability: RFC-904, page 15
An implementation MUST default to not providing the external list of
routers in other autonomous systems; only the internal list of
routers together with the nets that are reachable through those
routers should be included in an Update Response/Indication packet.
However, an implementation MAY elect to provide a configuration
option enabling the external list to be provided. An implementation
MUST NOT include in the external list routers that were learned
through the external list provided by a router in another autonomous
system. An implementation MUST NOT send a network back to the
autonomous system from which it is learned, i.e. it MUST do split-
horizon on an autonomous system level.
If more than 255 internal or 255 external routers need to be
specified in a Network Reachability update, the networks reachable
from routers that can not be listed MUST be merged into the list for
one of the listed routers. Which of the listed routers is chosen for
this purpose SHOULD be user configurable, but SHOULD default to the
source address of the EGP update being generated.
An EGP update contains a series of blocks of network numbers, where
each block contains a list of network numbers reachable at a
particular distance through a particular router. If more than 255
networks are reachable at a particular distance through a particular
router, they are split into multiple blocks (all of which have the
same distance). Similarly, if more than 255 blocks are required to
list the networks reachable through a particular router, the router's
address is listed as many times as necessary to include all the
blocks in the update.
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Unsolicited Updates: RFC-904, page 16
If a network is shared with the peer, an implementation MUST send an
unsolicited update upon entry to the Up state if the source network
is the shared network.
Neighbor Reachability: RFC-904, page 6, 13-15
The table on page 6 that describes the values of j and k (the
neighbor up and down thresholds) is incorrect. It is reproduced
correctly here:
Name Active Passive Description
-----------------------------------------------
j 3 1 neighbor-up threshold
k 1 0 neighbor-down threshold
The value for k in passive mode also specified incorrectly in RFC-
904, page 14 The values in parenthesis should read:
(j = 1, k = 0, and T3/T1 = 4)
As an optimization, an implementation can refrain from sending a
Hello command when a Poll is due. If an implementation does so, it
SHOULD provide a user configurable option to disable this
optimization.
Abort timer: RFC-904, pages 6, 12, 13
An EGP implementation MUST include support for the abort timer (as
documented in section 4.1.4 of RFC-904). An implementation SHOULD
use the abort timer in the Idle state to automatically issue a Start
event to restart the protocol machine. Recommended values are P4 for
a critical error (Administratively prohibited, Protocol Violation and
Parameter Problem) and P5 for all others. The abort timer SHOULD NOT
be started when a Stop event was manually initiated (such as through
a network management protocol).
Cease command received in Idle state: RFC-904, page 13
When the EGP state machine is in the Idle state, it MUST reply to
Cease commands with a Cease-ack response.
Hello Polling Mode: RFC-904, page 11
An EGP implementation MUST include support for both active and
passive polling modes.
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Neighbor Acquisition Messages: RFC-904, page 18
As noted the Hello and Poll Intervals should only be present in
Request and Confirm messages. Therefore the length of an EGP
Neighbor Acquisition Message is 14 bytes for a Request or Confirm
message and 10 bytes for a Refuse, Cease or Cease-ack message.
Implementations MUST NOT send 14 bytes for Refuse, Cease or Cease-ack
messages but MUST allow for implementations that send 14 bytes for
these messages.
Sequence Numbers: RFC-904, page 10
Response or indication packets received with a sequence number not
equal to S MUST be discarded. The send sequence number S MUST be
incremented just before the time a Poll command is sent and at no
other times.
RIP is specified in [ROUTE:3]. Although RIP is still quite important
in the Internet, it is being replaced in sophisticated applications
by more modern IGPs such as the ones described above. A router
implementing RIP SHOULD implement RIP Version 2 [ROUTE:?], as it
supports CIDR routes. If occasional access networking is in use, a
router implementing RIP SHOULD implement Demand RIP [ROUTE:?].
Another common use for RIP is as a router discovery protocol.
Section [4.3.3.10] briefly touches upon this subject.
Dealing with changes in topology: [ROUTE:3], page 11
An implementation of RIP MUST provide a means for timing out
routes. Since messages are occasionally lost, implementations
MUST NOT invalidate a route based on a single missed update.
Implementations MUST by default wait six times the update
interval before invalidating a route. A router MAY have
configuration options to alter this value.
DISCUSSION
It is important to routing stability that all routers in a RIP
autonomous system use similar timeout value for invalidating
routes, and therefore it is important that an implementation
default to the timeout value specified in the RIP specification.
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However, that timeout value is too conservative in environments
where packet loss is reasonably rare. In such an environment, a
network manager may wish to be able to decrease the timeout period
to promote faster recovery from failures.
IMPLEMENTATION
There is a very simple mechanism that a router may use to meet the
requirement to invalidate routes promptly after they time out.
Whenever the router scans the routing table to see if any routes
have timed out, it also notes the age of the least recently
updated route that has not yet timed out. Subtracting this age
from the timeout period gives the amount of time until the router
again needs to scan the table for timed out routes.
Split Horizon: [ROUTE:3], page 14-15
An implementation of RIP MUST implement split horizon, a scheme used
for avoiding problems caused by including routes in updates sent to
the router from which they were learned.
An implementation of RIP SHOULD implement Split horizon with poisoned
reverse, a variant of split horizon that includes routes learned from
a router sent to that router, but sets their metric to infinity.
Because of the routing overhead that may be incurred by implementing
split horizon with poisoned reverse, implementations MAY include an
option to select whether poisoned reverse is in effect. An
implementation SHOULD limit the time in which it sends reverse routes
at an infinite metric.
IMPLEMENTATION
Each of the following algorithms can be used to limit the time for
which poisoned reverse is applied to a route. The first algorithm
is more complex but does a more thorough job of limiting poisoned
reverse to only those cases where it is necessary.
The goal of both algorithms is to ensure that poison reverse is
done for any destination whose route has changed in the last Route
Lifetime (typically 180 seconds), unless it can be sure that the
previous route used the same output interface. The Route Lifetime
is used because that is the amount of time RIP will keep around an
old route before declaring it stale.
The time intervals (and derived variables) used in the following
algorithms are as follows:
Tu The Update Timer; the number of seconds between RIP updates.
This typically defaults to 30 seconds.
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Rl The Route Lifetime, in seconds. This is the amount of time
that a route is presumed to be good, without requiring an
update. This typically defaults to 180 seconds.
Ul The Update Loss; the number of consecutive updates that have to
be lost or fail to mention a route before RIP deletes the
route. Ul is calculated to be (Rl/Tu)+1. The +1 is to
account for the fact that the first time the ifcounter is
decremented will be less than Tu seconds after it is
initialized. Typically, Ul will be 7: (180/30)+1.
In The value to set ifcounter to when a destination is newly
learned. This value is Ul-4, where the 4 is RIP's garbage
collection timer/30
The first algorithm is:
- Associated with each destination is a counter, called the
ifcounter below. Poison reverse is done for any route whose
destination's ifcounter is greater than zero.
- After a regular (not triggered or in response to a request)
update is sent, all the non-zero ifcounters are decremented by
one.
- When a route to a destination is created, its ifcounter is set
as follows:
- If the new route is superseding a valid route, and the old
route used a different (logical) output interface, then the
ifcounter is set to Ul.
- If the new route is superseding a stale route, and the old
route used a different (logical) output interface, then the
ifcounter is set to MAX(0, Ul - INT(seconds that the route
has been stale/Ut).
- If there was no previous route to the destination, the
ifcounter is set to In.
- Otherwise, the ifcounter is set to zero
- RIP also maintains a timer, called the resettimer below. Poison
reverse is done on all routes whenever resettimer has not
expired (regardless of the ifcounter values).
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- When RIP is started, restarted, reset, or otherwise has its
routing table cleared, it sets the resettimer to go off in Rl
seconds.
The second algorithm is identical to the first except that:
- The rules which set the ifcounter to non-zero values are changed
to always set it to Rl/Tu, and
- The resettimer is eliminated.
Triggered updates: [ROUTE:3], page 15-16; page 29
Triggered updates (also called flash updates) are a mechanism for
immediately notifying a router's neighbors when the router adds or
deletes routes or changes their metrics. A router MUST send a
triggered update when routes are deleted or their metrics are
increased. A router MAY send a triggered update when routes are
added or their metrics decreased.
Since triggered updates can cause excessive routing overhead,
implementations MUST use the following mechanism to limit the
frequency of triggered updates:
(1) When a router sends a triggered update, it sets a timer to a
random time between one and five seconds in the future. The
router must not generate additional triggered updates before
this timer expires.
(2) If the router would generate a triggered update during this
interval it sets a flag indicating that a triggered update is
desired. The router also logs the desired triggered update.
(3) When the triggered update timer expires, the router checks the
triggered update flag. If the flag is set then the router
sends a single triggered update which includes all the
changes that were logged. The router then clears the flag
and, since a triggered update was sent, restarts this
algorithm.
(4) The flag is also cleared whenever a regular update is sent.
Triggered updates SHOULD include all routes that have changed
since the most recent regular (non-triggered) update. Triggered
updates MUST NOT include routes that have not changed since the
most recent regular update.
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DISCUSSION
Sending all routes, whether they have changed recently or not, is
unacceptable in triggered updates because the tremendous size of
many Internet routing tables could otherwise result in
considerable bandwidth being wasted on triggered updates.
Use of UDP: [ROUTE:3], page 18-19.
RIP packets sent to an IP broadcast address SHOULD have their initial
TTL set to one.
Note that to comply with Section [6.1] of this memo, a router SHOULD
use UDP checksums in RIP packets that it originates, MUST discard RIP
packets received with invalid UDP checksums, but MUST NOT discard
received RIP packets simply because they do not contain UDP
checksums.
Addressing Considerations: [ROUTE:3], page 22
A RIP implementation SHOULD support host routes. If it does not, it
MUST (as described on page 27 of [ROUTE:3]) ignore host routes in
received updates. A router MAY log ignored hosts routes.
The special address 0.0.0.0 is used to describe a default route. A
default route is used as the route of last resort (i.e., when a route
to the specific net does not exist in the routing table). The router
MUST be able to create a RIP entry for the address 0.0.0.0.
Input Processing - Response: [ROUTE:3], page 26
When processing an update, the following validity checks MUST be
performed:
o The response MUST be from UDP port 520.
o The source address MUST be on a directly connected subnet (or on a
directly connected, non-subnetted network) to be considered valid.
o The source address MUST NOT be one of the router's addresses.
DISCUSSION
Some networks, media, and interfaces allow a sending node to
receive packets that it broadcasts. A router must not accept its
own packets as valid routing updates and process them. The last
requirement prevents a router from accepting its own routing
updates and processing them (on the assumption that they were sent
by some other router on the network).
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An implementation MUST NOT replace an existing route if the metric
received is equal to the existing metric except in accordance with
the following heuristic.
An implementation MAY choose to implement the following heuristic to
deal with the above situation. Normally, it is useless to change the
route to a network from one router to another if both are advertised
at the same metric. However, the route being advertised by one of
the routers may be in the process of timing out. Instead of waiting
for the route to timeout, the new route can be used after a specified
amount of time has elapsed. If this heuristic is implemented, it
MUST wait at least halfway to the expiration point before the new
route is installed.
RIP Shutdown
An implementation of RIP SHOULD provide for a graceful shutdown
using the following steps:
(1) Input processing is terminated,
(2) Four updates are generated at random intervals of between two
and four seconds, These updates contain all routes that were
previously announced, but with some metric changes. Routes
that were being announced at a metric of infinity should
continue to use this metric. Routes that had been announced
with a non-infinite metric should be announced with a metric
of 15 (infinity - 1).
DISCUSSION
The metric used for the above really ought to be 16 (infinity);
setting it to 15 is a kludge to avoid breaking certain old hosts
that wiretap the RIP protocol. Such a host will (erroneously)
abort a TCP connection if it tries to send a datagram on the
connection while the host has no route to the destination (even if
the period when the host has no route lasts only a few seconds
while RIP chooses an alternate path to the destination).
RIP Split Horizon and Static Routes
Split horizon SHOULD be applied to static routes by default. An
implementation SHOULD provide a way to specify, per static route,
that split horizon should not be applied to this route.
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The Gateway to Gateway protocol is considered obsolete and SHOULD NOT
be implemented.
Acknowledgments
O that we now had here
But one ten thousand of those men in England
That do no work to-day!
What's he that wishes so?
My cousin Westmoreland? No, my fair cousin:
If we are mark'd to die, we are enow
To do our country loss; and if to live,
The fewer men, the greater share of honour.
God's will! I pray thee, wish not one man more.
By Jove, I am not covetous for gold,
Nor care I who doth feed upon my cost;
It yearns me not if men my garments wear;
Such outward things dwell not in my desires:
But if it be a sin to covet honour,
I am the most offending soul alive.
No, faith, my coz, wish not a man from England:
God's peace! I would not lose so great an honour
As one man more, methinks, would share from me
For the best hope I have. O, do not wish one more!
Rather proclaim it, Westmoreland, through my host,
That he which hath no stomach to this fight,
Let him depart; his passport shall be made
And crowns for convoy put into his purse:
We would not die in that man's company
That fears his fellowship to die with us.
This day is called the feast of Crispian:
He that outlives this day, and comes safe home,
Will stand a tip-toe when the day is named,
And rouse him at the name of Crispian.
He that shall live this day, and see old age,
Will yearly on the vigil feast his neighbours,
And say 'To-morrow is Saint Crispian:'
Then will he strip his sleeve and show his scars.
And say 'These wounds I had on Crispin's day.'
Old men forget: yet all shall be forgot,
But he'll remember with advantages
What feats he did that day: then shall our names.
Familiar in his mouth as household words
Harry the king, Bedford and Exeter,
Warwick and Talbot, Salisbury and Gloucester,
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Be in their flowing cups freshly remember'd.
This story shall the good man teach his son;
And Crispin Crispian shall ne'er go by,
From this day to the ending of the world,
But we in it shall be remember'd;
We few, we happy few, we band of brothers;
For he to-day that sheds his blood with me
Shall be my brother; be he ne'er so vile,
This day shall gentle his condition:
And gentlemen in England now a-bed
Shall think themselves accursed they were not here,
And hold their manhoods cheap whiles any speaks
That fought with us upon Saint Crispin's day.
-- William Shakespeare
This memo is a product of the IETF's Router Requirements Working
Group. A memo such as this one is of necessity the work of many more
people than could be listed here. A wide variety of vendors, network
managers, and other experts from the Internet community graciously
contributed their time and wisdom to improve the quality of this
memo. The editor wishes to extend sincere thanks to all of them.
The current editor also wishes to single out and extend his heartfelt
gratitude and appreciation to the original editor of this document;
Philip Almquist. Without Philip's work, both as the original editor
and as the Chair of the working group, this document would not have
been produced. He also wishes to express deep and heartfelt
gratitude to the previous editor, Frank Kastenholz. Frank changed
the original document from a collection of information to a useful
description of IP technology - in his words, a "snapshot" of the
technology in 1991. One can only hope that this snapshot, of the
technology in 1994, is as clear.
Philip Almquist, Jeffrey Burgan, Frank Kastenholz, and Cathy
Wittbrodt each wrote major chapters of this memo. Others who made
major contributions to the document included Bill Barns, Steve
Deering, Kent England, Jim Forster, Martin Gross, Jeff Honig, Steve
Knowles, Yoni Malachi, Michael Reilly, and Walt Wimer.
Additional text came from Andy Malis, Paul Traina, Art Berggreen,
John Cavanaugh, Ross Callon, John Lekashman, Brian Lloyd, Gary
Malkin, Milo Medin, John Moy, Craig Partridge, Stephanie Price, Yakov
Rekhter, Steve Senum, Richard Smith, Frank Solensky, Rich Woundy, and
others who have been inadvertently overlooked.
Some of the text in this memo has been (shamelessly) plagiarized from
earlier documents, most notably RFC-1122 by Bob Braden and the Host
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RFC 1812 Requirements for IP Version 4 Routers June 1995
Requirements Working Group, and RFC-1009 by Bob Braden and Jon
Postel. The work of these earlier authors is gratefully
acknowledged.
Jim Forster was a co-chair of the Router Requirements Working Group
during its early meetings, and was instrumental in getting the group
off to a good start. Jon Postel, Bob Braden, and Walt Prue also
contributed to the success by providing a wealth of good advice
before the group's first meeting. Later on, Phill Gross, Vint Cerf,
and Noel Chiappa all provided valuable advice and support.
Mike St. Johns coordinated the Working Group's interactions with the
security community, and Frank Kastenholz coordinated the Working
Group's interactions with the network management area. Allison
Mankin and K.K. Ramakrishnan provided expertise on the issues of
congestion control and resource allocation.
Many more people than could possibly be listed or credited here
participated in the deliberations of the Router Requirements Working
Group, either through electronic mail or by attending meetings.
However, the efforts of Ross Callon and Vince Fuller in sorting out
the difficult issues of route choice and route leaking are especially
acknowledged.
The editor thanks his employer, Cisco Systems, for allowing him to
spend the time necessary to produce the 1994 snapshot.
Editor's Address
The address of the current editor of this document is
Fred Baker
Cisco Systems
519 Lado Drive
Santa Barbara, California 93111
USA
Phone:+1 805-681-0115
EMail: fred@cisco.com
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